key: cord-0072115-xohr8mqq
authors: Mubeen, Bismillah; Ansar, Aunza Nayab; Rasool, Rabia; Ullah, Inam; Imam, Syed Sarim; Alshehri, Sultan; Ghoneim, Mohammed M.; Alzarea, Sami I.; Nadeem, Muhammad Shahid; Kazmi, Imran
title: Nanotechnology as a Novel Approach in Combating Microbes Providing an Alternative to Antibiotics
date: 2021-11-30
journal: Antibiotics (Basel)
DOI: 10.3390/antibiotics10121473
sha: aa850e78f6a7be21a84ba87006076577b47b6054
doc_id: 72115
cord_uid: xohr8mqq

The emergence of infectious diseases promises to be one of the leading mortality factors in the healthcare sector. Although several drugs are available on the market, newly found microorganisms carrying multidrug resistance (MDR) against which existing drugs cannot function effectively, giving rise to escalated antibiotic dosage therapies and the need to develop novel drugs, which require time, money, and manpower. Thus, the exploitation of antimicrobials has led to the production of MDR bacteria, and their prevalence and growth are a major concern. Novel approaches to prevent antimicrobial drug resistance are in practice. Nanotechnology-based innovation provides physicians and patients the opportunity to overcome the crisis of drug resistance. Nanoparticles have promising potential in the healthcare sector. Recently, nanoparticles have been designed to address pathogenic microorganisms. A multitude of processes that can vary with various traits, including size, morphology, electrical charge, and surface coatings, allow researchers to develop novel composite antimicrobial substances for use in different applications performing antimicrobial activities. The antimicrobial activity of inorganic and carbon-based nanoparticles can be applied to various research, medical, and industrial uses in the future and offer a solution to the crisis of antimicrobial resistance to traditional approaches. Metal-based nanoparticles have also been extensively studied for many biomedical applications. In addition to reduced size and selectivity for bacteria, metal-based nanoparticles have proven effective against pathogens listed as a priority, according to the World Health Organization (WHO). Moreover, antimicrobial studies of nanoparticles were carried out not only in vitro but in vivo as well in order to investigate their efficacy. In addition, nanomaterials provide numerous opportunities for infection prevention, diagnosis, treatment, and biofilm control. This study emphasizes the antimicrobial effects of nanoparticles and contrasts nanoparticles’ with antibiotics’ role in the fight against pathogenic microorganisms. Future prospects revolve around developing new strategies and products to prevent, control, and treat microbial infections in humans and other animals, including viral infections seen in the current pandemic scenarios.

Antibiotics are drugs that may either destroy microbes or suppress them. Based on their target population, antibiotics are graded as antibacterial, antifungal, and antiviral. The term antibiotic is generally used to refer to most antibacterial compounds [1] . Antibiotics have been used for generations to prevent and treat infections and aid with many medical therapies, varying from organ transplantation to chemical therapy. Inhibition of enzymes, DNA interference, RNA and protein synthesis, and destruction of the membrane structure are well-known antimicrobial pathways of antibiotics [2] . Depending on the formation and the mode of multi-drug resistance, many groups or classes of antibiotics have been developed. Thus, it is virtually impossible to imagine the future without antibiotics.

Unfortunately, due to the rise of antibiotic resistance in microorganisms, this may become a reality [3] . Emerging drug resistance in microorganisms relates directly to the exploitation of antibiotics, excessive doses of medications leading to increased toxicity, prolonged hospitalization, and growing fatality [4] , their widespread use in agriculture, and the lack of development of new antibiotics [5] . Moreover, the modern convenience of mobility (of products and infected people) helps disseminate pathogens across the globe at a rate never seen before [6] . Apart from the adverse socio-economic consequences, the public health challenge of antibiotic resistance to pandemic infectious diseases is serious [6] . World Health Organization (WHO) has recognized antimicrobial resistance (AMR) as one of the major challenges to public health [7] .

Feasible pathways known to prevent antibiotic resistance in microbes include decreasing the consumption of antimicrobial medicines and improving drug release, modifying antibiotic targets, developing medicines for degrading or modifying enzymes in microorganisms, developing a biofilm coating containing the bacteria, and avoiding antibiotic exposure [8] . Eventually, such developments will lead towards reduced drug accumulation in microbial cells or a brief intracellular residency of drugs that do not effectively reach therapeutic concentrations [9] . Currently, however, higher doses and repeated drug administration are prevalent, contributing significantly to adverse side effects on animals and humans. Resistance has been developed towards several forms of antibiotics widely used against pathogenic microorganisms [10] . Most significantly, no new kinds of antibiotics have been developed in recent years. Furthermore, the development and promotion of new antibiotics is a costly and time-consuming procedure, requiring new compounds and multiple clinical studies and licensing [11] . The possibility that bacterial resistance towards all-new antibiotics will develop promptly would lead to decreasing antibiotic usage and declining sales, further exacerbating public health and economic condition. Therefore, the failure of antibiotic advancement would eventually lead to an elevated mortality threat from infections [12] . Consequentially, modern therapies are critical for overcoming these challenges.

Medicine has been modernized with the introduction of nanotechnology, the most significant breakthrough in recent years. There is a steady rise in the market for nanotechnology products. Nanotechnology, a groundbreaking science, will influence our efforts to improve human health. The medical industry has studied the longevity, efficiency, durability, flexibility, and inimitable physicochemical characteristics of nanoparticles. They are being utilized in numerous therapeutic approaches, such as the targeted delivery of medications, prognostic visual monitoring of therapy, and even tumor identification [13, 14] . Several conventional approaches have been used to synthesize nanoparticles, for example, effective techniques such as physical vapor deposition, laser ablation, sputtering, melt mixing, and chemical methods such as photo-reduction, sol-gel, thermolysis, and microemulsion. As a result of these techniques, nanoparticles can become unstable, harmful compounds can attach to nanoparticles' surface, and hazardous by-products can develop.

The biogenic nanoparticle synthesis relies on green methodologies. Green synthesis advantages include the production of stable nanoparticles, the use of a biomass-based surface coating that provides extra active surface areas for biological interaction, the exclusion of dangerous formation of byproducts, and additional stabilizing or reducing 

The development and effects of a disease on the human body depend on the form and strain of the pathogen [27] . The immune system generally provides an excellent defense against infectious agents. However, microbes may overtake the capacity of the immune system to fend them off. In such cases, an infection is harmful. Some microbes have no negative effect, while others generate toxins or toxic agents that cause adverse body responses. Due to this difference, some infections are harmless and hardly detectable, while others may be severe and life-threatening. Infection can spread in various ways, partly due to the differences in microbes themselves; fungi, parasites, bacteria, and viruses 

With a historical context of human disease, an exceedingly high percentage of infectious agents has been involved in infectious diseases. Microbes have been considered responsible for many infectious diseases during the second half of the nineteenth century. As a result, antimicrobial chemotherapy was introduced as the principal therapeutic technique against the pathogenic species.

Penicillin was discovered in 1928 by Fleming. In a region containing an infected blue mold (a fungus of the penicillium genus), the development of Staphylococcus aureus in cultivation dishes was inhibited, leading to the discovery that a microbe is developing compounds that may prevent other microbial growth. Subsequently, the antibiotic penicillin came into clinical usage in the 1940s. In the period of antimicrobial chemotherapy, penicillin was an excellent safety and efficacy agent, and during the Second World War, it saved the lives of many wounded troops. Penicillin had become the first antibiotic and marked the beginning of modern antibiotic production [5] (Table 1) . Table 1 . History of antibiotics, their discoveries, and events that have occurred.

<19th century Some of the oldest cultures used complex molds and plant extracts for therapy. For example, the ancient Egyptians added moldy bread to infectious wounds. [28] 19th century Scientists began to study the activity of antibacterial chemicals. [29] 20th century

The most significant case in the history of antibiotics is Alexander Fleming's discovery of penicillin in 1928. The first antibiotics were introduced in the late 1930s. The time between the 1950s and 1970s is considered the golden age in the development of new types of antibiotics, with no new classes found since then. Between 1944 and 1972, human life expectancy leaps by eight years, primarily due to the advent of antibiotics. Modified forms of erythromycin were used in the 1970s were 1980. In the 1970s, with the staled research and no discovery of new antibiotics, the fight against emerging microbial resistance to antibiotics consisted mainly in the alteration to existing antibiotics. By the 1980s and 1990s, scientists were only able to make advances in the laboratory. [30] 21st century Currently, more than 100 antibiotics are available to treat diseases in humans and livestock. [31] 350 CE-550 CE Traces of tetracycline from ancient Sudanese Nubia are found in human skeletal remains. [32] 1887 Soil bacteria application of the Anthrax strain. [33] 1887 Fever of intestinal Cholera infection. [34] 1888 A bacterium substance that has antibacterial properties. [35] 1896 Antibiotic effects found in Penicillium. [36] 1907 A synthesis of antibiotics derived from arsenic. [37] 1909 Arsphenamine Antisyphilitic. [38] 1912 A Chemotherapeutic Polymer, Neosalvarsan. [39] 1928 Synthesis of penicillin by the bacteria Staphylococcus. [40] 1930 Decomposition of part of bacillium from soil microorganisms. [41] 1932 Prontosil, the first microbial to receive sulphonamide. [42] 1936 Sulfonamide [43] 1937 Sulfonamides are added as effective antimicrobials. [44] 1938 Sulfapyridine for the treatment of pneumococcal pneumonia is used in a clinical setting. [45] 1939 Isolation of Tyrothricin (an antibacterial material). [46] 1939 Gramicidin A is discovered as the first clinically effective topical antibiotic from the soil bacterium bacillus brevis. [47] 1939

The penicillin G form became popular, the first penicillin used in therapy. [48] 

Antibiotic sulfacetamide sulfonamide is first reported in the treatment of eye diseases. [49] 1940 Sulfonamide antibiotic sulfamethoxazole is used as a common agent for the treatment of UTI and is commercialized. [50] 1941 β-Lactam antibiotics are incorporated into clinical trials for the first time. [51] 1941 Penicillin for therapeutic use is introduced. [52] 1942

For the prevention of bacterial infections, sulfadimidine is used. [53] 1942 Bacteria immune to penicillin were observed for the first time, around one year after penicillin introduction. [54] 1942

The first antibiotic peptide was isolated from Gramicidin S. [55] 1943

The first aminoglycoside is discovered-Streptomycin antibiotic. It is the first successful antibiotic against tuberculosis. [56] 1943

It synthesized a drug called sulfamerazine. [57] 1943 Penicillin was mass manufactured and used extensively during World War II to treat the Allied forces fighting in Europe. [58] 1943 First isolates of Bacitracin. This medication is being used to treat minor cuts, burns, and scrapes causing slight skin disease. [59] 1945 Chloramphenicol is isolated from Streptomyces venezuelae soil organism. [60] 1947

Chloramphenicol is first synthesized from Streptomyces venezuelae, a soil organism. It was marketed in 1949, owing to its wide range of antimicrobial activity, its use subsequently becoming widespread. [61] 1947

Chlortetracycline isolated from a sample of mud on the Missouri River. It is the first tetracycline used. [62] 1947

The antibiotic class of polymyxin is found, the first being polymyxin B isolated from bacterium paenibacillus polymyxa. [63] 1947 Nitrofuran is used in the drug class. Nitrofurans are organic, antimicrobial agents with a wide variety of activates, which include Giardia and Salmonella spp, amebas, trichomonads, and certain coccidia, against Gram-positive bacteria as well as Gram-negative bacteria. [64] 1948

Mafenide isolation-an antibiotic of the form of sulfonamide, is approved by the United States FDA. [65] 1949

The aminoglycoside antibiotic Neomycin is being isolated and used in a variety of topical product lines, such as ointments, eye drops, and creams. [66] 1950

Oxytetracycline enters commercial use. [67] 1950

Resistance is observed against chloramphenicol. [68] 1952

Lincosamides, a small group of agents with a novel structure, unlike any other antibiotic, are introduced.

[69]

1952 Antibiotic thiamphenicol with a wide range of action is synthesized. [70] 

Erythromycin is introduced; an antibiotic for treating bacterial inflammatory diseases, including skin infections, chlamydia infections, respiratory tract infections, syphilis, and pelvic inflammatory diseases.

[71]

1952

We add Streptogramins. Streptogramins are involved in treating vancomycin-resistant Staphylococcus aureus and vancomycin-resistant Enterococcus.

[72]

1953 Antibiotic cephalosporin C, from which cephalosporins later grow, is discovered. It prevents cell wall replication by preventing the cross-linkage of peptidoglycan. [73] 1953

Resistance to a macrolide is observed. [74] 1954 Benzathine penicillin is a drug for the syphilis cure. [75] 1954 A cycloserine antibiotic is found. This is used to treat tuberculosis. [76] 1955 First launched to the French market is the macrolide antibiotic spiramycin. Spiramycin is used for treating multiple diseases. [77] 1956 Second, vancomycin was isolated from the orienlalis bacterium streptomyces. Vancomycin is used to treat severe joint infections, endocarditis, bloodstream infections, bone and skin infections, and meningitis caused by staphylococcus aureus, which is methicillin immune. [78] 1956

Resistance is observed against erythromycin. [79] 1957

Kanamycin is being used. It is used for the treatment of serious bacterial infections and tuberculosis. [80] 1957

We add Ansamycins. These secondary bacterial metabolites demonstrate antimicrobial activity. [81] 1959

Colistin becomes essential to cure Gram-negative bacterial infections. [82] 1959 They add nitroimidazole. They are effective bactericidal agents against protozoa and anaerobes. [83] 1960

Scientists grow methicillin to kill penicillin-resistant strains. [84] 1960

Metronidazole is used as an important antitrichomonal agent commercially. [85] 1961 Resistance to Methicillin is first identified. [86] 1961 It is formulated with antibiotic ampicillin. It will become the medication of choice for the treatment of Hemophilus influenzae meningitis in a short period. [87] 1961 It is first reported to be spectinomycin. It is used only to cure gonorrhea infections. [88] 1961 Ethambutol is observed. The medicine is used mainly to treat tuberculosis. [89] 1962 Fusidic acid is being incorporated into medical practice. Skin infections caused by staphylococcal bacteria are treated with antibiotics. [90] 1962 Quinolones were mistakenly found as a by-product of studies on the chloroquine antimalarial medication. [91] 1963 Found gentamicin. It is used to cure different kinds of bacterial infections. [92] 

Gram-negative bacterium Acinetobacter baumannii becomes a pathogen and is immune to antibiotics. [93] 1965 It is synthesized with Antibiotic Cloxacillin. It is currently effective in the treatment of a variety of bacterial infections, which include septic arthritis, cellulite, measles, external otitis, and impetigo. [94] 1966

Resistance to Nalidixic Acid is found. [95] 1966 Doxycycline antibiotics are synthesized. It is currently used to treat tuberculosis, bacterial pneumonia, early Lyme disease, chlamydia, syphilis, and cholera. [96] 1966

Resistance is observed against cephalothin. [97] 1967

First is developed clindamycin. It is commonly used for treating a variety of infections caused by bacteria. [98] 1968 Antibiotic rifampicin is used for medical practice. [99] 1968

Resistance to Tetracycline is found. [100] 1968 Introduced Trimethoprim. It is primarily used for urinary infection management. [101] 1969 Fosfomycin was found. It has a broad spectrum of action towards a vast number of Gram-negative and Gram-positive bacteria.

[102]

1970 Non-toxic, semi-synthetic acid-resistant flucloxacillin isoxazolyl penicillin is incorporated into clinical practice. [103] 1971

Tobramycin is a discovered aminoglycoside antibiotic. It is used to treat different forms of bacterial infections, especially Gram-negative infections. [104] 1971 Mupirocin is isolated from Pseudomonas fluorescens. [105] 1972

The beta-lactam antibiotic cephamycin C is first isolated from the broad extracellular spectrum. [106] 1972

Minocycline is discovered as an antibiotic. It has antibacterial and anti-inflammatory effects. Minocycline is used in acne treatment and against several infectious diseases. [107] 1972 Tinidazole is introduced. It is an antiparasitic drug used against infections of protozoa. [108] 1973

Carbenicillin is discovered as a bactericidal antibiotic. Carbenicillin is resistant to bactericidal action and beta-lactamase. [109] 1974 It is a commercially available antibiotic trimethoprim/sulfamethoxazole. [110] 1974

Cotrimoxazole is introduced. It is used in the treatment of many bacterial infections, including bronchitis, pneumonia, intestine infections, urinary tract, and skin [111] 1976

The discovery of antibiotic amikacin. Amikacin has a broad spectrum towards a wide range of Gram-negative species, including pseudomonas, Escherichia coli, and certain Gram-positive species, such as Staphylococcus aureus. [112] 1978 Cefoxitin comes in as an early cephamycin. [113] 

The glycopeptide class of teicoplanin is discovered. Teicoplanin is used in the prophylaxis and treatment of severe Gram-positive bacterial infections, including Enterococcus faecalis and methicillin-resistant Staphylococcus aureus. [114] 1979 Patent on cefaclor antibiotics. It is used to treat such diseases of the bacteria, for example, pneumonia and eye, lung, ear, urinary tract, and throat infections. [115] 1981

Resistance to beta-lactamase is found at AmpC. [116] 1981

The first fluoroquinolone, the ciprofloxacin, is discovered. [117] 1983

Resistance is found to extended-spectrum-beta-lactamase. [118] 1985 Discovery of daptomycin, an antibiotic. [119] 1985

Carbapenems are introduced. They are widely used to treat severe bacterial or high-risk infections. [120] 1986

An enterococcus immune to vancomycin is identified. [121] 1987

It is used to treat endocarditis, intra-abdominal infections, sepsis, pneumonia, joint infections, and UTI. [122] 1987

Extremely powerful fluoroquinolones are introduced. They are used to treat various disorders, such as the urinary tract and respiratory infections. [123] 1987

Resistance is observed against cephalosporins. [124] 1987

Resistance is observed against carbapenems. [125] 1990

Resistance to fluoroquinolone is found. [126] 1993

It is used to treat bacterial infections such as bronchitis, diarrhea, sexually transmitted diseases (STDs), and ear, lung, sinus, nose, mouth, and reproductive organs infections. [127] 1993 Antibiotic clarithromycin is introduced. It is used in the prevention and treatment of certain bacterial infections. [128] 1994 Cefepime moves into clinical practice. It is licensed to treat mild to severe infections. [129] 1997 Staphyloccocus is reported to be immune to vancomycin. [130] 1999

The quinupristin/dalfopristin antibiotic is approved. [131] 2000 It uses oxazolidinones. These synthetic drugs are active towards a wide variety of Gram-positive bacteria. [132] 2000 For treating infections caused by Gram-positive bacterial resistance to other antibiotics, antibiotic linezolid is introduced.

In the European Union, antibiotic telithromycin is approved. [134] 2001

Broader-spectrum fluoroquinolones are introduced.

[135]

2002

Resistance is observed against linezolid. [136] 2002 FDA accepts cefditoren, ertapenem and pivoxil. [137] 2002 Staphylococcus aureus is confirmed to be vancomycin-resistant. [138] 2003

Introduce lipopeptides as antibiotics. [139] 2003 Daptomycin is used by Gram-positive species to combat chronic and life-threatening infections. [140] 2004 Telithromycin is introduced [60] . Certain cases of pneumonia are treated with this drug. [141] 

Antibiotic tigecycline is used for the prevention of intraabdominal infections and skin and skin system infections. [142] 2011 FDA recommends fidaxomicin to treat Difficile Infection in clostridium. [143] 2012 FDA recommends bedaquiline for multidrug-resistant tuberculosis therapy. [144] 2013 FDA recommends telavancin for the prevention of pneumonia in hospitals caused by susceptible Staphylococcus aureus. [145] 2013 Centers for Disease Control and Prevention identified 17 antibiotic-resistant micro-organisms in the United States, which caused at least 23,000 deaths. [146] 2015

The American fast-food company McDonald's announces it will phase out its antibiotic-containing meat products. [147] 2016

In the United States, ceftazidime/avibactam was approved for use. [148] 2016 Natural antibiotic teixobactin is present in an uncultivated bacterial screen. Without detectable resistance, it is found to kill pathogens. [149] 2017

Scientists develop new, safe, and simpler formulations of teixobactin-a next-generation antibiotic that beats multidrug-resistant infections such as methicillin-resistant Staphylococcus aureus. [150] 2018

The antibiotics called odilorhabdins, or ODLs, are produced by symbiotic bacteria living in nematode worms that colonize food insects in the soil.

[151]

A new family was synthesized using the so-called peptidomimetics. [152] 2020

The newly-found corbomycin and the lesser-known complestatin have an unparalleled method of destroying bacteria which is accomplished by blocking the bacterial cell wall structure. [153] 2021 Tebipenem hydrobromide is an oral carbapenem antibiotic in development for the treatment of complicated urinary tract infections (cUTI), including pyelonephritis, caused by susceptible microorganisms. [154] 2021 Cefiderocol: A new cephalosporin stratagem against multidrug-resistant Gram-negative bacteria for treating complicated urinary tract infections and nosocomial pneumonia based on clinical trials demonstrating noninferiority to comparators.

[155]

Antibiotics can be classified according to their mode of action, the spectrum of the action, or their chemical structure. Bactericidal or bacteriostatic antibiotics may be commonly present across the Gram-negative and Gram-positive spectrum [156] . Depending on molecular structure, they can be classed as macrolides, β lactam, aminoglycosides, glycopeptides, tetracycline, and quinolones. The bacteria are either bacteriological or bacteriostatic; the targets can be of a wide variety (Gram-negatives or Gram-positive bacteria) [5] .

β-Lactam inhibits the growth of bacterial cell walls by binding penicillin-binding enzymes (PBPs). PBPs perform the function of connecting the peptide units in the peptidoglycan sheet. After βlactams are connected to PBPs, cell lysis occurs. The lactam antibiotics are also divided into monobactams, cephalosporins, carbapenems, carbacephems, and penicillins. Penicillin-resistant bacteria were reported to appear in the late 1960s. The enzymes β-lactamases, which could degrade β-lactam antibiotics, were synthesized by these bacteria. However, the emergence of carbapenem, the new class of β-lactams, solved this problem as carbapenem is not sensitive to the β-lactamases. Carbapenems exhibit the broadest spectrum of activity of all of the recognized lactams [5] . However, some bacterial species showed resistance to carbapenem [157] .

Glycopeptides also attack the synthesis of bacterial cell walls, and additionally, they block the PBPs and inhibit peptidoglycan synthesis [5] . By attacking protein synthesis in the cell's tetracycline, macrolides, oxazolidinones, and aminoglycosides block bacterial growth. The binding of macrolides to the 50S ribosomal subunit causes the inhibition of mRNA elongation during translation [5] . Oxazolidinones are also connected to the 50S subunit; however, they inhibit protein synthesis by inhibiting the development of a 70S initiation complex similar to macrolides [158] . These two groups combined make up the 50S category of blockers. Aminoglycosides and tetracycline attach to the ribosomal 30S subunit that prevents the utilization of aminoacyl-tRNA to the ribosome, thus inhibiting the synthesis of proteins. Tetracycline and macrolides are typically bacteriostatic, while the mode of action of aminoglycosides is broadly bactericidal [5] .

Nucleic acid synthesis is necessary for cell survival. Quinolones inhibit bacterial growth by inhibiting the operation of helicases in DNA which, just before reproduction or repair of DNA, are crucial for relaxing DNA double-helical structure. Quinolones also interfere with bacterial functions of topoisomerase II and topoisomerase IV, which negatively impact RNA polymerase and thus inhibit the synthesis of RNA [5] .

The para-aminobenzoic acid (PABA), a substrate for synthesizing folic acid used in bacterial cells, is imitated by sulfonamides structurally. Sulfonamide avoids cell division and causes the inhibition of the growth of bacteria, and it is necessary for the synthesis of nucleic acid. Regrettably, these modern antibiotics have been detected in bacteria which makes it difficult to treat infections due to these bacteria [159] (Figure 2 ).

Antibiotic resistance is considered present when a drug begins to lose its ability to successfully suppress bacteria growth. In the presence of active antibiotics, bacteria are "immune" and continue to divide. Bacteria are called resistant bacteria when they replicate even in the presence of antibiotics [160] . If the microbes are less susceptible or resistant, an effect greater than the usual concentration of the same drug is needed. Antimicrobial resistance has been found immediately after the launch of new antimicrobial compounds [161] . The mechanism of natural selection, in which evolution allows all bacteria to have a degree of low resistance, may partly explain antibiotic resistance [162] .For instance, one study confirmed that sulfamethoxazole and trimethoprim (TMP-SMZ), ampicillin, and tetracycline, commonly used in earlier years, now no longer play a role in Thailand's treatment of non-cholera diarrhea [163] . However, a study in Bangladesh demonstrated the effective therapeutic use of the same drugs [164] . Even before the use of antibiotics in infection control, resistance has been documented [165] . 

Antibiotic resistance is considered present when a drug begins to lose its ability to successfully suppress bacteria growth. In the presence of active antibiotics, bacteria are "immune" and continue to divide. Bacteria are called resistant bacteria when they replicate even in the presence of antibiotics [160] . If the microbes are less susceptible or resistant, an effect greater than the usual concentration of the same drug is needed. Antimicrobial resistance has been found immediately after the launch of new antimicrobial compounds [161] . The mechanism of natural selection, in which evolution allows all bacteria to have a degree of low resistance, may partly explain antibiotic resistance [162] .For instance, one study confirmed that sulfamethoxazole and trimethoprim (TMP-SMZ), ampicillin, and tetracycline, commonly used in earlier years, now no longer play a role in Thailand's treatment of non-cholera diarrhea [163] . However, a study in Bangladesh demonstrated the effective therapeutic use of the same drugs [164] . Even before the use of antibiotics in infection control, resistance has been documented [165] .

Agricultural antibiotics are typically identical and adjacent to commonly used antibiotic compounds [166] , which can also encourage drug resistance. The food chain may Agricultural antibiotics are typically identical and adjacent to commonly used antibiotic compounds [166] , which can also encourage drug resistance. The food chain may be viewed as the primary route of spreading antibiotic-resistant bacteria between the animal and human populations. Livestock obtains antibiotics from food, water, or parents who may bear microbial resistance to a specific antibiotic [166] . Antibiotic resistance in livestock feed increases with the use of antibiotics as growth promoters [167] . According to the study of the rural villages in Barcelona, a fecal carrier of Quinolone-resistant Escherichia coli was reported in one-fourth of the babies, the possible source of which could be poultry or swine. These children have been exposed to quinolones [168] (Table 2 ). 

Streptococcus Pneumoniae Multiple drugs [169] Streptococcus pyogenes Tetracyclines, macrolides [170] Mycobacterium tuberculosis Multiple drugs [171] Escherichia coli Multiple drugs [172] Salmonella typhimurium Multiple drugs [173] Neisseria gonorrhoeae Penicillin, tetracycline, fluoroquinolones [174] Gonococci Quinolone [175] Enterobacteriaceae β-lactam (carbapenem), Quinolone [176] Pseudomonas aeruginosa Multiple drugs [177] Enterococcus Vancomycin [178] Staphylococcus aureus β-lactam (methicillin), Vancomycin [179] 3.3. Development of Antibiotic Resistance

As suggested above, bacteria seem to have a natural mechanism that promotes resistance. The resistance mechanism arises by mutations at the gene stage [180] . Selective pressure is caused by antibiotics, and even the genes function in accordance with selective pressure [181] . Bacteria possess the ability to transfer genetic material directly between themselves by transferring plasmids, meaning that natural selection may not be the only process through which resistance develops. The bacteria in a colony thus may mutate, resulting in resistance [182] . Broad-spectrum antibiotic drugs used in the treatment of nosocomial infections in health centers may, in fact, improve microbial resistance since large colonies of mutated bacteria are often found in such places [183] . Increased association between antibiotic-resistant infections and antibiotic use has been demonstrated [184] . Resistance development can also arise in cases where patients fail to complete the course of their prescribed medication. In such cases, the bacteria remain unaffected and become much more immune to the action of antibiotics [181] . Thus, bacteria can acquire multiple resistance characteristics over time and become immune to many antibiotic classes [185] [186] [187] . Some FDA-approved antibiotics for the treatment of microbial infections and their resistant microbes are listed in Table 3 .

The Antibiotic resistance in bacteria develops through the mechanisms shown in Figure 3 :

Antibiotic enzyme inactivation/degradation; an endogenous cellular enzyme is modified to interact with that of the antibiotic in a manner in which the bacteria are no longer affected. B-lactamase enzymes are among the most important examples; they hydrolyze most commonly administered antibiotics, i.e., b-lactams (cephalosporin and penicillin), and are the most widespread source of antibiotic resistance in Gramnegative bacteria.

The excretion of the drug through efflux pumps; Bacteria are triggered to eliminate the antibiotic by stimulating the proteins that can eradicate an extensive range of substances from the periplasm to the outside cell. This is a mechanism of resistance especially essential for P. aeruginosa and Acinetobacter spp.

Reduced absorption by variations in the external membrane permeability; these changes inhibit the successful entry of antibiotics.

Drug target modifications to weaken or demolish the antibiotic binding efficacy and thereby minimize its potential. 

Antibiotic production is no longer deemed an economically viable strategy for pharmaceutical companies [11] . Because antibiotics are widely used and are primarily curative, they are less effective in managing conditions related to diabetes, psychological disease, asthma, or gastrointestinal complications [11, 189] .

An annual cost-benefit study by the Office of Health Economics in London reports 

Antibiotic production is no longer deemed an economically viable strategy for pharmaceutical companies [11] . Because antibiotics are widely used and are primarily curative, Antibiotics 2021, 10, 1473 15 of 61 they are less effective in managing conditions related to diabetes, psychological disease, asthma, or gastrointestinal complications [11, 189] .

An annual cost-benefit study by the Office of Health Economics in London reports that the current net value of the new antibiotic is $50 million compared with about 1 billion dollars in neuromuscular condition treatment drugs [11] . The expense of modern antibiotics is typically USD 1000-USD 3000 a year, while USD 100-USD 1000 is spent on cancer chemotherapy [11, 190, 191] . The effectiveness, usability, and generally lower prices of antibiotics have, on occasion, resulted in poor evaluation from investors and the general public [190] .

Furthermore, restricted use of antibiotics has been recommended by microbiologists and infectious disease specialists [190] . In some cases, healthcare professionals limit the use of the latest medication, believing it might promote resistance, and instead, continue administering current antibiotics that have shown equivalent effectiveness prior to the introduction of a new antibiotic [190] . New drugs are therefore often used as the "last line" of defense medicine in the fight against severe diseases. Such a method limits the usage of modern drugs and reduces investor returns [190] . Many pharmaceutical companies fear that the million-dollar investments required to develop new antibiotics may provide inadequate returns [189] [190] [191] . Graph 1 shows a relative decrease in the manufacturing of new antibiotics over a period of time ( Figure 4 ). 

Nanotechnology-based approaches rang from the engineering and material sciences to biology and medicine. Materials with dimensions between 1-100 nm are commonly referred to as nanomaterial. They vary in shapes and sizes to help give characteristic features for a large spectrum of uses. The properties of the material undergo significant changes when limited to a rather small scale. Health sciences have shown considerable interest in various applications of nanotechnology. Nanomaterials are usually metal and metal oxides or their composite, carbon-based, and emulsion-based. They are cost-effective and can fight antibiotic-resistant bacteria. Approximately 10 million deaths by 2050 are predicted due to the growing risk of antibiotic resistance [192] . Nano-based technologies can offer a long-term and effective approach to managing drug resistance.

The protection of ceramic matrixes has been in use for over 4500 years, including the use of organic asbestos nanofibers [193] . More than 4000 years ago, the ancient Egyptians used NMs for synthesizing five nm diameter lead sulfide (PbS) nanoparticles (NPs) for hair dye [194] . NMs were based on the synthetic chemical process. "Egyptian blue" was the first synthetic stain produced and utilized by the ancient Egyptians in the third century BC with a synthetic combination in the range of nanometer-sized quartz and glass 

Nanotechnology-based approaches rang from the engineering and material sciences to biology and medicine. Materials with dimensions between 1-100 nm are commonly referred to as nanomaterial. They vary in shapes and sizes to help give characteristic features for a large spectrum of uses. The properties of the material undergo significant changes when limited to a rather small scale. Health sciences have shown considerable interest in various applications of nanotechnology. Nanomaterials are usually metal and metal oxides or their composite, carbon-based, and emulsion-based. They are cost-effective and can fight antibiotic-resistant bacteria. Approximately 10 million deaths by 2050 are predicted due to the growing risk of antibiotic resistance [192] . Nano-based technologies can offer a long-term and effective approach to managing drug resistance.

The protection of ceramic matrixes has been in use for over 4500 years, including the use of organic asbestos nanofibers [193] . More than 4000 years ago, the ancient Egyptians used NMs for synthesizing five nm diameter lead sulfide (PbS) nanoparticles (NPs) for hair dye [194] . NMs were based on the synthetic chemical process. "Egyptian blue" was the first synthetic stain produced and utilized by the ancient Egyptians in the third century BC with a synthetic combination in the range of nanometer-sized quartz and glass [195] .

The synthesis by chemical methodologies of the metallic NPs dated back to the 14th century BC when Mesopotamians and Egyptians began the manufacture of glass from metals that could be referred to as the beginning of the metal nanoparticles era [196] . These materials may be the first experimental cases of synthetic NMs. In Frattesina di Rovigo (Italy), a red glass colored by Cu nanoparticles surface excitation was discovered during the late Bronze Age (1200-1000 BC) [197] . Likewise, it is recorded that Cu NPs and cuprous oxide (cuprite Cu 2 O) were found in Celtic red enamels from 400-100 BC [198] . However, the most notable example of prehistoric metallic NPs is a Roman glass workpiece [199] . The Mesopotamians began to use glazed ceramics for metallic decorations in the 9th century [193] . Moreover, clay minerals with a size of a few nanometers are the most ancient example of nanomaterial. In 5000 BC, in Cyprus, clay was used to bleach clothes and wool [200] . The synthesis of an AuNP colloidal solution, which was the very first scientific effort in NP preparation, was documented in 1857 by Michael Faraday. This was apparently among the first publications that detected and explored quantum-size effects. The cause of the particular colors of metal colloids was later explained by Mie in 1908 [201] . In the 1940s, SiO 2 NPs were developed to provide rubber insulation to replace carbon black [202] . Today, manufactured nanomaterials can significantly enhance the properties of bulk materials with respect to their strength, conductivity, resilience, and lightness and can offer beneficial applications and serve as structural and detecting materials for protection. Despite other potential applications, taking advantage of the favorable shape and size to enhance the appearance of materials remains the primary use of NPs.

In 2003, Samsung launched the antibacterial technology Silver Nanomic TM from ionic AgNPs in their air conditioners, washing machines, air purifiers, and cooling systems [203] . In auto production, NPs and nanostructured materials (NSMs) are commonly used as tire fillers to improve adherence to the surface, car body fillers to improve stability, and translucent layers for heating, mist, and ice-free window panes [204] . By the end of 2003, Mercedes-Benz launched an NP base coat for metallic and nonmetallic surfaces in series production. The coating improves the rubbing resistance and strengthens the gloss. The latest studies concentrated on the production of specialized earth-based astronomical telescopes with adaptive optics and magnetic mirrors with ferrofluid shape-shifting potential [205] . In solar cells with dye sensitization potential, TiO NPs are widely used [206] . In 2012, Logitech launched the first large commercial usage of dye-sensitized solar cells, an external light-powered iPad keypad. Abraxane TM was developed in 2005, sold, and launched on the pharmaceutical market as a human serum-albumin NP substance comprising paclitaxel [207] .

In the 1980s, the advance in nanotechnology allowed Nano-scale construction by the tracking of atomic particles. Subsequently, nanotechnology has become important in diverse areas like biomaterials, organic chemistry, medicine, and others. In the medical science and healthcare industry, nanomedicine and nano-scale particles [208] are used for therapeutic purposes, as biomaterials, and diagnostic tools [209] . Thus nanomaterials and future molecular nanotechnology are widespread medical applications [210, 211] . Nanotechnology has made many difficult diagnoses possible and has expanded the knowledge of disease pathogenesis. Many medications and procedures are seriously impacted because of their poorer efficacy, usefulness, and adverse effects. As the scale of nanoparticles is close to biological molecules and forms, in vivo and in vitro therapeutic strategies and higher specificities are useful [208] . Higher specific activity medications can increase effectiveness and decrease adverse effects. Smaller-sized nanoparticles may have treatment application in the high-risk areas, reducing the potential harm and delivering the exact medication dosage required.

Despite their past therapeutic successes, the use of antibiotics became problematic at the beginning of the 20th century [212] , with the development of drug-resistant bacteria brought on partly through their extensive use [213, 214] . Increased pathogen antibiotic resistance to colistin [215] , carbapenems [216, 217] , and tigecycline [218] , and stalled production of new antibiotics made it impossible to cure the contagious disease caused by harmful pathogens. Even though a new antibiotic may be found, it could not provide a guarantee of its effectiveness against all multi-drug-resistant infections [219] . Nonetheless, the threat to public health is real since both the Gram-negative and Gram-positive multiple-drugresistance bacteria are developing faster than ever [220] . Thus, technological developments must aid the efforts against these dangerous pathogens and help meet the long-term demand for successful treatment of drug-resistant bacterial infectious disease [221] .

The latest developments in the production of medicinal nanomaterials may benefit the purpose of antibiotics. Theoretically, nanoparticles are a modern class of bacterial antimicrobials and synthetic pathogens. Nanoparticles as antibiotics can hopefully minimize resistance and support the efficient delivery of antibiotics [222] . Recent research suggests that certain antimicrobial-activated metal nano constructs have indeed helped combat infectious diseases [223] . Such constructs benefit from lower toxicity, lower cost, and better pharmacokinetic factors while helping to eliminate drug-resistant bacteria. Their most significant benefit is that they maintain their efficacy longer than traditional antibiotics, which is extremely valuable in the long-term sustained therapeutic effect [224] .

The nanomaterials are classified into four categories:

1.

Carbon-based nanomaterial 2.

Inorganic nanomaterial 3.

Organic-based nanomaterial 4.

Composite-based nanomaterial

These nanomaterials typically have carbon and are found in spheres, ellipsoids, and hollow tubes. The types of carbon-based NMs include Fullerenes (C60), Carbon Nanotubes (CNT), Carbon nanofibers, Carbon Black, Graphene (Gr) [225] (Table 4) .

CNTs reported by 1991 are cylindrical informs connected with covalent bonds [226] . Multiwalled nanotubes and single-walled (SW) nanotubes have various types of single pipe CNTs 1-5 nm in diameter, and multiple nested tubes of lengths ranging from 100 nm to micrometers, respectively [227] . The cytotoxic influence of CNTs has been shown in both in vivo and alveolar macrophages [228, 229] . The antimicrobial property of SWNTs indicates that their effective antibacterial and antiviral properties are based on the low aqueous dispersion of pure CNTs. The aqueous dispersion of CNTs has recently been demonstrated and could further be improved utilizing other surfactants or polymers. The best antimicrobial carbon-based nanomaterials identified are SWNTs. Initial interaction with bacteria, membrane dysfunction, and membrane oxidations are part of the SWNTs' action in preventing microbial growth [230] . The use of CNTs for purifying water, E. coli inactivation, and poliovirus are being gradually studied, and MS2 phage elimination is also being investigated [231] . Thus far, CTTs offer relevant materials that can be used as antimicrobial agents.

Fullerenes are ball clusters made up of atoms of carbon [232] . Antimicrobial activity was observed in fullerenes against many bacteria, including Salmonella, Streptococcus spp, and E. coli [232] . It Is suggested that their antibacterial activity was induced by energy metabolism inhibition after nanoparticles were internalized into the bacteria [233, 234] .

It was proposed that fullerene compounds prevent bacterial growth by destroying the respiratory chain [235] .

The antibacterial efficacy of a sulfobutyl fullerene derivative in environmental bacteria was assessed by Yu et al. (2005) . They observed that after photoirradiation, the used derivatives could inhibit environmental bacteria [236] . Mizuno et al. (2011) have also stated that cationic replacement fullerene derivatives are highly successful in destroying a large variety of microbial cells following the white light irradiation. A new generation of synthetic fullerenes was tested against Gram-negative and Gram-positive bacteria and whether they carry basic or quaternary amino groups.

Graphene is generally referred to as a monolayer of carbon atoms, closely enclosed within a 2-dimensional crystal [237] . The GO Nanosheets are created by the chemical modification of graphene with suspended epoxyl, hydroxyl, and carboxyl groups that can be dispersed rapidly into water. The membrane stress is known to constitute the critical antimicrobial function of GO through direct interaction with sharp Nanosheets [238] . The inhibitory effects on E. coli growth were demonstrated by both graphene and GO. Testing antimicrobial effects on graphene sheets was performed by Akhavan and Ghaderi (2010), confirming that the direct relationship of extremely sharp edges and bacteria has resulted in RNA effluxes by impaired cellular membranes of both Gram-positive and Gram-negative bacterial membranes. The antimicrobial effects of the two active GO nanostructures (graphene oxide-chlorophyllin and graphene oxide-chlorophyllin-Zn) on E. coli were reported by Azimi et al. (2014) . The authors suggested that E. coli was affected by the functional GO.

Silver has been used as an antibacterial agent for many years. Applications of silver as metal and metal oxide nanoparticles are included in nanomaterials. These nanomaterials can be synthesized into metals such as Ag or Au, metal oxides such as ZnO and TIO 2 NP, and semiconductors such as ceramics and silicon. A few of these demonstrate high antimicrobial activity towards certain bacteria, viruses, and other microbes. Specific nanomaterials with strong antibacterial efficacy are thought to have high volume to surface ratios as well as a unique chemical-physical property [239] (Table 4) .

Silver as an antibacterial agent has been used in various ways; as silver nitrate, silver sulfadiazine, and powdered silver for infectious diseases, dental research, catheters, and burned wound treatment [240] . The development of antibiotics in the 1940s limited the use of silver as an antibacterial agent. However, the emergence of antibiotic-resistant bacteria and diminished antibiotic efficaciousness has resurrected the therapeutic use of silver [241] . AgNPs are found suitable against almost all viruses, bacteria, and other eukaryotic microorganisms in various types of metal and metal oxides [242, 243] . The effectiveness of AgNPs as antimicrobial agents depends entirely on their size and shape [244] . Mechanism of action of AgNP targets the cell division and respiratory chain, eventually destroying the cell [245] . Increased synergistic antimicrobial actions against Gram-Positive and Gram-Negative bacteria have been reported, resulting from the action of AgNPs in conjunction with conventional antibiotics such as vancomycin, erythromycin amoxicillin, and penicillin G [246] .

Further studies suggested that Ag + ion, which has a sulfur and nitrogen affinity, can suppress and destroy the protein structure by binding it to thiol and amino groups [247] . Lastly, silver NMs have been reported as photocatalytic [248] and capable of triggering reactive oxygen species ROS [249] [250] [251] . Some have denied that this effect is cell-type dependence, at least in eukaryotic cells [242] . Silver has a broad spectrum of applications, from injury dressing to surgical device coating and manufacturing applications. Often there are negative health consequences associated with the use of metallic silver [252] . These adverse effects include permanent skin pigmentation (argyria) and eye loss, organ destruction, inflammation, and changes in the blood cell count [253] . However, amounts of AgNPs commonly used, and the concentration-dependent toxicity that influences the mitochondrial activity (possibly responsible for AgNPs toxicity) is still below observation [254] .

Gold coating on carbon nanotubes improves drug production. Gold nanoparticles have been used to identify bacteria by adjusting colors to facilitate cytometry flow responsiveness. Gold nanoparticles' action as antimicrobial agents is primarily based on the electrostatic appeal to the cell membrane's negative-loaded bilayer; the suggestion has also been supported by the discovery that anionic particles are not toxic while cationic particles are [243] . Near-infrared (NIR) light can absorb gold nanocages, nanoparticles, nanorods, and nanoshells often used to cure a bacterial infection under intense laser beams of sufficient wavelength [252] . AuNPs, coupled with antibiotics or antimicrobials, were shown to have elevated effectiveness, and modifications have been studied of the specific antimicrobial effects [255] . In addition, bacterial killing was attributed to the intense laserinduced hyperthermic effect couped with the bubbles forming around cluster AuNPs [256] . The gold nanoparticles have been found to cause strong antimicrobial effects on Gramnegative and Gram-positive bacteria with an antibiotic (i.e., streptomycin-coated Au NPs, gentamicin, and neomycin). In contrast with conventional free ampicillin, nanotechnology advances show that AuNPs coated with chitosan and ampicillin demonstrate at least a twofold rise in their antimicrobial activity [243] . Gold nanoparticles encourage adjuvants to replace antibiotic therapy to treat severe bacterial infections, including multi-drug-resistant bacteria, with low doses and minimal adverse effects.

Zinc, as a metal oxide, an antibacterial agent ZnO NPs, and its antibacterial activity can conserve agricultural goods and food against specific foodborne bacterial pathogens such as E. coli [242, 257] . ZnO NPs' less expensive production, the ability to obstruct UV, and its white appearance make it more useful than Ag NPs. It showed the peerless capability of the multilayer avowal of Nano-ZnO on cotton fabric with antibacterial activity against S. aureus on its analysis part [258] . ZnO NPs' potential to destroy the bacteria by destroying the cell membrane (proteins and lipids) and removing the intracellular material makes them suitable antibacterial particles. The ZnO-based nanoparticles are additionally broadspectrum bactericidal NM [259] and have shown a wide variety of antibiotic activity against different microbes that mainly depend on the particle size and concentration chosen [260] . In addition, it also generates H 2 O 2 and Zn +2 ions vital to bacterial cells [260] . Polyvinyl alcohol (PVA)-veiled ZnO shows enhanced permeability of the membrane, cell idealization, and intracellular structural adjustments [261] .

Titanium Dioxide (TiO 2) is a nontoxic antimicrobial with a potential bactericidal application. It is most frequently employed as a photocatalyst disinfecting material. Titanium dioxide nanoparticles (TiO 2 NPs) have been widely studied and compared with other preferred nanoparticles to assess their antimicrobial photocatalyst activity [262] . The inhibition of microbial growth is found to be higher after irradiation with near-UV light, and the bactericidal behavior of TiO 2 NP improves noticeably when combined with UV-A [263] . TiO 2 behavior largely depends on the scale, intensity, and wavelength of light (100-1000 ppm levels are required to destroy bacteria). The UV-A irradiated TiO 2 antibacterial agent has shown reduction efficacy in microbial growth (in the declining order) of P. aeruginosa, E. coli, S. aureus, C. albicans, and E. faecium based Cell membrane [264] . It was also suggested that the antibacterial photocatalytic efficacy of TiO 2 conditional density of the microbial surface morphology starts to fall in the sequence of viruses > bacterial wall > bacterial spores [264] . Growth inhibition characteristics of TiO 2 NPs with UV-A irradiation show inhibition against Enterobacter cloacae, E. coli, and P. aeruginosa were surprisingly less successful against Enterobacter cloacae than P. aeruginosa and E. coli [265] .

Reactive oxygen species (ROS) production, free hydroxyl radicals, and peroxides render TiO 2 a useful antibacterial photocatalytic agent [266] . TiO 2 NP oxidative strike has been attained with hydroxyl radicals (potent oxidants) created from TiO 2 photocatalyst, which have broad (nonselective) reactivity and mainly attack microbial surfaces. The composition and the integrity of the cell wall are essential to sustain semi-permeability, respiration, and other phosphorylation reaction. TiO 2 NPs photocatalytic action can interrupt the normal cell function compromising the bacterial cell membrane structure. The TiO 2 photocatalyst action leads to lipid peroxidation reaction (oxidative lipid degradation), which subsequently leads to cell death [267] . Thus, while the usage of radiation improves the photocatalytic antibacterial activity of TiO 2 NPs, it also causes individual bacterial mortality from irradiation [268] . The potential for visible light activation (e.g., sunlight) makes TiO 2 far more remarkable antibacterial agent possible.

Metal doping improves the TiO 2 antibacterial properties, leading to enhanced bacterial and viral photocatalytic inactivation [269] . Composite Ag/(C, S)-TiO 2 NPs have shown strong light-independent antimicrobial activity when tested against B. subtilis and E. coli spores [270] . TiO 2 can also be used as a low-cost, high-efficiency, stable, nontoxic alternative to traditional chemical disinfectants, which may produce toxic byproducts, and as such, it would be of particular value for water treatment systems in developing countries. [227] . TiO 2 reactivity toward microorganisms can be applied to improve food safety, hygiene, and cosmetics using TiO 2 photocatalytic disinfection of nanocomposite antimicrobial surface coating capable of destroying UV radiation-tolerant microbes [269] . TiO 2 nanocomposite surface coating for orthodontic products, toothbrushes, dental implants, and screws has shown effective antibacterial activity against Lactobacillus acidophilus [266] .

Copper is a beneficial antibacterial agent since it is a structural part of many microorganism enzymes. When Cu 2+ ions are high, ROS can be formed, disrupting amino acid formation and a more toxic DNA [271, 272] . The basic principle behind copper microbial inactivation is the so-called contact-killing. Other antimicrobial mechanisms such as inoculation methods and incubation period, which are important, also rely on the copper contact method. The efficiency of this touch extinction has been improved by factors such as elevated temperatures [273] , high metal content in copper [274] , and decreased relative moisture [275] . Cu NPs with great affinity to the amines and carboxyl group on the surface of the organism kill Bacillus subtilis and have demonstrated better action than Ag NPs [276] . The chemical and physical quality of copper oxide (CuO) compared with silver is less expansive [277] .

The bacterial cell wall was damaged at a higher concentration of aluminum oxide (Al 2 O 3 ) nanoparticles [278] . Alumina NPs are high-temperature thermodynamically stable particles. The chemical arrangement includes oxygen atoms that fill a matrix to two-thirds of the octahedral sites [278] , which conform to hexagonally wrapped alumina ions. The aluminum oxide NPs had an effect on the surface charge, shape, and particle size [279] . In contact with organic matter, nanoparticles appear to mix with hard water and seawater in soil. Such aggregations rely on the pH and salt content of the particles. Most toxicity studies focus on the detailed configuration and characterization of the solution parameters, including thickness, distribution, structure, morphologies, surface areas, surface chemistry, and particle reactivity. They are believed to have moderate inhibitory properties and may be used in combination. Ag/Meso-Al 2 O 3 nanoparticles displayed extensive S. aureus and P. aeruginosa inhibitory activity.

Nitric oxide (NO) has an immune function as a diatomic free radical and is an effective antimicrobial agent acting against infection in two ways; at a low concentration at which it promotes the growth of immune cells, and at a high concentration where it inhibits or kills pathogens (via binding with DAN, proteins, and lipids). For combination therapy, NO is commonly used, but the performance of individual NO donors, based on sparse evaluation, shows limited results. The difficulty of processing or administering NO as an antibacterial agent has been a restricting factor. Lately, a strong trend of vulnerability has been found in Gram-negative and Gram-positive bacteria, including methicillin-resistant Staphylococcus aureus, by utilizing a gaseous NO (gNO) donor delivery platform [280] .

NP-based scaffolding could hold large NO loads, which can be released at appropriate sites, physiological pH, or temperature under aquatic conditions [281] . The NO and NOreleasing Silica Nanoparticle antibacterial experiments have been conducted to destroy Gram-positive and Gram-negative fungi and bacteria. In vitro MRSA study has shown pathogen behavior in silane with nanoparticles releasing NO [280] . These nanoparticles can associate with the pathogen surface causing pathogen inhibition and leading to bactericide. The NO-releasing NPs are versatile with unique properties dependent on nanoparticles' size and adjustable NO donor design. NO-releasing NPs have been used for treating contaminated wounds and subsequently for successful healing of wounds in diabetic mice [282] . Human studies have been limited thus far, but given the versatility and potential of NPs that make them highly suitable for NO delivery, there is a need for intensified research into the human application of this technology.

Magnesium oxide (MgO-NPs) is an essential mechanism behind antimicrobial activity; it produces ROS and other nanoparticles [283, 284] . MgO-NPs are associated physically with the cell surface as some other nanoparticles and cause a dysfunction of the cell membrane integrity which contributes to membrane leakage [8] . Therefore, MgO-NPs destroy the cells through intracellular biomolecules irreversible oxidation. Furthermore, some studies have shown that with the lack of lipid peroxidation and ROS, MgO-NPs generate a high antibacterial effect. Research suggests that the relationship between MgO-NPs antibacterial behavior and nanoparticle association to the microbial cellular membrane changes pH and releases Mg +2 [285] . Moreover, the antibiotic behavior of MgO-NPs was found to be caused by the adsorption of halogen molecules onto the exterior of MgO [8] .

Iron oxide nanoparticles are highly ferromagnetic and have reduced oxidation sensitivity. There has been considerable attention towards iron oxide nanoparticles since they are known as nontoxic and biologically compatible materials because of the presence of Fe (II/III) ions [286] . Release and termination of toxic ions, oxidation damage caused by catalysis, the ion cell membrane transport activity variation, and lipid peroxidation or surfactant products are chemical pathways associated with reactive oxygen species (ROS). In nanotoxicology, ROS is considered a key rudimentary chemical mechanism, which can result in secondary processes that can eventually destroy cells and even cause cell death. In addition, ROS are a major inflammatory factor. The inflammatory action is believed to occur by up-regulation, stimulated by the activation of specific transcription factors in genes involved in a proinflammatory response (NF-ŢB, AP-2). Cell stability can also be directly affected by free radical formation [287, 288] . Nano-bio-interface physical processes are primarily governed by particle size and surface properties. They involve membrane function, membrane transport mechanism destruction, protein conformation or folding, and the accumulation of proteins [289] . The iron oxide nanoparticles can impede the production of B. subtilis as well as E. coli. The maximum inhibition (29 mm) in S. aureus compared to E. coli and P. aeruginosa was observed with 015 mg/mL of iron oxide nanoparticles [290] . In another analysis, Fe 2 O 3 and Ag/Fe 2 O 3 were found to have antibacterial properties, and nanoparticles against S. dysenteriae had antibacterial activity much more significant than that of Fe 2 O 3 nanoparticles individually [291] .

SPION is a modern approach to using magnetic particles; it induces local hyperthermia in the presence of a magnetic field [292] or may otherwise be protected in other nano-materials. Biofilms can be penetrated and degraded by Ag and Au and their magnetic effect [293] [294] [295] .

Organic-Based Nanomaterials involve nanomaterial primarily composed of organic material, with the exception of inorganic or carbon nanomaterial. The use of noncovalent (weak) molecular interactions tends to convert organic nanomaterial into desired structures, including liposomes, micelles, dendrimers, and polymeric NPs. Compared with inorganic materials, organic antibacterial materials are known to be less stable in nature, particularly at higher temperatures (Table 4) .

A cationic homopeptide of L-lysine known as Poly-ε-lysine is effective against Grampositive and Gram-negative bacteria. Additionally, it acts against spores of B. subtilis, B. stearothermophilus, and B. coagulans [296, 297] . Some scientists have developed a technique to fight deadly antibiotic-resistant bacteria using nanocargos of gold nanoparticles (AuNPs) combined with ε-polylysine. These nanocargos were 15-20-fold more antibacterial compared with free poly-e-lysine when measured against carbapenem-resistant Acinetobacter baumannii (CRAB) referral strains and Staphylococcus aureus (MRSA) [298] .

The proven disinfectants are the quaternary ammonium compounds, including cetrimonium chloride, benzalkonium, and stearalkonium chloride. The antimicrobial action of quaternary ammonium compound relies on bash of the N-alkyl chain length and lipophilicity [299] .

The mechanism of electrostatic interaction between a positively charged compound moieties and a negative charge bacterial membrane, followed by the integration of the hydrophobic tail compound into a hydrophobic membrane core where structural enzymes and proteins are denatured, culminated in initial encounters with the bacterial wall [300] .

N-Halamine complexes comprise one or multiple covalent bonds between nitrogen and halogen, which are common imide, amide, or amine group halogenations that provide stabilization and gradual emissions into the atmosphere of freely activated halogen species. These oxidizing halogenic agents facilitate the direct transfer of the active substance to the required biological locations or isolation from the aqueous medium to the halogen-free medium. These free, reactive halogens cause a microbial cell to inhibit or inactivate [301] .

Polysiloxanes, linear silicone oxide polymers, are yet another major type of polymer. Sauvet et al. synthesized a block of copolymers and statistical siloxanes having ammonium quaternary salt as a lateral substitution. These polymers show high antimicrobial action against Escherichia coli and Staphylococcus aureus. In block polymers or statistical copolymers, there was no significant difference in the activity [302] .

Benzoic acid, phenol, and p-hydroxybenzoate esters are the most widely used disinfectants and preservatives. As monomers, the antibiotic activity of these compounds has Antibiotics 2021, 10, 1473 23 of 61 already been identified. Attempts were made to combine them into a polymer backbone to synthesize the new, improved activity of antimicrobial polymers. Phydroxyphenyl acrylate has been more beneficial for both bacteria and fungi in a descriptive analysis of the antimicrobial activity of p-hydroxyphenyl acrylate, p-2-propane oxyphenol [303] .

A broad spectrum of antimicrobial activity was found in quaternary ammonium compounds against both the Gram-positive and Gram-negative bacteria. Quaternary ammonium polyethylenimines (QPEI) provide a wide range of bacterial targets. When embedded in the different polymeric matrices, the polyamines have been shown to be an effective antimicrobial nanoparticles [304] . Polymers that have phosphonium quaternary or sulfonium groups have structures that are close to those of the compound ammonium quaternary group. Phosphonium-based polycationic biocides are more effective than quaternary ammonium salt polymers with respect to antimicrobial action. The NIPAAm and methacryloyloxyethyl trialkylphosphine chlorides experiments on water-soluble copolymer thermal sensitivity demonstrate that antimicrobial activity rises incrementally in polymer alkyl chain length and units of phosphonium in the polymer [305] .

Triclosan is among the most common antimicrobial agents. A Triclosan solution was combined with water-based styrene-acrylate emulsion, and Enterococcus faecalis was tested. Depending on an agar diffusion test, triclosan liberation relies mainly on the solvent, either nonexistent or very sluggish in water and relatively fast with n-heptanes [306] . In addition to organic/aqua solutions, triclosan has been integrated, and PVA nanoparticles, which are water-dispersible, display higher antibacterial activity in relation to Corynebacterium [307] .

The broad spectrum of antibacterial action has been identified in deacetylated chitin known as chitosan [308] . Chitosan nano-scale and its compounds have only recently been shown to possess antimicrobial action against microbes, viruses, and molds [309] . It is much more efficacious than bacteria against viral and fungal infections, and it has often been found to become more selective for Gram-positive than Gram-negative bacteria [306] . The molecular weight of Chitosan has a significant function in its antibacterial action, which also relies on variation in targeted bacteria's cell wall: low molecular weight chitosan exhibits strong antimicrobial effects towards Gram (−) bacteria and high molecular weight towards Gram (+) [310] . Mechanisms through which chitosan works as an antimicrobial agent are described in multiple hypotheses: a.

Adding it to the negatively loaded cell surface, inducing agglutination and even microbial cell permeation, allowing leaks of intracellular substances [309] . b.

Chitosan chelation characteristics used for the chelation of trace metals blocks the action of certain enzymes, causing cell death. c.

Fungal chitosan produced through host hydrolytic enzymes from the fungal wall prevents RNA and protein synthesis [310] .

Chitosan antimicrobial activities and water-soluble chitosan derivatives are observed to have significantly greater efficacy in combating bacterial membranes over others. Chitosan is a suitable, low-cost, and effective disinfectant for developing nations with a wide range of action and far less toxicity to mammalian cells [311] .

Composite nanomaterial consists of multiphase nanoparticles with a single nanodimensional layer that can either mix nanoparticles with other nanoparticles or combine nanoparticles with smaller or larger materials (e.g., hybrid nanofibers) or more complex frameworks, such as metalorganic framework systems (Table 4) .

Nano-composites in the ceramic matrix are primarily Al 2 O 3 or silicon carbide (SiC). Most of the research so far has shown that, after adding low-volume (approximately 10%) SiC particles of appropriate size and the heat pressure of the final mixture, the Al 2 O 3 matrix has shown significant strengthening.

In a study, the coating system with a nano-TiO 2 antimicrobial agent was used to prepare the antibacterial corrugating medium, and the antimicrobial efficacy was tested using the zone of inhibition approach. Furthermore, various concentrations of TiO 2 antimicrobial agents have been observed in the mechanical properties of corrugating media, such as thickness, rigidity, bursting strength, tensile strength, and folding tolerance [312] .

Nanocomposites in a metal matrix (MMNC) refer to materials that comprise a matrix of a ductile metal or alloy that are implanted in a nano-sized reinforcing material. Metallic and ceramic materials combine these composites.

Metal nanocomposite active antimicrobial packages are developed by the incorporation of polymeric films of metal NPs. In nanocomposite antimicrobial mechanisms, the performance of NEs is effective primarily because of the high surface to volume proportion and large surface reactivity of the antimicrobial/metal oxide nano-sized particles, which enable them to more easily inactivate microbes [313] . Silver (Ag), gold (Au), zinc oxide (ZnO), silicon (SiO 2 ), titanium dioxide (TiO 2 ), alumina (Al 2 O 3 ), and iron oxides (Fe 3 O 4 , Fe 2 O 3 ) are some of metal and metal oxides nanomaterial widely used as antimicrobial agent.

The nanocomposites of the polymeric matrix are used extensively in heavy industry to make manufacturing simpler, lightweight, and flexible. They do, however, exhibit several drawbacks compared with metals and ceramics, such as low modulus and power.

Bio-nano-composite films built on poly (lactic acid) (PLA) and strengthened with nanoclay C30B (5.0 percent w/w) are infused with thymol and cinnamaldehyde active compounds at a high concentration of 11 to 17 percent w/w. The addition of active substances and nanoclay produces structural, thermal, mechanical, and antimicrobial properties to alter against specified Gram-negative and Gram-positive bacteria [314] . • [331] • [332] 

The use of nanoparticles to fight bacteria is a fairly modern approach that may provide a viable solution to the crisis of global antibiotic resistance. Theoretically, it would be difficult for microbes to establish a resistance to several destroying pathways utilizing nanoparticles because of their multiple-target and action capability.

Many experiments have been conducted to test the metal-based nanoparticles' mechanism of action. The nanoparticles are known for their strong antibacterial activity against a wide array of pharmaco-resistant species in silver and silver oxide. They use several mechanisms to work against bacteria, rendering them most efficient. The silver nanoparticles work by generating vast amounts of silver ions, which influence the permeability of the cell membrane and help to inhibit energy transfer through the transport chain of electrons. In addition, microbial cell damage to DNA [336] [337] [338] has also been identified. Zinc oxide nanoparticles are another type of nanoparticle which grows in the cells and emit Zn +2 ions there. These involve hydrogen peroxide production and destruction of the cell membranes [339, 340] . Titanium dioxide nanoparticles participate in reactive oxygen production and subsequently influence the integrity of the cell membrane [341] [342] [343] . In contrast to metal nanoparticles, numerous nanomaterials dependent on polymers, liposomes, or carbons, each of which has its own mechanisms of action, are often used for fighting pathogens. Nanoparticles with chitosan work by boost permeability and breakout of the membrane. They as well engage within enzyme inactivation of the microbial machinery [227, 309] . Carbon nanotubes act primarily in producing and oxidative degradation of the cell membrane, lipid, and proteins through reactive oxygen species [344] . A relatively recent family of nanoparticles that involves fullerenes works by rising neutrophil infiltration and is active in cell membrane disruption [345, 346] . These various action pathways are ways in which nanoparticles can successfully attack the microbial machinery ( Figure 5 ). and is active in cell membrane disruption [345, 346] . These various action pathways are ways in which nanoparticles can successfully attack the microbial machinery ( Figure 5 ). 

The effectiveness and efficiency of a nano-formulation filled with medicines depend mainly upon the kinetic release. For maximum effectiveness, it is essential to have medicines released for nano-carrier slow before reaching the site of action to prevent medication loss [347] [348] [349] . This procedure must be tested and continuously monitored to guarantee optimal and safe activity at the site and to avoid off-site behavior and possible subsequent adverse reactions. The drug release kinetics is the key factor in the effect nanoparticles, designed as antibiotic nano-carriers, will have on medication delivery [350, 351] . Popular techniques for evaluating the release of NPs include dynamic ultracentrifugation, ultrafiltration, dialysis, and others. Dynamic dialysis is often preferred since additional phases in the isolation and release of medication from NPs are omitted at different kinetic periods. Furthermore, the exterior stress applied in several other approaches during the separation often reduces the efficiency of those methods [352] . Commonly, a broad range of technics is used to include antibiotics, such as liposomes, nano-emulsion, polymeric NPs, micelle systems, dendrimers, and strong lipid NPs, in targeted, regulated, and appropriate manner [353] . The drug release kinetics for polymeric NPs depends largely on the following:

i.

Surface-bound or adsorbed product desorption ii. Drugs diffusion from polymeric NPs iii. Polymeric NP erosion and a cumulative erosion/diffusion effect 

The effectiveness and efficiency of a nano-formulation filled with medicines depend mainly upon the kinetic release. For maximum effectiveness, it is essential to have medicines released for nano-carrier slow before reaching the site of action to prevent medication loss [347] [348] [349] . This procedure must be tested and continuously monitored to guarantee optimal and safe activity at the site and to avoid off-site behavior and possible subsequent adverse reactions. The drug release kinetics is the key factor in the effect nanoparticles, designed as antibiotic nano-carriers, will have on medication delivery [350, 351] . Popular techniques for evaluating the release of NPs include dynamic ultracentrifugation, ultrafiltration, dialysis, and others. Dynamic dialysis is often preferred since additional phases in the isolation and release of medication from NPs are omitted at different kinetic periods. Furthermore, the exterior stress applied in several other approaches during the separation often reduces the efficiency of those methods [352] . Commonly, a broad range of technics is used to include antibiotics, such as liposomes, nano-emulsion, polymeric NPs, micelle systems, dendrimers, and strong lipid NPs, in targeted, regulated, and appropriate manner [353] . The drug release kinetics for polymeric NPs depends largely on the following: i.

Surface-bound or adsorbed product desorption ii. Drugs diffusion from polymeric NPs iii. Polymeric NP erosion and a cumulative erosion/diffusion effect Unless the rate of membrane degradation becomes more significant than the product diffusion from the polymer layer, diffusion happens as a consequence of drug exposure. The initial "burst-free release" effect is, typically, a drug release from polymeric NPs, which implies the surface release of a compound bound or adsorbed in contrast with that used within the matrix [354] . Compared with polymeric NPs, the release of the drug from liposome depends largely on the following: i.

Lipid membrane composition ii. Nature of drug involved iii. The percentage of drug's permeability iv. Environmental issues to consider such as temperature, pH, or exterior stimulations like degradation of the enzymes, ultrasound, or interaction of the proteins [91] [92] [93] [94] A significant focus has been placed on designing nanoparticles with improved drug delivery mechanisms. Several techniques for regulation of product release kinetics have been implemented, including the use of anionic gemini surfactant and covalent bonds, which can disrupt the pH of polymer NPs within an acidic environment [355] . In order to produce new nanoparticles with improved product supply and antibacterial action, the filling of the drug with polyelectrolytes is now an emergent trend [356] . Numerous experiments have examined nanoparticle drug loading and release kinetics for directed and controlled release. The chitosan-magnetic iron oxide NPs (Strep-CS-MNP) packed with streptomycin exhibited a significant burst discharge preceded by controlled drug release kinetics based on the physical mixture of chitosan-streptomycin, as well as magnetic iron oxide NPs, implicit the need for monitored drug release pathways. The analysis found that particles observed kinetics with a correlation (R) valuation of 0.9863 in the quasi-2nd order. The analysis found that Strep-CS-MNP had greater antibacterial activity than Streptomycin only toward MRSA. Other studies have found an improved production of the pH-responsive vancomycin-loaded chitosan NP at pH 6.5 relative to pH 7.4. The treatment further revealed that the risk of MRSA in a design of skin infection of the mouse was 8-fold reduced compared with those handled with pure vancomycin [353] .

Newly published research indicates that the 90% loaded release of the drug around 2.5 h after first-order release kinetics has been generated by single-walled carbon nanotubes (SWCNTs). The drug demonstrated 16 times greater efficacy in contrast to ciprofloxacin against P. Aeruginosa and S. aureus and eight times against E. coli [357] . Different structures were used together to incorporate metal and antibiotic, antibacterial results. In yet another study, 120 h of vancomycin release profile with high antibacterial impact toward MRSA were shown in vancomycin-loaded aragonite NP. Such NPs, with a broad release profile, will serve as a strong local antibiotic supply mechanism for osteomyelitis treatment [355] . Research further showed the design of well-ordered, biocompatible Cu-doped MSNs with an extensive specific surface area, subsequently encapsulated with tetracycline (TET) species and coated with ultrasmall silver nanoparticles-stabilized polyethyleneimine (PEI-SNP) complex layer for combating antibiotic bacterial resistance. Outcomes from the bioassay showed that SNPs increased the antibacterial potential of the strain of MDR E. coli substantially by cell membrane sensitization and enhanced intracellular access to nanoscale containers for pH-caused drug cargo transport. In addition, the degradation of MDR bacteria was aided by massive ROS levels owing to Cu species [358] . An effective approach has been proposed for the delivery of antimicrobial agents, in particular at acidic pH. Nanoparticles were immobilized with silver-indole-3 acetic acid hydrazide (IAAH-Ag) complexes via a pH-sensitive hydrazone bond, which acts as a model drug. The synthesized IAAH-Ag pH-sensitive complex was shown to have a robust antimicrobial ability in the planktonic and biofilm states towards multi-drug-resistant bacterial isolates. Nanoconjugates have been shown to be of strong effectiveness in the treatment of bacterial mice infection [359] .

The special features of biologically synthesized NPs are more significant than nanomaterial developed by chemical and physical methods. Nanoparticles may be synthesized physically/chemically [360] . These processes may pose a variety of issues, such as the use of dangerous chemicals, the generation of hazardous by-products, and geometrical errors [361] . Chemical processes typically consist of using one or more organic compounds or molecules, which aid particle toxicity and sensitivity and could create a risk to the environment and human health [361] .

Green synthesis particulates are clearly distinguished from physical-chemical ones. The bottom-up method of green synthesis is similar to a chemical reduction in which expensive chemical-reducing compound is substituted with extracts of natural substances, such as fruits or tree leaves for metal or metal oxides NP synthesis, or by using different biological organisms. The nanoparticles produced through green synthesis are known as 'biogenic nanoparticles'. Biological species have enormous production potential for NPs. Biogenic reductions of metal precursors to link NPs are environment friendly [362] , safe [363] , chemical-free [364, 365] , and can be used in large amounts. In addition, expensive metals like gold or silver can be recycled through the production of biological nanoparticles. These metals have limited sources, and their costs fluctuate [366] . NPs' can easily communicate with other biological molecules, a capacity that improves antimicrobial behavior by enhancing the interaction mechanism of microorganisms, primarily with sugars enzymes, proteins, and even the entire cells [367] . The biological composition of the biogenic NPs allows for smooth drug isolation or up-concentration through centrifugation of biogenic NPs from the reaction media [368] .

For biogenic NP synthesis, biological removal of metal precursors generally occurs in vitro or in vivo. Carbohydrates, enzymes, and plant chemicals such as flavonoids, phenolics, terpenoids, cofactors, and others, are thus mostly reduced and stabilized [369, 370] . It has been suggested that fungi, bacteria, algae, plants, and yeast produce biogenic NPs in-vivo [371] [372] [373] . Biological extracts mostly used in in vitro synthesis include the purification of organic agents and mixing them in a controlled manner for the related metal precursor into an aqueous solution. This spontaneous reaction takes place at around room temperature [374] , but it is often vital to involve stirring and heating [375] . These items are environmentally safe for the processing of biogenic NPs and their waste materials [376] .

The green synthesis of NPs will typically adopt either the bottom-up or top-down method ( Figure 6 ). NPs are generated by reducing the size and via different chemical and physical techniques in the top-down approach [377] . NPs are formed by smaller structures, such as molecules and atoms, with the key effect on oxidation/reduction in the bottom-up synthesis. NPs with homogenous chemical characteristics and limited errors are extracted in this sustainable and green pathway. Plant extracts and microorganisms are commonly used in the biological method of NPs production (Figure 7 ) [378] [379] [380] . The choice of the suitable species or extracts will consider the specific features, such as phytochemical substances, biochemical processes, enzyme functions, circumstances of cell development, and optimum reaction [381] .

Fungi are secondary metabolite contributors and active biomolecules, which are very important for NP synthesis. Fungal species such as Foxysporum produce proteins, polymers, and enzymes that willingly support the development of metal NPs [382] . These components enhance NP outcome and stability. In studies, some fungal organisms were reported to generate NPs with traces of extracellular amino acid. For example, the surface of the yeast includes glutamic acid and aspartic acid, which, in the presence of sufficient light, transforms silver into silver ions [383] . Ahmad et al. (2003) have found that fungal species such as Foxysporum have cytosol reductase enzymes that, in the presence of NADH + reduction element, reduce silver from silver ions [381] . The phytochelatin class is strongly able to suppress silver ions in silver metal [384] , which are present primarily in fungus. The population of fungal Coriolusversicolor was used by Sanghi and Verma (2009) for the silver NP synthesis (Ag NPs). In this study, FTIR data revealed the existence of the hydroxyl group in fungal mycelium, which contributes electrons to the silver ion and decreases them to transform Ag NPs into bare metal. In addition, it is reported that aromatic and aliphatic amines and other proteins in the fungal extract used to maintain Ag-NPs developed as a capping agent. It was further shown how silver powder became stabilized by the amide coupling of protein [385] . The role in the stabilization and capping of Ag NPs by SH group comprising fungal extract protein has also been documented by Tan et al. (2002) [386] . utilized Roryzae mycelia for synthesizing gold (Au) nanoparticles by reducing the in situ of acidic chloroauric acid (HAuCl 4 ) (pH 3) [387] . Verticillium fungus is indeed an excellent mediator for silver NPs synthesis. Biomass of fungus has generally been discovered to produce intracellular NPs on AgNO 3 treatment in an acidic medium (pH 5.5-6) [388] (Table 5) . 

Fungi are secondary metabolite contributors and active biomolecules, important for NP synthesis. Fungal species such as Foxysporum produce mers, and enzymes that willingly support the development of metal NP components enhance NP outcome and stability. In studies, some fungal o reported to generate NPs with traces of extracellular amino acid. For examp of the yeast includes glutamic acid and aspartic acid, which, in the presen light, transforms silver into silver ions [383] . Ahmad et al. (2003) have fou species such as Foxysporum have cytosol reductase enzymes that, in th NADH + reduction element, reduce silver from silver ions [381] . The phytoc strongly able to suppress silver ions in silver metal [384] , which are prese fungus. The population of fungal Coriolusversicolor was used by Sanghi and for the silver NP synthesis (Ag NPs). In this study, FTIR data revealed the e hydroxyl group in fungal mycelium, which contributes electrons to the silv creases them to transform Ag NPs into bare metal. In addition, it is reported and aliphatic amines and other proteins in the fungal extract used to ma developed as a capping agent. It was further shown how silver powder bec by the amide coupling of protein [385] . The role in the stabilization and NPs by SH group comprising fungal extract protein has also been docume Bacteria NP synthesis aided by bacteria is produced by two methods: intracellular and extracellular. Less time-consuming, extracellular synthesis of NPs is more advantageous than the intracellular system, provided that no downstream process is needed in order to gather NPs from organisms [396, 397] . On the inside of the cell, the bacteria contain reductase enzyme, which catalyzes metal ion decrease into metal NPs. Dradioduran species have high antioxidant activity and are highly resistant to oxidative stress and radiation. This makes it suitable to use Au NPs in green synthesis from their ionic form (Table 6 ). Leptothrix bacteria were used to synthesize AU-NPs by reducing gold salt on an aqueous medium in a new analysis by Kunoh Tatsuki et al. (2017) . It has been documented that guanine RNA molecules and 2-deoxy guanosine residues minimize gold salt ( Figure 6 ).

Plant-aided NP synthesis is far more effective than microbial synthesis. Plants possess numerous biochemicals (e.g., polyphenols) and many metabolites, which can act as stabilizers and reduce the synthesis factor of biogenic NPs. The synthesis of NPs in plants is environmentally sustainable and cost-effective. Plant-based NPs have been shown to be somewhat more stable than microbial and fungal NPs [396] . The controlled plant synthesis of the NPs is divided into three groups; phytochemical, intracellular, and extracellular materials. When plant extract is used as the raw material for the synthesis of NPs, the extracellular method is used. Intracellular synthesis of NPs occurs within plant tissue cells utilizing cellular enzymes. After synthesis, by destroying the plant cell wall, the NPs are restored. Synthesis of plant extract NP is relatively inexpensive and results in higher yields because more plant extract phytochemicals can stabilize or transform ions of metal into metal NPs [404] . Phytochemical controlled NP synthesis is not a commonly used method, as it involves understanding the specific phytochemical required for balanced NP synthesis [405] . Shakeel Ahmed et al. (2015) produced Ag NPs in a spherical form via A. indica leaves extract. In the FTIR study, the flavonoids and phytochemical compounds of the plant extract were found to act as reducers and stabilizers during the synthesis of NP. There was a high antibiotic response in these NPs [406] . Suman et al. (2013) isolated Au NPs through M. citrifolia root extract that had also been reported to be antimicrobial in nature [407] (Table 7 ). 

Purification of nanoparticles after the synthesis is quite important before using them in any sort of application ( Figure 6 ). Scientists have increasingly used the centrifugation process to purify nanoparticles since the procedure is simple and time-effective. Therefore, for the isolation and purification of metallic nanoparticles produced biologically, in order to isolate unreacted bioactive molecules, frequent washing and high-speed centrifugation are performed [405] . However, the process has several drawbacks, such as centrifugation which may induce NP agglomeration. Because of the disunion of the passivating agent from NPs and a transition in the NP's underlying properties, NP destabilization occurs. The process of dialysis, using the exact cutting of the membrane, is another common form of purification. The dialysis membrane can quickly transfer tiny organic molecules contained in plant extracts, although organic molecules found as surface-passivizing agents stay in place and are connected with NPs in the dialysis membrane. This filtration process requires time which normally takes more than 24 h. However, for bio-fabricated nanoparticles, the diafiltration method is not used as it is insoluble in soil. The application of external magnetic power effectively splits up the magnetic nanoparticles such as Fe 2 O 3 and Fe 3 O 4 . Moreover, it is always challenging to extract closely bound biomolecules from the nanoparticle layer ( Figure 6 ).

Some researchers have obtained four types of antibacterial materials and coatings during the last decade. The first types of antibacterial coatings are those to which bacteria do not show a natural tendency to attach. Frequently, this form of coating is focused on hydrophilic polymers like polyethylene glycol (PEG), oxazolines, radicals in nitroxide, and chlorinated plasma polymers [419] [420] [421] . The second type of coatings or compounds that are modified can destroy bacteria while in contact. Studies have shown that an RNH 4+ bonded nitrogen concentration of 4.18% and a surface potential of +120.4 mV is needed for the killing of Escherichia coli efficiently [422, 423] , with a carefully planned amount density gradient of QAC. Figure 8 presents strategies that provide excellent approaches to avoid the colonization of bacteria on the device surface while the bacteria that have penetrated the implantation site are not removed. An exposed wound is therefore infected by opportunistic pathogens. Coatings or materials that release antibacterial agents have been produced for pathogen neutralization. A significant range of antibacterial substances, including classical antibiotics [424, 425] , nitrous oxide [426, 427] , antibacterial polymers, and peptides, may be issued under this strategy [428] [429] [430] . The last category consists of coatings and materials that trigger antibacterial material only when the product has been infected or engulfed by photogenic bacteria (Figure 8 ) [431] [432] [433] .

Three main factors influence the synthesis of various NPs. They are temperature, pH, and reaction time (Figure 9 ).

Significant research is being currently being carried out worldwide on the question of temperature regulation in NPs. Temperature is one of the most critical parameters that affect the morphology and synthesis of the NPs. The different forms, dimensions, and synthetic structure of NPs are temperature-dependent (triangles, platelets of octahedral, spherical, and rod-like). The rate of the reaction, as well as the formation of nuclear centers, tends to increase with the increase in temperature [434] [435] [436] . Sneha et al. (2010) analyzed the temperature effects on the morphology of Piper leaf extract synthesized Au NPs [437] . They found triangular NP types at 20 • C, while octahedral NPs of 5-500 nm were produced at temperatures from 30 to 40 • C. Therefore, the size distribution of the NPs was much more appropriate and spherical in the form at increased temperature (50-60 • C). Iravani and Zolfaghari (2013) [438] documented the biological development of Ag NPs via P. eldarica bark extracts under different temperatures. The synthesis was conducted at 25, 50, 100, and 150 • C. Triangular NP types were found at 20 • C, while octahedral NPs of 5-500 nm were produced at temperatures from 30 to 40 • C. The NPs were produced at 20 • C. Electron micrographs scan of NPs confirmed this result. In the synthesis of the AgNPs using biocompatible polymer PEG [439] , the effect and temperature of atmospheric oxidation have been investigated by Fleitas-Salazar et al. (2017) . The analysis showed that PEG had a tendency towards decreasing silver salt at 100 • C. It was also suggested that the functional PEG groups strongly interacting with Ag molecules at 100 • C resulted in a more balanced and stabilized Ag-NP structure. At 60 • C, Ag ions were reduced by hydroxyl group oxidations found in PEG. The researchers have thus confirmed that there are many methods for Ag NP synthesis operating at different temperatures. The synthesis procedure for AU NPs in aqueous poly (ethylene oxide)-poly (propylene oxide) solution at various temperature levels was developed by Islam et al. (2011) . Their findings revealed that the NPs are regulated by changes in polymer morphology occurring at relatively low temperatures, distribution, and size. However, modification in polymer chemistry is regulated at higher temperatures [440] . The impact of temperatures upon the encapsulation and development of Au NPs was studied by Tans et al. (2015) using the standard PNIPAm/PEI. The TEM analysis showed that the optimum encapsulation of Au NPs, and that of stable Au-PNIPAm/PEI composite particle production, is between 25-30 • C, with homogeneous particle distribution across the template. The encapsulation at a lower temperature (15 • C) was relatively poor [441] . In another review of the synthesis of cobalt ferrite NPs doped by Manganese [442] , the number of NPs was shown to rise with the increase in temperature. 

Three main factors influence the synthesis of various NPs. They are temperature, pH, and reaction time (Figure 9 ). 

Three main factors influence the synthesis of various NPs. They are temperature, pH, and reaction time (Figure 9 ). 

The pH of the reaction plays a crucial role in forming NPs. The formation of nuclear centers is also regulated by the pH-like temperature. With the increase in pH, there is a parallel rise in the number of nuclear sites, hence the growing number of metal NPs. Several studies on the effectiveness of pH in developing the morphology and scale of NPs have been conducted. Armendariz et al. (2004) have observed the synthesis of A. sativa Au NPs at various pH levels. The lower pH (pH 2) revealed fewer NPs but a much greater NPs size (25-85 nm) . They indicated that Au NPs do not generate any new nuclear centers at a lower pH but instead had a tendency to aggregate into larger NPs [443] . In contrast, small NPs were developed with a slightly higher pH (pH 3-4). Fan et al. performed an additional analysis of the synthesis of pH-dependent NPs. They monitored the release of NIPAm poly-(N-isopropylacrylamide)/chitosan NPs filled with Camptothecin into the tumor and noted that when the NIPAm and chitosan ratio is 4:1 (w/w), the loaded NPs are released to the target. At pH 6.8 the rate of release of Camptothecin was considered to be ideal. However, they noted that the release rate decreased as the pH decreased or increased to the 37 • C temperature. Okitsu et al. (2009) [444] performed further experimental analysis to examine the impact of pH on dimensions of the average size of the gold nanorods and concluded that the ratio and the size decreased with an increase in pH.

The reaction time, along with the temperature and pH, is considered an essential factor affecting the NP morphology. Karade et al. (2018) [445] conducted an analysis of the impact of the reaction time on magnetic NPs. Fe NPs have been synthesized with green tea extract using Ferric nitrate solution. It was reported that the reaction time affected both the structural and magnetic properties of magnetic NPs. The size of the particles enlarges from 7.5-12 nm as the reaction time rises. Increasing reaction time has also been observed to increase the magnetic saturation (Ms) of NPs. Additionally, the impact of the duration of reaction on cadmium selenide NP particle size has been studied [446] . The estimated particle sizes at 4, 8, 12, and 16 h reaction times were determined to be 15.8, 10.5, 6.7, and 111.7 nm, respectively. The size of cadmium selenide NPs decreased with an increase in reaction time. It was reported that the unusual size increase at 16 h resulted from particle accumulation. Furthermore, Flor et al. (2004) studied the impact of response time on the particle sizes of ZnO and Cerium doped ZnO [447] . The study indicated the linear increase in particle size with reaction time rise. It was found that at constant periods of reaction, cerium doped particle sizes are greater than standard ZnO. Finally, the impact of the reaction time on stability, size, and reduction of AuNPs synthesized from oil palm oil extracted (E. guineensis) was examined, and it was observed that with the rise in reaction time, the reduction rate of AgNPs was also increased.

Nanoparticle behavior toward the microbes (bacteria and fungi) may be caused and influenced by various factors. Here, we identified several that could, theoretically, affect nanoparticle antimicrobial behavior. Chemical structure or size, composition, the concentration of nanoparticles, along with their form, target microorganism nanoparticles are acting against, and the effect of photoactivation are addressed below ( Figure 10 ). reaction time. It was reported that the unusual size increase at 16 h resul accumulation. Furthermore, Flor et al. (2004) studied the impact of resp particle sizes of ZnO and Cerium doped ZnO [447] . The study indicated th in particle size with reaction time rise. It was found that at constant per cerium doped particle sizes are greater than standard ZnO. Finally, the action time on stability, size, and reduction of AuNPs synthesized from tracted (E. guineensis) was examined, and it was observed that with th time, the reduction rate of AgNPs was also increased.

Nanoparticle behavior toward the microbes (bacteria and fungi) ma influenced by various factors. Here, we identified several that could, th nanoparticle antimicrobial behavior. Chemical structure or size, composi tration of nanoparticles, along with their form, target microorganism n acting against, and the effect of photoactivation are addressed below (Fi 

Chemical Composition is the crucial feature of the antibacterial mechanism in nanostructures. Many studies have focused on the choice of a substance suitable for nanoparticle synthesis and the potential effects such choices would entail for the antibacterial mechanisms [281, 448] . Analysis revealed the significance of the chemical compositions of nanoparticles and the way nanoparticles are sprayed against bacterial cells. There were substantial effects in copper nanoparticles compared with iron, size 30-40 nm and 30-70 nm, respectively, of ten drug-resistant S. aureus. Recent research interest has turned to the combined production of nanoparticles with the objective of achieving chemical and antibacterial activities.

Nanoparticle shape has been shown to affect the effectiveness of several antibacterial nanoparticles. The shape-dependent behavior of silver nanoparticles was defined by three distinct shapes (sphere, elongated, and truncated triangular silver nano-plates). Analysis of E. coli activity was based on the percentage of the active facets. Increased antimicrobial activity with more facets [111] with high atomic density facets was observed [224] .

The micro-organisms targeted by the nanoparticle have significant effects on its activities. A higher percentage of AgNP activity towards Gram-negative rods than Gram-positive cocci and higher tolerance to E. coli than to S. aureus for silver nanoparticles are good examples. The results were linked to peptidoglycan that is absent in mammalian cells in the S. aureus cell wall. The cell walls of both Gram-negative and Gram-positive bacteria, in contrast, were disordered by ZnO NPs [449, 450] . In ZnO NPs, the operation against S. aureus was higher than that against E. coli [263, 451] . These findings demonstrate the targetdependent nature of the relationship between antibacterial activity and nanoparticles.

Photoactivation is considered the most relevant parameter of the antibacterial behavior of the nanoparticle. When exposed to UV radiation, the TiO 2 NPs were considerably more active against E. coli [452] . TiO 2 nanoparticles with exposure to standard laboratory lightning exhibited a 20% increase in growth control properties, and ZnO nanoparticles, when exposed to visible light and UV radiation resulted, also showed increased activity [453] .

After the synthesis of the NPs, a range of methodologies are used to evaluate their conformational specifications for size, form, homogeneity dispersity, and morphology. Dynamic Light Scattering (DLS), UV-Vis Absorption Spectroscopy, X-Ray Diffraction (XRD), Electron Microscopy Transmission (TEM), Energy Dispersive X-ray Analysis (EDAX), and Scanning Electron Microscopy (SEM) are methods most frequently used to characterize NPs ( Figure 11 ).

The UV-Vis absorption spectra are used for the aqueous suspension of NPs in size and form [454] . To identify the NPs of approximately 2 to 100 nm [455] , wavelengths from 300 to 800 nm are usually used. For instance, UV-Vis emission spectra of Aloe Vera extract synthesized ZnO particles display high UV spectrum absorption with a higher wavelength of 358 nm to 375 nm because of their membrane Plasmon resonance [456] .

The SEM and TEM describe the morphology and scale of NPs [457] . ZnO-NP (25 to 55 nm) seen in the electron microscopy study is compatible with the XRD [458] . The green synthesized carbon nanotubes were analyzed by SEM and TEM, which were completely coated with polyaniline layers [459] . TiO 2 particles were commonly spherically agglomerated within the range of 10 to 30 nm in the TEM examination. In addition, a crystalline structure was shown by Selected Area Electron Diffraction (SAED) [460] .

XRD contains data regarding symmetry, sizes, and the state of metallic NP detection [461] . X-rays penetrate nanomaterials. The division sequence collected is correlated with structural knowledge requirements. XRD peaks (2 h) at 28.51, 33.06, and 47.42 angles of 111, 200, and 220 planes, respectively, and normal separation peaks at the front-andcenter cubic step of the CeO 2 NPs [462] . The XRD analysis confirmed the existence in the Scherer equation (Elango and Roopan 2015) of the crystalline patterns of PbNPs and the average particle size of 47 nm. Antibiotics 2021, 10, x FOR PEER REVIEW 42 of 64 Figure 11 . Methods for the characterization of Nanoparticles.

The UV-Vis absorption spectra are used for the aqueous suspension of NPs in size and form [454] . To identify the NPs of approximately 2 to 100 nm [455] , wavelengths from 300 to 800 nm are usually used. For instance, UV-Vis emission spectra of Aloe Vera extract synthesized ZnO particles display high UV spectrum absorption with a higher wavelength of 358 nm to 375 nm because of their membrane Plasmon resonance [456] .

The SEM and TEM describe the morphology and scale of NPs [457] . ZnO-NP (25 to 55 nm) seen in the electron microscopy study is compatible with the XRD [458] . The green synthesized carbon nanotubes were analyzed by SEM and TEM, which were completely coated with polyaniline layers [459] . TiO2 particles were commonly spherically agglomerated within the range of 10 to 30 nm in the TEM examination. In addition, a crystalline structure was shown by Selected Area Electron Diffraction (SAED) [460] .

XRD contains data regarding symmetry, sizes, and the state of metallic NP detection [461] . X-rays penetrate nanomaterials. The division sequence collected is correlated with structural knowledge requirements. XRD peaks (2 h) at 28.51, 33.06, and 47.42 angles of 111, 200, and 220 planes, respectively, and normal separation peaks at the front-and-center cubic step of the CeO 2 NPs [462] . The XRD analysis confirmed the existence in the Scherer equation (Elango and Roopan 2015) of the crystalline patterns of PbNPs and the average particle size of 47nm. FTIR Spectroscopy is designed to identify different types of functional groups or metabolites that may contribute to the reduction and stabilization of NPs at the surface of NPs [378] . The functional group bands observed at 3450, 3266, and 2932 cm −1 have been allocated to stretching the amines frequencies, O-H to stretch alcohols, and C-H to extend the alkanes for NPs using Aloe-Vera extracts. ZnO is allocated for the peaks in the region of 600-400 cm −1 [463] . In 1648, 1535, 1450, and 1019 cm −1 and 1450 cm −1 peaks of carboxyl ions, the FTIR range of AgNP synthesized using the Solanumtorvum leaf extract was reportedly responsible for stabilization of the Ag NPs [464] .

DLS and EDAX are used to study the flow of size of liquids and essential components of NPs accordingly [465] [466] [467] .

Although antibiotics have been important historically, nanoparticles are increasingly being used in emerging medical research and application. If the efficacy and potential of antibiotics and nanoparticles are to be compared, their combined action will prove to be more significant than that of either one alone. Some comparisons are offered below in Table 8 . Table 8 . Comparison of Nanoparticles with antibiotics and their combination.

Size Complex because of the poor membrane transport and size scale

The ultra-small size is controllable and can penetrate membranes easily

The small size of the NP carriers makes it easier to transport the antibiotics [468] Protection This shows resistance against bacteria, all because of the increased efflux and decreased uptake.

No resistance against bacteria and shows a strong effect on bacteria.

NP carriers can help protect the drugs from resistance by target bacteria by increasing the serum levels of antibiotic [469] Precision and safety Not targeted at the specific location and thereby shows adverse effects

Helps target the specific areas and thereby minimize the adverse effects.

More specific targeting and minimal adverse effects [470, 471] Controllability 

As already stated, NPs do not only defend themselves against bacterial and microbial resistance but can also be the "medium and carrier" for antibiotics. The methodologies of NP-based drugs vary based on the pathways discussed earlier.

The essential features of NPs as a carrier for the delivery of antibiotics, in contrast with conventional delivery systems, are:

• Size: the ultra-small and customizable size of NPs is ideal for performing antimicrobial activities and combating intracellular bacteria [467, 468] . • Protection: NP carriers can help protect the drugs from resistance by target bacteria by increasing the serum levels of antibiotics [280, 469] • Precision and Safety: NP carriers can help find a contaminated region with antibiotics and eliminate systemic adverse reactions [470, 471] . • Controllability: safe and controllable antibiotic release can be flexibly achieved [472] [473] [474] . • Combination: the same NP may be used to combine several antibiotics or drugs, and NPs can be combined with others to enhance the antimicrobial properties of the antibacterial agents [282, 472, 476] Recently, researchers have combined the gold and silver nanoparticles with Ampicillin. They reported that silver nanoparticles have an inherent ability to combat the microorganism, although gold nanoparticles have an antimicrobial effect only when in surface communication with ampicillin. Broad-spectrum action against the Gram-negative bacteria and Gram-positive bacteria is accomplished by the ampicillin-functioning of silver and gold nanoparticles. Silver and gold combined with ampicillin are very effective in treating bacteria resistant to antibiotics [477] .

Any effective antibiotic, including certain penicillins, can be recovered through the use of antibiotics with metallic nanoparticles [245, 252, 261, 267] . In addition, the combined use of nanoparticles with antibiotics or other antimicrobials allows these agents to decrease the toxicity in human cells [269] . The majority of research is dedicated to the study of the interactions of nanoparticles and antibiotics and their various combinations, especially with b-lactams (ampicillin, amoxicillin) and glycopeptides (vancomycin), which have shown promising enhancing effects in vitro. These effects are much more likely due to the increased penetration of these nanoparticles in the cell wall. While the interaction of other metallic nanoparticles with antibiotics has still not been thoroughly investigated, ZnO and TiO 2 nanoparticles have shown, with limited evidence that they can respond to efflux pumps that cause the resistance of many clinically important antibiotics, such as fluoroquinolones and many more [478] .

Although there are currently several applications of the nanoparticles, only a few studies have been conducted in the context of antimicrobial activity. Some of the antimicrobial applications of nanoparticles on different animal models are shown in Table 9 . Table 9 . Nano-particles and their applications on animal models.

Piglets Nano zinc Diarrhea in young piglets can be reduced by Nano zinc [479] Albino Rats Silver AgNPs using A. nobilis revealed higher microbicidal activity for wound healing. [480] Mouse Gold

In xenograft mouse models, QAuNPs significantly inhibited cell proliferation, caused apoptosis in vitro, and destroyed angiogenesis and tumor regression in vivo [481] Mouse Copper Treatment of wounds in mice with copper nanoparticles. [482] 9. Challenges for Nanoparticle

The benefits of nanotechnology in numerous fields, including medicine, are wellestablished, but the potential implications or harmful effects of these nano-sized particles are not well-explained. In the medical context, as an alternative antibiotic, a whole range of functions and relationships of the nanoparticles can be found [483] . A number of groundbreaking studies are underway in nanotechnology, while the critics of these new technologies find it incredibly challenging to reconcile the side of nanoparticles with their reported strengths. As nanotechnology development is gaining momentum, concerns have been raised about its safety, particularly in medicine [484] . Nano-formulation plays an essential role in the development of nano-based drugs and thus faces regulatory issues relating to medicines. To design a new nanodrug based on the form of drugs already existing, specific regulatory manufacturing criteria must be provided and rigorously adhered to throughout drug production. A shorter approval process is pursued for nanodrugs developed from previously licensed micro-formulations; however, when a novel product is formulated, the paths of assessment and approval are more stringent [485] . Manufacturers must follow the guidance of the FDA (Current Appropriate Manu-Invoicing Practices) and the Quality Control Regulations for the production of new Nano drugs.

Nanoparticles have significant benefits and advancements in the management of infectious diseases over conventional antibiotics; however, their delivery technique is still difficult in clinical applications. For proper therapeutic results and effective clinical application, an assessment of the potential nanoparticle interactions with tissues, organs, or cells, their doses, and potential mode of administration, is needed [486] . Nanoparticle toxicity is necessary for effective clinical translation to take place. [487] . However, intravenous (I.V.) NP administration can lead to NPs accumulating in bone marrow, spleen, liver, and lung [488] . Due to their small size and effective cell absorption, inhaled NPs can enter the liver, brain, spleen, heart, and lung [489] . Moreover, the toxicity of several nanoparticles is not well known [483] . NP therapeutic administration can produce nanotoxicity of multiorganisms. All toxic cases show NPs association with oxidative stress-inducing cells contributing to hepatotoxicity and pulmonary toxicity [490, 491] . Suggested metabolic modifications such as mitochondrial dysfunction, decreased ketogenesis, beta-oxidation of fatty acids, and glycolysis contribute to hepatotoxicity and nephrotoxicity [492] . While preexisting in vitro methods have certain advantages, there are no popular practices for universal NP dosing [484, 488] , as nanoparticles demonstrate size-specific action. To solve these problems, additional characterization methods are required [490] . More recent work mainly focuses on delivering targeted bacteria [493, 494] .

Antimicrobial resistance has posed an unprecedented global threat to human life. Conventional antibiotics are losing their potency against the ever-evolving multiple drugresistant pathogens. In search for a viable alternative strategy, a nanotechnology-offers promise and nanotechnology-based drug delivery device for the production of future nano-antibiotics (nAbts) is seen as a weapon in the 21st century technological revolution. To evolve novel pharmaceutical drugs over time, the newly developed field of nanotechnology is still in its infancy and requires significant effort and investment. Compared with traditional antibiotics, nanoparticles can have numerous benefits, such as longevity, absorption, controlled release, distribution, and delivery.

Furthermore, for the resistant, antimicrobial environment, nanoparticles can be costeffective and ecological, as well as flexible. Nanoparticles have distinct and well-defined physical and chemical characteristics that can be customized for desirable purposes. Moreover, owing to the excessive volumetrically surface area, they have a strong antimicrobial performance that gives them an advantage over their chemical counterparts facing drug resistance challenges. The advances in nanotechnology and nanoparticle synthesis have opened the floodgates for groundbreaking strategies in the production of new antimicrobial agents. A multitude of processes that vary in traits, including size, morphology, electrical charge, and surface coatings, allow researchers to develop novel composite antimicrobial substances for different applications used to perform antimicrobial activities. The antimicrobial activity of inorganic nanoparticles and carbon-based nanoparticles can be applied to various research, medical, and industrial uses in the future and offer a solution to the crisis of antimicrobial resistance to traditional approaches. In addition, nanomaterials provide a wide range of opportunities for infection prevention, diagnosis, treatment, and biofilm control. However, a detailed evaluation of these nanomaterials is required to identify their effects on natural organic tissues and to assess their impact on humans and the environment before large-scale industry implementations are carried out. 

Antibiotics: Classification and mechanisms of action with emphasis on molecular perspectives

How antibiotics kill bacteria: From targets to networks

Global Governance Mechanisms to Address Antimicrobial Resistance

Nanotechnology as a therapeutic tool to combat microbial resistance

The antibiotic resistance crisis: Part 1: Causes and threats

Challenges in Antimicrobial Resistance: An Update

Understanding media publics and the antimicrobial resistance crisis

The growing role of nanotechnology in combating infectious disease

Antibiotics 2021

Nanoantibiotics": A new paradigm for treating infectious diseases using nanomaterials in the antibiotics resistant era

Chapter 9-Advances in antibiotic nanotherapy: Overcoming antimicrobial resistance

Seven Ways to Preserve the Miracle of Antibiotics

Global analysis of strategies to tackle antimicrobial resistance

Nanotechnology: Emerging tools for biology and medicine

Nanotechnology-future prospect in recent medicine: A review

Functional metagenomics reveals diverse Beta-lactamases in a remote Alaskan soil

Metagenomic Analysis of Apple Orchard Soil Reveals Antibiotic Resistance Genes Encoding Predicted Bifunctional Proteins

National Institute of Allergy and infectious diseases

Uncovering effects of antibiotics on the host and microbiota using transkingdom gene networks

What is a disease? Disease, disability and their definitions

The Role of Bacteria in the Pathogenesis of Inflammatory Bowel Disease

Progress on new therapeutics for fungal nail infections

Severe acute respiratory syndrome

Current Advances in Detection and Treatment of Babesiosis

Human Cutaneous Protothecosis: Report of a Case and Literature Review

Archaea and Their Potential Role in Human Disease

The pathology of methanogenic archaea in human gastrointestinal tract disease

Thermal inactivation, growth, and survival studies of Listeria monocytogenes strains belonging to three distinct genotypic lineages

History of Antibiotics Research

Chemical diversity of propolis and the problem of standardization

History of antimicrobial drug discovery: Major classes and health impact

Impact of Antibiotic Use in Adult Dairy Cows on Antimicrobial Resistance of Veterinary and Human Pathogens: A Comprehensive Review

Tetracycline consumption in prehistory

Sensitive and Rapid Quantitative Detection of Anthrax Spores Isolated from Soil Samples by Real-Time PCR

Effects of Global Climate on Infectious Disease: The Cholera Model

Antibacterial properties of extracts from selected planktonic freshwater cyanobacteria-A comparative study of bacterial bioassays

A new antibiotic, leucinostatin, derived from penicillium lilacinum

Arsinothricin, an arsenic-containing non-proteinogenic amino acid analog of glutamate, is a broad-spectrum antibiotic

The use of antisyphilitic remedies

The magic bullet as cancer therapeutic-Has nanotechnology failed to find its mark? Prog

Antibiotics 2021

Staphylococcal cell wall: Morphogenesis and fatal variations in the presence of penicillin. Microbiol

The effects of biocidal treatments on metabolism in soil-IV. The decomposition of fumigated organisms in soil

Different roads to discovery

Prontosil (hence sulfa drugs) and penicillin (hence β-lactams)

Historical Discovery Development

Antimicrobial activity of some sulfonamide derivatives on clinical isolates of Staphylococus aureus

Observations upon the experimental and clinical use of sulfapyridine. III. The mechanism of recovery from pneumococcal pneumonia in patients treated with sulfapyridine

Decade-long use of the antimicrobial peptide combination tyrothricin does not pose a major risk of acquired resistance with gram-positive bacteria and Candida spp

Discovery of gramicidin A analogues with altered activities by multidimensional screening of a one-bead-one-compound library

Acute and chronic desensitization of penicillinallergic patients using oral penicillin

Erythema multiforme after use of topical sulfacetamide

A review of the recent advances in antimicrobial coatings for urinary catheters

Drug delivery approaches to overcome bacterial resistance to β-lactam antibiotics

Introduction of a Practice Guideline for Penicillin Skin Testing Improves the Appropriateness of Antibiotic Therapy

Sulphadimidine, co-trimoxazole, and a placebo in the management of symptomatic urinary tract infection in general practice

Bacteria antibiotic resistance: New challenges and opportunities for implant-associated orthopedic infections

Peptide antibiotics

Platforms for antibiotic discovery

Syntheses and characterisation of mercury complexes of sulfadiazine, sulfamerazine and sulfamethazine

Zones of inhibition? The transfer of information relating to penicillin in Europe during World War II

Topical Antimicrobial Therapy for Treating Chronic Wounds

Modeling Tetracycline Antibiotic Sorption to Clays

Isolation and Identification of a Paenibacillus polymyxa Strain That Coproduces a Novel Lantibiotic and Polymyxin

New Antimicrobial Nitrofuran, trans-5-Amino-3-[2-(5-Nitro-2-Furyl) Vinyl]-∆2-1,2,4-Oxadiazole: Antibacterial, Antifungal, and Antiprotozoal Activities In Vitro

Sulfonamide cross-reactivity: Is there evidence to support broad cross-allergenicity?

Determination of neomycin and related substances in pharmaceutical preparations by reversed-phase high performance liquid chromatography with mass spectrometry and charged aerosol detection

Detection of oxytetracycline and doxycycline residue in different growth stages of commercial broiler

Amplifiable resistance to tetracycline, chloramphenicol, and other antibiotics in Escherichia coli: Involvement of a non-plasmid-determined efflux of tetracycline

Antibiotic Resistance in Bacteria and Its Future for Novel Antibiotic Development

A comparative study on the inhibitory actions of chloramphenicol, thiamphenicol and some fluorinated derivatives

Influence of the Antibiotic Erythromycin on Anaerobic Treatment of a Pharmaceutical Wastewater

Vancomycin-resistant enterococcal infections: Epidemiology, clinical manifestations, and optimal management

The role of efflux in macrolide resistance

Treatment of syphilis: A systematic review

Cycloserine for treatment of multidrugresistant tuberculosis: A retrospective cohort study in China

Role of spiramycin/cotrimoxazole association in the mother-to-child transmission of toxoplasmosis infection in pregnancy

The Safety and Economic Impact of Cefazolin versus Nafcillin for the Treatment of Methicillin-Susceptible Staphylococcus aureus Bloodstream Infections

Insights into erythromycin action from studies of its activity as inducer of resistance

The role of eis mutations in the development of kanamycin resistance in Mycobacterium tuberculosis isolates from the Moscow region

Cineromycins, γ-butyrolactones and ansamycins by analysis of the secondary metabolite pattern created by a single strain of Streptomyces

Intravenous Colistin Monotherapy versus Combination Therapy against Carbapenem-Resistant Gram-Negative Bacteria Infections: Meta-Analysis of Randomized Controlled Trials

Reductive activation of nitroimidazoles in anaerobic microorganisms

Blue 470-nm Light Kills Methicillin-Resistant Staphylococcus aureus (MRSA) in Vitro

Its use in clinical dentistry

Methicillin-resistant Staphylococcus aureus emerged long before the introduction of methicillin into clinical practice

Role of nontypeable Haemophilus influenzae in pediatric respiratory tract infections

Evaluation of apramycin against spectinomycin-resistant and -susceptible strains of Neisseria gonorrhoeae

Population Pharmacokinetics of Ethambutol in South African Tuberculosis Patients

fusidic acid and bacitracin: Activity, action and clinical uses of three topical antibiotics. Veter Dermatol

The Quinolones: Past, Present, and Future

Novel bioactive hydrophobic gentamicin carriers for the treatment of intracellular bacterial infections

The threat of antibiotic resistance in Gram-negative pathogenic bacteria: β-lactams in peril!

Antibiotic resistance and extended spectrum beta-lactamases: Types, epidemiology and treatment

Nalidixic Acid: An Antibacterial Paradox

Safety and Efficacy Review of Doxycycline

Determination of Antimicrobial Resistance and Resistant Genes in Acinetobacter Baumannii from Human Clinical Samples

Effects of Human Immunodeficiency Virus Infection on Recurrence of Tuberculosis after Rifampin-Based Treatment: An Analytical Review

Bacterial resistance to tetracycline: Mechanisms, transfer, and clinical significance

Antibiotics 2021

A review of its antibacterial activity, pharmacokinetics and therapeutic use in urinary tract infections

Fosfomycin for the treatment of resistant gram-negative bacterial infections: Insights from the society of infectious diseases pharmacists

Antibacterial Drugs Today

Amphiphilic Tobramycin-Lysine Conjugates Sensitize Multidrug Resistant Gram-Negative Bacteria to Rifampicin and Minocycline

a new class of beta-lactam antibiotics: Discovery and development of imipenem/cilastatin

The intestinal anti-inflammatory effect of minocycline in experimental colitis involves both its immunomodulatory and antimicrobial properties

A randomized, controlled, open-label trial of a single day of mebendazole versus a single dose of tinidazole in the treatment of giardiasis in children

Effects of the Combination of Gentamicin and Carbenicillin on the Bactericidal Activity of Serum

The removal of trimethoprim and sulfamethoxazole by a high infiltration rate artificial composite soil treatment system. Front

Contemporary unconventional clinical use of co-trimoxazole

Cefoxitin and Cephamycins: Microbiological Studies

Glycopeptide antibiotics: Back to the future

Cefaclor, a cephalosporin antibiotic, delays gastric emptying rate by a CCK-A receptormediated mechanism in the rat

Therapeutic challenges of ESBLS and AmpC beta-lactamase producers in a tertiary care center

Clinical use of the fluoroquinolones

Antibiotic resistance profile & extended spectrum beta-lactamase (ESBL) production in Acinetobacter species

Daptomycin: Discovery, development and perspectives. The battle against microbial pathogens: Basic science, technological advances and educational programs

Carbapenems in clinical practice: A guide to their use in serious infection

Vancomycin-resistant enterococci: Why are they here, and where do they come from?

Intra-abdominal Sepsis: Newer Interventional and Antimicrobial Therapies

Recent updates of fluoroquinolones as antibacterial agents

Resistance to cephalosporins and carbapenems in Gram-negative bacterial pathogens

Carbapenem resistance mechanisms in Pseudomonas aeruginosa: Alterations of porin OprD and efflux proteins do not fully explain resistance patterns observed in clinical isolates

Mechanisms of fluoroquinolone resistance

Infectious Disease in Athletes

A review of rescue regimens after clarithromycin-containing triple therapy failure (for Helicobacter pylori eradication)

Cefepime plasma concentrations and clinical toxicity: A retrospective cohort study

Systematic Review and Meta-Analysis of the Significance of Heterogeneous Vancomycin-IntermediateStaphylococcus aureusIsolates

Use of Linezolid, an Oxazolidinone, in the Treatment of Multidrug-Resistant Gram-Positive Bacterial Infections

New treatment option for gram-positive infections in critically ill patients-overview over linezolid

Telithromycin: The First of the Ketolides

Linezolid update: Stable in vitro activity following more than a decade of clinical use and summary of associated resistance mechanisms

Fight against Antimicrobial Resistance: We Always Need New Antibacterials but for Right Bacteria

Infection with vancomycin-resistant Staphylococcus aureus containing the vanA resistance gene

Lipopeptides as anti-infectives: A practical perspective

Daptomycin: A novel agent for Gram-positive infections

Drugs of the 21st century: Telithromycin (HMR 3647)-The first ketolide

First of a new class of antimicrobial agents

Fidaxomicin Versus Vancomycin for Clostridium difficile Infection: Meta-analysis of Pivotal Randomized Controlled Trials

A new drug approved for treatment of multidrug-resistant tuberculosis

The Role of Telavancin in Hospital-Acquired Pneumonia and Ventilator-Associated Pneumonia

Antibiotic resistant organism: An emerging public health problem and role of ayurveda (an overview)

Effect of cooking and cold storage on biologically active antibiotic residues in meat

Ceftazidime-Avibactam for Treatment of Carbapenem-Resistant Enterobacteriaceae Bacteremia

Total Synthesis of Teixobactin

Discovery of Next-Generation Antimicrobials through Bacterial Self-Screening of Surface-Displayed Peptide Libraries

From worms to drug candidate: The story of odilorhabdins, a new class of antimicrobial agents

The Role of Formyl Peptide Receptors for Immunomodulatory Activities of Antimicrobial Peptides and Peptidomimetics

Novel approaches to developing new antibiotics for bacterial infections

Tebipenem pivoxil hydrobromide-No PICC, no problem! Pharmacotherapy

Cefiderocol: A new cephalosporin stratagem against multidrug resistant gram-negative bacteria

Antibiotic classes and antibiotic susceptibility of bacterial isolates from selected poultry; a mini review

What remains against carbapenem-resistant Enterobacteriaceae? Evaluation of chloramphenicol, ciprofloxacin, colistin, fosfomycin, minocycline, nitrofurantoin, temocillin and tigecycline

Current Updates on Oxazolidinone and Its Significance

Antibiotics: Mode of Action and Mechanisms of Resistance

Overview of Bacteria

Antibiotic Resistance: An Ecological Imbalance

From Tragedy the Antibiotic Age is Born

Trends in antibiotic resistance among diarrheal pathogens isolated in Thailand over 15 years

Managing neonatal and early childhood syndromic sepsis in sub-district hospitals in resource poor settings: Improvement in quality of care through introduction of a package of interventions in rural Bangladesh

An enzyme from bacteria able to destroy penicillin

Antimicrobial use and resistance in animals

The antimicrobial paradox: Why preservatives lose activity in foods

Emergence and dissemination of quinolone-resistant Escherichia coli in the community

Healthcare utilization and cost of pneumococcal disease in the United States

Studies on streptococcus pyogenes I

Multidrug-resistant tuberculosis and extensively drug-resistant tuberculosis

Antimicrobial drug resistance in strains of Escherichia coli isolated from food sources

Study on antibiotic susceptibility of Salmonella typhimurium L. forms to the third and forth generation cephalosporins

An Illustration of the Potential Health and Economic Benefits of Combating Antibiotic-Resistant Gonorrhea

Annual changes in drug sensitivity of gonococci derived from urethritis in men

Resistance: A Review

Impact of multidrug-resistant Pseudomonas aeruginosa infection on patient outcomes

Vancomycin resistant Enterococci: A brief review

The emergence of vancomycin-intermediate and vancomycin-resistant Staphylococcus aureus

Economics of Antibiotic Resistance: A Theory of Optimal Use

The antimicrobial paradox. How miracle drugs are destroying the miracle

Antimicrobial resistance: The example of Staphylococcus aureus

Resistance to Antibiotics: Are We in the Post-Antibiotic Era?

Outpatient antibiotic use in Europe and association with resistance: A cross-national database study

Antibiotic Resistance: Synthesis of Recommendations by Expert Policy; World Health Organization

Molecular mechanisms that confer antibacterial drug resistance

Molecular mechanisms of antibiotic resistance

Bacteriophage therapy: A potential solution for the antibiotic resistance crisis

New antibiotic agents in the pipeline and how they can help overcome microbial resistance

The crisis of no new antibiotics-What is the way forward?

Antimicrobial Activity of Metal and Metal-Oxide Based Nanoparticles

The fascinating world of nanoparticle research

Early Use of PbS Nanotechnology for an Ancient Hair Dyeing Formula

Nanoscience of an Ancient Pigment

Nanotechnology: From the ancient time to nowadays

Crystals and phase transitions in protohistoric glass materials. Phase Transit

Microstructure of opaque red glass containing copper

Invisibility cup. Nat. Photon

Clay Minerals as an Ancient Nanotechnology: Historical Uses of Clay Organic Interactions, and Future Possible Perspectives. Macla

Beiträge zur Optik trüber Medien, speziell kolloidaler Metallösungen

Nanostructured materials: An overview and commercial analysis

Samsung and its attractions-Asia's new model company

Risks, Ethical, Legal and Social Aspects of Nanotechnology

Ethylene Glycol Based Ferrofluid for the Fabrication of Magnetically Deformable Liquid Mirrors

A low-cost, high-efficiency solar cell based on dye-sensitized colloidal TiO 2 films

Nanoparticles-A historical perspective

Nanoparticles: Pharmacological and toxicological significance

Novel applications of nanotechnology in medicine

The emerging nanomedicine landscape

What is nanomedicine?

Changing patterns of infectious disease

Antimicrobial-Drug Resistance

Cholesteroled polymer (Chol-b-Lys)-based nanoparticles (CL-NPs) confer antibacterial efficacy without resistance

Survey of resistance of Pseudomonas aeruginosa from UK patients with cystic fibrosis to six commonly prescribed antimicrobial agents

Urinary tract infection and antimicrobial susceptibility pattern of extended spectrum beta lactamase producing clinical isolates

Prevalence of blaNDM-1 among Gram negative bacteria from clinical samples of Tamin Nadu

Mechanisms of Tigecycline Resistance among Klebsiella pneumoniae Clinical Isolates

The clinical consequences of antimicrobial resistance

No Drugs: No ESKAPE! An Update from the Infectious Diseases Society of America

New ways to treat bacterial infections

Silver nanoparticles as a new generation of antimicrobials

Toxicity of gold nanoparticles functionalized with cationic and anionic side chains

Does the Antibacterial Activity of Silver Nanoparticles Depend on the Shape of the Nanoparticle? A Study of the Gram-Negative Bacterium Escherichia coli

Natural Organic Matter Stabilizes Carbon Nanotubes in the Aqueous Phase

Antimicrobial nanomaterials for water disinfection and microbial control: Potential applications and implications

The degree and kind of agglomeration affect carbon nanotube cytotoxicity

Cytotoxicity of carbon nanomaterials: Single-wall nanotube, multi-wall nanotube, and fullerene

Electronic-Structure-Dependent Bacterial Cytotoxicity of Single-Walled Carbon Nanotubes

Impact of solution chemistry on viral removal by a single-walled carbon nanotube filter

Cationic fullerenes are effective and selective antimicrobial photosensitizers

Mechanisms of carbon nanotube-induced toxicity: Focus on oxidative stress

The Activity of [60]Fullerene Derivatives Bearing Amine and Carboxylic Solubilizing Groups against Escherichia coli: A Comparative Study

Medicinal Chemistry and Pharmacological Potential of Fullerenes and Carbon Nanotubes

Photodynamic therapy with a cationic functionalized fullerene rescues mice from fatal wound infections

Synthesis, Characterization and Antibacterial Activity of Chlorophyllin Functionalized Graphene Oxide Nanostructures

The use of nanoparticles in anti-microbial materials and their characterization

Chemiosmotic Mechanism of Antimicrobial Activity of Ag+ in Vibrio cholerae

The increasing use of silver-based products as antimicrobial agents: A useful development or a cause for concern?

Antibacterial activities of zinc oxide nanoparticles against Escherichia coli O157:H7

Preparation, characterization and evaluation of a biopolymeric gold nanocomposite with antimicrobial activity

Nanoparticles in Energy Technology: Examples from Electrochemistry and Catalysis

A historical review of the use of silver in the treatment of burns. II. Renewed interest for silver

Biogenic synthesis of silver nanoparticles and their synergistic effect with antibiotics: A study against gram-positive and gram-negative bacteria

Effects of silver nanoparticles on microbial growth dynamics

Photocatalytic action of AgCl nanoparticles and its antibacterial activity

Growth kinetics and mechanistic action of reactive oxygen species released by silver nanoparticles from Aspergillus niger on Escherichia coli

Unique Cellular Interaction of Silver Nanoparticles: Size-Dependent Generation of Reactive Oxygen Species

Silver nanoparticles induce oxidative cell damage in human liver cells through inhibition of reduced glutathione and induction of mitochondria-involved apoptosis

A review of the in vivo and in vitro toxicity of silver and gold particulates: Particle attributes and biological mechanisms responsible for the observed toxicity

Exposure-Related Health Effects of Silver and Silver Compounds: A Review

In Vitro Cytotoxicity of Nanoparticles in Mammalian Germline Stem Cells

Functionalised gold nanoparticles for controlling pathogenic bacteria

An investigation into the effects of silver nanoparticles on antibiotic resistance of naturally occurring bacteria in an estuarine sediment

Zinc Oxide Protects Cultured Enterocytes from the Damage Induced by Escherichia coli

Modifying of Cotton Fabric Surface with Nano-ZnO Multilayer Films by Layer-by-Layer Deposition Method

Size-dependent antimicrobial response of zinc oxide nanoparticles

Quantitative evaluation of antibacterial activities of metallic oxide powders (ZnO, MgO and CaO) by conductimetric assay

Toxicological Effect of ZnO Nanoparticles Based on Bacteria

A practical demonstration of water disinfection using TiO2 films and sunlight

Selective toxicity of zinc oxide nanoparticles to prokaryotic and eukaryotic systems

Enhancement of solar inactivation of Escherichia coli by titanium dioxide photocatalytic oxidation

Sublethal effects of ultraviolet A radiation on Enterobacter cloacae

Photocatalytic antibacterial effect of TiO2 film formed on Ti and TiAg exposed to Lactobacillus acidophilus

Bactericidal activity of photocatalytic TiO(2) reaction: Toward an understanding of its killing mechanism

Comparative eco-toxicity of nanoscale TiO 2 , SiO 2 , and ZnO water suspensions

Antimicrobial efficiency of titanium dioxide-coated surfaces

A Multifunctional Biocide/Sporocide and Photocatalyst Based on Titanium Dioxide (TiO 2 ) Codoped with Silver, Carbon, and Sulfur

Antibacterial and antifungal activity of a soda-lime glass containing copper nanoparticles

Toxicity of manufactured copper nanoparticles-A review

Strain specificity in antimicrobial activity of silver and copper nanoparticles

Genes involved in copper resistance influence survival of Pseudomonas aeruginosa on copper surfaces

The survival of Escherichia coli O157 on a range of metal surfaces

Effects of temperature and humidity on the efficacy of methicillin-resistant Staphylococcus aureus challenged antimicrobial materials containing silver and copper

Susceptibility constants of Escherichia coli and Bacillus subtilis to silver and copper nanoparticles

Characterisation of copper oxide nanoparticles for antimicrobial applications

Antimicrobial sensitivity of Escherichia coli to alumina nanoparticles

Characterization of Nanomaterial Dispersion in Solution Prior to In Vitro Exposure Using Dynamic Light Scattering Technique

Bactericidal Efficacy of Nitric Oxide-Releasing Silica Nanoparticles

The effects of topical treatment with acidified nitrite on wound healing in normal and diabetic mice

Nanotechnology approaches for global infectious diseases

The emergence of nanomedicine: A field in the making

Antibacterial Activity of Silver Nanoparticles: Structural Effects

Co-precipitation method of synthesis and characterization of iron oxide nanoparticles

Potential toxicity of superparamagnetic iron oxide nanoparticles (SPION)

Preparation and properties of magnetic Fe3O4-chitosan nanoparticles

Biomedical applications of superparamagnetic iron oxide nanoparticles encapsulated within chitosan

Antibacterial Efficacy of Iron-Oxide Nanoparticles against Biofilms on Different Biomaterial Surfaces

Evaluation of antibacterial activity of Fe 2 O 3 nanoparticles against Shigella dysenteriae

Inactivation of Pseudomonas aeruginosa PA01 biofilms by hyperthermia using superparamagnetic nanoparticles

Antibacterial properties of nanoparticles

Enhanced Efficacy of Superparamagnetic Iron Oxide Nanoparticles Against Antibiotic-Resistant Biofilms in the Presence of Metabolites

Panorama of poly-ε-lysine

Superparamagnetic iron oxide nanoparticles (SPION) for the treatment of antibiotic-resistant bio-films

The use of superparamagnetic nanoparticles for prosthetic biofilm prevention

Cefazolin loadedchitosan nanoparticles to cure multi drug resistant Gram-negative pathogens

Silver Nanoparticles Synthesized Using Caesalpinia sappan Extract as Potential Novel Nanoantibiotics Against Methicillin-Resistant Staphylococcus aureus

Basic and applied studies on ε-polylysine

Polymeric materials with antimicrobial activity

Interaction of Al 2 O 3 nanoparticles with Escherichia coli and their cell envelope biomolecules

Mechanisms of action of disinfectants

Amphiphilic block and statistical siloxane copolymers with antimicrobial activity

Antimicrobial activity of phenol and benzoic acid derivatives

Synthesis of water-soluble thermosensitive polymers having phosphonium groups frommethacryloyloxyethyl trialkyl phosphonium chlorides-N-isopropylacrylamide copolymers and their functions

Evaluation of a polymer coating containing triclosan as the antimicrobial layer for packaging materials

Formation and enhanced biocidal activity of water-dispersable organic nanoparticles

Hydrolysis and antibacterial activity of polymers containing 8-quinolinyl acrylate

Effect of abiotic factors on the antibacterial activity of chitosan against waterborne pathogens

Preparation and antibacterial activity of chitosan nanoparticles

In vitro screening for anti-microbial activity of chitosans and chitooligosaccharides, aiming at potential uses in functional textiles

Chitosan as antimicrobial agent: Applications and mode of action

The chemistry and applications of antimicrobial polymers: A state-of-the-art review

Characterisation of the antibacterial effect of polyethyleneimine nanoparticles in relation to particle distribution in resin composite

Polyethyleneimine nanoparticles incorporated into resin composite cause cell death and trigger biofilm stress in vivo

Preparation and characterization of nanoTiO2 antibacterial corrugating medium

Evaluation of nanocomposite packaging containing Ag and ZnO on shelf life of fresh orange juice

PLA/organoclay bionanocomposites impregnated with thymol and cinnamaldehyde by supercritical impregnation for active and sustainable food packaging

Nanoparticles: Alternatives against drug-resistant pathogenic microbes

Nano-therapeutics: A revolution in infection control in post antibiotic era

Antimicrobial activity of the metals and metal oxide nanoparticles

Nanomaterials for alternative antibacterial therapy

A review of mammalian toxicity of ZnO nanoparticles

Mechanism of antibacterial activity of copper nanoparticles

Metal nanobullets for multidrug resistant bacteria and biofilms

Superparamagnetic Iron Oxide Nanoparticles-Current and Prospective Medical Applications

The antimicrobial effects and mechanism of ε-poly-lysine against Staphylococcus aureus

An Overview of Chitosan Nanoparticles and Its Application in Non-Parenteral Drug Delivery

Effects of Quaternary-Ammonium-Based Formulations on Bacterial Community Dynamics and Antimicrobial Susceptibility

Biocidal Materials with Superior Antimicrobial Efficacies for Wound Dressings

Antibacterial effects of quaternary bis-phosphonium and ammonium salts of pyridoxine on Staphylococcus aureus cells: A single base hitting two distinct targets?

Medicinal applications of fullerenes

Carbon Nanotube Assembly and Integration for Applications

Carbon Nanotubes: A Review of Their Properties in Relation to Pulmonary Toxicology and Workplace Safety

Antibacterial activity of graphene oxide nanosheet against multidrug resistant superbugs isolated from infected patients

Antibacterial Properties of Graphene-Based Nanomaterials

Antibacterial potential of nanocomposite-based materials-a short review

Antibacterial Activity of Nanocomposites of Copper and Cellulose

Antibacterial Activities of Aliphatic Polyester Nanocomposites with Silver Nanoparticles and/or Graphene Oxide Sheets

Historical review of the use of silver in the treatment of burns. I. Early uses

Modern applications of plasmonic nanoparticles: From energy to health

Silver nanoparticles as antimicrobial agent: A case study on E. coli as a model for Gram-negative bacteria

A review on the application of inorganic nano-structured materials in the modification of textiles: Focus on anti-microbial properties

Coating of ZnO Nanoparticle on Cotton Fabric to Create a Functional Textile with Enhanced Mechanical Properties

Hydroxyapatite-supported Ag-TiO 2 as Escherichia coli disinfection photocatalyst

Disinfection of surfaces by photocatalytic oxidation with titanium dioxide and UVA light

Oxidative stress following exposure to silver and gold nanoparticles in mice

Single-Walled Carbon Nanotubes Exhibit Strong Antimicrobial Activity

Nano-C60 cytotoxicity is due to lipid peroxidation

The mechanism of cell-damaging reactive oxygen generation by colloidal fullerenes

Modeling the Release Kinetics of Poorly Water-Soluble Drug Molecules from Liposomal Nanocarriers

Modeling Drug-Carrier Interaction in the Drug Release from Nanocarriers

Development of a Highly Active Nanoliposomal Irinotecan Using a Novel Intraliposomal Stabilization Strategy

Therapeutically optimized rates of drug release can be achieved by varying the drug-to-lipid ratio in liposomal vincristine formulations

Liposomal Delivery of Hydrophobic Weak Acids: Enhancement of Drug Retention Using a High Intraliposomal pH

Determination of Drug Release Kinetics from Nanoparticles: Overcoming Pitfalls of the Dynamic Dialysis Method

Nanoengineered Drug Delivery Systems for Enhancing Antibiotic Therapy

Polymer nanoparticles

Development of nanoantibiotic delivery system using cockle shell-derived aragonite nanoparticles for treatment of osteomyelitis

Polyelectrolyte complex of vancomycin as a nanoantibiotic: Preparation, in vitro and in silico studies

Single-walled carbon nanotubes-ciprofloxacin nanoantibiotic: Strategy to improve ciprofloxacin antibacterial activity

Combating Antibiotic Resistance through the Synergistic Effects of Mesoporous Silica-Based Hierarchical Nanocomposites

pH-triggered controllable release of silver-indole-3 acetic acid complexes from mesoporous silica nanoparticles (IBN-4) for effectively killing malignant bacteria

Plantnanoparticle interaction: An approach to improve agricultural practices and plant productivity

Biosynthesis of Nanoparticles by Microorganisms and Their Applications

Novel microbial route to synthesize ZnO nanoparticles using Aeromonas hydrophila and their activity against pathogenic bacteria and fungi

Antibacterial activity of ruthenium nanoparticles synthesized using Gloriosa superba L. leaf extract

Synthesis of Gold Nanotriangles and Silver Nanoparticles Using Aloe vera Plant Extract

Biosynthesis of silver and gold nanoparticles by novel sundried Cinnamomum camphora leaf

Enrichment and separation of silver from waste solutions by metal ion imprinted membrane

The potential of nanofibers and nanobiocides in water purification

Lactic acid bacteria as reducing and capping agent for the fast and efficient production of silver nanoparticles

Biological synthesis of metallic nanoparticles

The greener synthesis of nanoparticles

Alfalfa sprouts: A natural source for the synthesis of silver nanoparticles

Biotechnological synthesis of functional nanomaterials

Advances in green synthesis of nanoparticles

Fungus-mediated biosynthesis and characterization of TiO 2 nanoparticles and their activity against pathogenic bacteria

Ultra-rapid photocatalytic activity of Azadirachta indica engineered colloidal titanium dioxide nanoparticles

Biological synthesis of copper nanoparticles using plant extract

Optical Properties of Selenium Quantum Dots Produced with Laser Irradiation of Water Suspended Se Nanoparticles

Biosynthesis of cadmium sulfide quantum semiconductor crystallites

Bacterial Aerobic Synthesis of Nanocrystalline Magnetite

Green synthesis of CuO nanoparticles using Gloriosa superba L. extract and their antibacterial activity

Extracellular biosynthesis of silver nanoparticles using the fungus Fusarium oxysporum

Analysis of the inter-and extracellular formation of platinum nanoparticles by Fusarium oxysporum f. sp. lycopersici using response surface methodology

Peptidemediated reduction of silver ions on engineered biological scaffolds

Silver Nanoparticles: Synthesis and Application for Nanomedicine

Biomimetic synthesis and characterisation of protein capped silver nanoparticles

Thiosalicylic Acid-Functionalized Silver Nanoparticles Synthesized in One-Phase System

Gold Nanoparticles: Microbial Synthesis and Application in Water Hygiene Management

Fungus-Mediated Synthesis of Silver Nanoparticles and Their Immobilization in the Mycelial Matrix: A Novel Biological Approach to Nanoparticle Synthesis

Psychrotrophic yeast Yarrowia lipolytica NCYC 789 mediates the synthesis of antimicrobial silver nanoparticles via cell-associated melanin

Antibacterial Activity and Mechanism of Action of the Silver Ion in Staphylococcus aureus and Escherichia coli

Effect of silver ions on transport and retention of phosphate by Escherichia coli

Silver and gold nanoparticles synthesized from Streptomyces sp. isolated from acid forest soil with special reference to its antibacterial activity against pathogens

Biosynthesis, characterization and antibacterial activity of silver nanoparticles using an endophytic fungal supernatant of Raphanus sativus

Synthesis and antibacterial activity of of silver nanoparticles

Controlled Synthesis of Gold Nanoparticles UsingAspergillus terreusIF0 and Its Antibacterial Potential against Gram Negative Pathogenic Bacteria

Biological Synthesis of Nanoparticles from Plants and Microorganisms

Biosynthesis of gold nanoparticles by the extreme bacterium Deinococcus radiodurans and an evaluation of their antibacterial properties

Antibacterial effect of silver nanoparticles on Staphylococcus aureus

Proteomic Analysis of the Mode of Antibacterial Action of Silver Nanoparticles

Antibacterial properties of silver nanoparticles in three different sizes and their nanocomposites with a new waterborne polyurethane

Nanosilver as a new generation of nanoproduct in biomedical applications

Intra/extracellular biosynthesis of silver nanoparticles by an autochthonous strain of Proteus mirabilis isolated from photographic waste

Antibacterial Activity of Biogenic Zinc Oxide Nanoparticals Synthesised From Enterococcus faecalis

Plant molecular farming: Production of metallic nanoparticles and therapeutic proteins using green factories

Noble Metal Nanoparticles: Plant-Mediated Synthesis

Green synthesis of silver nanoparticles using Azadirachta indica aqueous leaf extract

The Green synthesis of gold nanoparticles using an aqueous root extract of Morinda citrifolia L

The inhibitory effects of silver nanoparticles, silver ions, and silver chloride colloids on microbial growth

Evaluation of Catharanthus roseus leaf extract-mediated biosynthesis of titanium dioxide nanoparticles against Hippobosca maculata and Bovicola ovis

Use of titanium dioxide nanoparticles biosynthesized by Bacillus mycoides in quantum dot sensitized solar cells

Production of nanoparticles using organisms

Green silver nanoparticles of Phyllanthus amarus: As an antibacterial agent against multi drug resistant clinical isolates of Pseudomonas aeruginosa

Green synthesis of silver nanoparticles with antibacterial activities using aqueous Eriobotrya japonica leaf extract

Antibiotics 2021

Antibacterial Activity of Green Synthesized Silver Nanoparticles Using Vasaka (Justicia adhatoda L.) Leaf Extract

Biogenic synthesis of Fe3O4 nanoparticles using tridax procumbens leaf extract and its antibacterial activity on Pseudomonas aeruginosa

Antibacterial activity of green synthesis of iron nanoparticles using Lawsonia inermis and Gardenia jasminoides leaves extract

Biogenic gold nanoparticles synthesized using Crescentia cujete L. and evaluation of their different biological activities

Green synthesis and characterization of zinc oxide nanoparticle using insulin plant ( Costus pictus D. Don ) and investigation of its antimicrobial as well as anticancer activities

Antibiofouling Properties of Plasma-Deposited Oxazoline-Based Thin Films

Plasma polymerised polyoxazoline thin films for biomedical applications

Effects of Precursor and Deposition Conditions on Prevention of Bacterial Biofilm Growth on Chlorinated Plasma Polymers. Plasma Process. Polym

Influence of immobilized quaternary ammonium group surface density on antimicrobial efficacy and cytotoxicity

Substrate Independent Approach for Immobilisation of Quaternary Ammonium Compounds to Surfaces to Reduce Bio-Burden

Controlled Release of Levofloxacin Sandwiched between Two Plasma Polymerized Layers on a Solid Carrier

Controlled and sustained release of pharmaceuticals via single step solvent-free encapsulation

Nitric oxide releasing plasma polymer coating with bacteriostatic properties and no cytotoxic side effects

Antibacterial properties of nitric oxide-releasing porous silicon nanoparticles

RAFT-derived antimicrobial polymethacrylates: Elucidating the impact of end-groups on activity and cytotoxicity

Guanylated polymethacrylates: A class of potent antimicrobial polymers with low hemolytic activity

Antimicrobial Polymethacrylates Synthesized as Mimics of Tryptophan-Rich Cationic Peptides

Responsive and smart antibacterial surfaces: Common approaches and new developments (Review)

Enzyme responsive hyaluronic acid nanocapsules containing polyhexanide and their exposure to bacteria to prevent infection

Enzymatic degradation of poly(l-lactide) nanoparticles followed by the release of octenidine and their bactericidal effects

Synthesis of Inorganic Nanomaterials

Green Nanobiotechnology: Factors Affecting Synthesis and Characterization Techniques

Counter ions and temperature incorporated tailoring of biogenic gold nanoparticles

Physicochemical condition optimization during biosynthesis lead to development of improved and catalytically efficient gold nano particles

Green Synthesis of Silver Nanoparticles UsingPinus eldaricaBark Extract

Antibiotics 2021

Biosynthesis and characterization of iron oxide nanoparticles using Eichhornia crassipes leaf extract and assessing their antibacterial activity

Effect of temperature in synthesis of silver nanoparticles in triblock copolymer micellar solution

Influence of temperature on the formation and encapsulation of gold nanoparticles using a temperature-sensitive template

Effect of reaction time on particle size and dielectric properties of manganese substituted CoFe 2 O 4 nanoparticles

Size controlled gold nanoparticle formation by Avena sativa biomass: Use of plants in nanobiotechnology

One-Pot Synthesis of Gold Nanorods by Ultrasonic Irradiation: The Effect of pH on the Shape of the Gold Nanorods and Nanoparticles

Effect of reaction time on structural and magnetic properties of green-synthesized magnetic nanoparticles

Effect of reaction time on the synthesis of cadmium selenide nanoparticles and the efficiency of solar cell

Effect of Reaction Time on the Particle Size of ZnO and ZnO:Ce Obtained by a Sol-Gel Method

Antibacterial Properties of an in situ Generated and Simultaneously Deposited Nanocrystalline ZnO on Fabrics

Bactericidal effect of iron oxide nanoparticles on Staphylococcus aureus

The antibacterial activity of Ta-doped ZnO nanoparticles

The damage of outer membrane of Escherichia coli in the presence of TiO2 combined with UV light

Nanostructures in biodiagnostics

Understanding the toxicity of aggregated zero valent copper nanoparticles against Escherichia coli

Phytosynthesis of silver nanoparticle using Gliricidia sepium

Metal Nanoparticles: Synthesis, Characterization, and Applications

Green synthesis of zinc oxide nanoparticles by Aloe barbadensis miller leaf extract: Structure and optical properties

High-resolution surface plasmon imaging of gold nanoparticles by energy-filtered transmission electron microscopy

Aloe vera extract functionalized zinc oxide nanoparticles as nanoantibiotics against multi-drug resistant clinical bacterial isolates

Green Synthesis and Characterization of Carbon Nanotubes/Polyaniline Nanocomposites

Bio-mediated synthesis of TiO 2 nanoparticles and its photocatalytic effect on aquatic biofilm

Monodisperse FePt Nanoparticles and Ferromagnetic FePt Nanocrystal Superlattices

Synthesis of cerium oxide nanoparticles using Gloriosa superba L. leaf extract and their structural, optical and antibacterial properties

Antimicrobial activity of zinc oxide nanoparticles synthesized from Aloe vera peel extract

Biogenic silver nanoparticles by Solanum torvum and their promising antimicrobial activity

Characterization of size, surface charge, and agglomeration state of nanoparticle dispersions for toxicological studies

Lattice-strain control of the activity in de alloyed core-fuel cell catalysts

Nanotechnology and pulmonary delivery to overcome resistance in infectious diseases

Nanoparticle-based drug delivery systems: Promising approaches against infections

Dendrimers in oral drug delivery application: Current explorations, toxicity issues and strategies for improvement

Vancomycin-Modified Mesoporous Silica Nanoparticles for Selective Recognition and Killing of Pathogenic Gram-Positive Bacteria Over Macrophage-Like Cells

Bacteria-Responsive Multifunctional Nanogel for Targeted Antibiotic Delivery

Lipid-polymer hybrid nanoparticles as a new generation therapeutic delivery platform: A review

Novel multifunctional pH-sensitive nanoparticles loaded into microbubbles as drug delivery vehicles for enhanced tumor targeting

Magnetic targeted drug delivery carriers encapsulated with pH-sensitive polymer: Synthesis, characterization and in vitro doxorubicin release studies

Advancements on the molecular design of nanoantibiotics: Current level of development and future challenges

Therapeutic strategies to combat antibiotic resistance

Nosocomial bacteremia due to Acinetobacter baumannii: Epidemiology, clinical features and treatment

Antimicrobial biomaterials based on carbon nanotubes dispersed in poly(lactic-co-glycolic acid)

Nanoparticles-Known and unknown health risks

Antimicrobial Activities and Mechanisms of Magnesium Oxide Nanoparticles (nMgO) against Pathogenic Bacteria, Yeasts, and

Bringing nanomedicines to market: Regulatory challenges, opportunities, and uncertainties

Emerging trends of nanomedicine-An overview. Fundam

On the Toxicity of Therapeutically Used Nanoparticles: An Overview

What do we (need to) know about the kinetic properties of nanoparticles in the body?

Toxicogenomics to Improve Comprehension of the Mechanisms Underlying Responses of In Vitro and In Vivo Systems to Nanomaterials: A Review

Drug delivery and nanoparticles: Applications and hazards

Integrated metabolomic analysis of the nano-sized copper particle-induced hepatotoxicity and nephrotoxicity in rats: A rapid in vivo screening method for nanotoxicity

Current in vitro methods in nanoparticle risk assessment: Limitations and challenges

Authors are thankful to our supporting fellows.

The authors declare no conflict of interest.