key: cord-0685157-91k8zfep
authors: Deng, Yulin; Jiang, Hao; Li, Xiaoqiong; Lv, Xuefei
title: Recent advances in sensitivity enhancement for lateral flow assay
date: 2021-10-13
journal: Mikrochim Acta
DOI: 10.1007/s00604-021-05037-z
sha: 7d95eb92db136c92b8c18cf9e1b855c9ed3ba841
doc_id: 685157
cord_uid: 91k8zfep

Conventional lateral flow assay (LFA) is typically performed by observing the color changes in the test lines by naked eyes, which achieves considerable commercial success and has a significant impact on the fields of food safety, environment monitoring, disease diagnosis, and other applications. However, this qualitative detection method is not very suitable for low levels of disease biomarkers’ detection. Although many nanomaterials are used as new labels for LFA, additional readers limit their application to some extent. Fortunately, a lot of work has been done for improving the sensitivity of LFA. In this review, currently reported LFA sensitivity enhancement methods with an objective evaluation are summarized, such as sample pretreatment, the change of flow rate, and label evolution, and future development direction and challenges of LFAs are discussed.

The rapid, portable, sensitive, and inexpensive detection of analytes from complex samples is essential for in vitro diagnostics [1, 2] . It is estimated that improving the technique of diagnostic tests for infectious diseases in developing countries can annually save at least 1.2 million deaths [3] . Especially when facing the outbreak of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), a rapid and facile screening strategy, which is employed in airports, customs, and community, shows the great significance to prevent epidemic and resume shipping and economic development.

Lateral flow assay (LFA) deployed as point-of-care testing (POCT), owing to its rapidity, simplicity, stability, and visual characteristics [4] , has been vital in enabling faster diagnosis, directing medical interventions, and mitigating the transmission of infectious diseases [2] .

Conventionally, the results of LFA are read out by naked eyes, by measuring the color change due to the accumulation of gold nanoparticles (AuNPs). This detection strategy is simple and rapid, and the early pregnancy test is the outstanding representative. However, these results are qualitative and lack of sensitivity and may function only for certain applications. As for the detection of critical biochemical markers present in extremely small amounts in a sample, such as myocardial infarction and cancer, these methods do not afford sufficient sensitivity, which restrict their applications. In recent years, the development of new nanomaterials has broadened the type of labels available for LFA to enhance sensitivity. These nanomaterials can be roughly divided into three categories according to the type of readout [5] , that is, naked-eye detection, fluorescence detection, and non-optical readout detection. Carbon nanoparticles [6, 7] , carbon nanotubes [8, 9] , and dye-loaded latex beads [10, 11] can provide an alternative to AuNPs for naked-eye detection. Fluorescent labels are generally recommended for low concentrations of targets and quantitative detection. Suitable fluorescent nanoparticles include fluorescent microspheres (FMs) [12] , quantum dots (QDs) [11] , upconverting nanoparticles (UCNPs) [13] , and liposomes with fluorescent dyes [14] . LFA with non-optical readout can be comparable with that of LFA with fluorescent labels, such as magnetic nanoparticles [15] [16] [17] and nanoparticles for electrochemical readings [18] [19] [20] . However, they either cannot provide a strong signal as AuNPs for naked-eye detection or comes with a higher cost and the need for an external reader.

In order to enhance the signal-noise ratio, a lot of signal amplification methods have been employed in POCT, such

Comparing with other biomarkers, nucleic acids are more stable under harsh environments and are gradually classified as biomarkers for disease diagnosis [30] , microbial detection [31] , and environmental monitoring [32] . With an increasing demand for diagnosis under resource-limited conditions, LFA for nucleic acid detection has gained greater attention owing to the lower cost and user-friendly [33] . However, one major drawback of the current LFA for nucleic acid detection is a low sensitivity, limiting its practical applications. Different from protein biomarkers present at the level of nanomolar or picomolar, the amounts of pathogenic bacteria that cause disease can be as low as a few CFU/mL [34] . In order to enhance the sensitivity of LFA for nucleic acid detection, various isothermal amplification methods are used, including rolling circle amplification (RCA) [ 

RPA is regarded as an isothermal PCR method. Recombinase and single-stranded binding protein are used to replace the programmed temperature changing of PCR [53] . The recombinase is used to complete the dissociation of the template and the combination of primers and templates, while single-stranded binding protein is used for maintaining the single chain so that the DNA polymerase completes the primer extension process. Most importantly, it is an effective approach in terms of sensitivity, specificity, and multiplexing [54, 55] .

Zhang's group [56] established a clustered regularly interspaced short palindromic repeats (CRISPR)-based diagnostic platform, which combined RPA and LFA with CRISPR-Cas enzymology for specific recognition of desired DNA or RNA sequences, called specific high-sensitivity enzymatic reporter unlocking (SHERLOCK). The template underwent the isothermal amplification reaction of RPA to amplify the signal. At the same time, a T7 promoter was added for in vitro transcription by RPA, which was used for converting the target from DNA to RNA for detection. After recognizing the target site of RNA, Cas13a would nonspecifically cleave molecular beacons to generate signals. For RNA target, reverse transcription was necessary.

To date, RPA integrated with LFA has been widely used in the detection of pathogenic bacteria and viruses in food safety [57] [58] [59] , environmental monitoring [37] , and other biomedical fields [60, 61] .

The core principle of LAMP is to design 2 or 3 pairs of primers for 6 regions of the target gene fragment to achieve rapid and efficient amplification [62] . Similar to nested PCR, multiple primers of LAMP strictly and efficiently ensured specificity. And, it is not affected by nontarget DNA and PCR inhibitors with high similarity to the target DNA [63, 64] .

Dou and co-workers [51] integrated polydimethylsiloxane (PDMS)/paper hybrid microfluidic chip with LAMP for Neisseria meningitidis detection (Fig. 1B) . Compared with the results of previous studies [65] , the introduction of paper into the microfluidic device for LAMP enabled more stable results than that of a paper-free microfluidic system. The LOD was about 3 copies of DNA, which was lower than that of other studies [66, 67] .

Facing the COVID-19, Zhang's group [52] developed an upgraded version of the new coronavirus detection process based on SHERLOCK, called STOPCovid (Fig. 1C) . The RNA in the sample was enriched by adding magnetic beads during the sample preparation process, thereby increasing the amount of initial RNA in LMAP and further improving the detection sensitivity. In addition, STOPCovid version 2.0 streamlined the operating steps of RNA enrichment with magnetic beads, removed the ethanol washing and eluting process, and shortened the whole time of the entire RNA enrichment process to less than 15 min.

Furthermore, LAMP integrated with LFA has also been used in the detection of E. coli [68] , plasmodium [64] , P. aeruginosa [69] , and SARS-CoV-2 [70] .

Unlike nucleic acid, protein can not achieve quantity increasing by amplification. Fortunately, enrichment strategies, such as isoelectric electrophoresis, dialysis, and magnetic enrichment, can be integrated with protein detection to increase the concentration and enhance the detection sensitivity.

Paper-based ion concentration polarization (ICP) preconcentrators were integrated with LFA by Kim et al. [71] to enhance the detecting sensitivity of β-human chorionic gonadotropin (β-hCG) ( Fig. 2A) . Through a simple 9 V battery and low power consumption (about 81 μW), a preconcentration factor of 25-folds was obtained, and the detection sensitivity was enhanced by 2.69 times compared with that of the commercial LFA for β-hCG.

Isotachophoresis (ITP) was used by Moghadam et al. [72] to focus target analytes into a thin band and then was transported to the test line of LFA, resulting in a dramatic increase in the surface reaction rate and equilibrium binding (Fig. 2B ). This strategy can improve the sensitivity of LFA by 400-fold compared with that of the commercial LFAs for β-hCG.

Kamei's group [53] firstly developed an aqueous twophase system (ATPS) to concentrate a target biomarker into a smaller volume before loading it onto LFA. Using this method, a tenfold improvement in the overall detection sensitivity of LFA was achieved for bacteriophage M13 [75] and transferrin (Tf) [76] . In addition, this newly discovered concentrating phenomenon suggested that the paper membrane sped up the macroscopic phase separation of ATPS.

Chiu et al. [73] expanded the paper device vertically, thereby increasing the cross-sectional area of flow and exploiting the effects of gravity on macroscopic separation (Fig. 2C ). In addition to accelerating phase separation, this 3-D component also enhanced the ability to process larger and more diluted volumes of sample. The novel integration of ATPS and LFA within a 3-D paper well successfully yielded a tenfold improvement in the detection of transferrin.

Tang et al. [74] integrated the semi-permeable membrane, glass fiber, and PEG buffer with LFA for samples enrichment (Fig. 2D ). PEG-loaded glass fiber was used as the dialysate for sample concentrating. Compared with that of the conventional LFA, tenfold signal enhancement in HIV detection and fourfold signal enhancement in myoglobin detection have been achieved, respectively.

Paper-based ICP pre-concentrators integrated with LFA for β-hCG detection [71] . B Experimental setup for (a) ITP-enhanced LFA and (b) conventional LFA. (c) Experimental snapshots were taken at 5 different time points [72] . C The 3-D paper is well combined with ATPS and LFA for transferrin detection [73] . (a) The 3-D paper well device was combined with a transferrin competition assay on nitrocellulose paper. Samples containing no transferrin were correctly diagnosed when using the (b) 1:1 or (c) 9:1 volume ratio of ATPS solutions. D Schematic of the integrated device of the semi-permeable membrane, glass fiber, and PEG buffer into with LFA [74] Sensitivity enhancement based on magnetic enrichment

Taking advantage of supermagnetism, magnetic bead-based separation is used as a convenient way to perform sample pretreatment and eliminate the interference of food matrices in LFA. Generally, aptamers [77, 78] or antibodies [79, 80] are labeled with magnetic beads for target capturing.

Besides the capability of fast separation in the magnetic field, magnetic nanoparticles or magnetic beads possess the color of brown and can provide low background noise, which make them ideal label materials of LFA [6] . Zhang et al. [81] developed a multiple immunoassay test strip based on Fe 3 O 4 superparamagnetic nanosphere (SPMN) probes, which was used to enrich samples and quench the fluorescence of multiple fluorescer on the test line (Fig. 3 ). Simultaneous detection of carcinoembryonic antigen (CEA) and carbohydrate antigen (CA153) was realized with LOD of 0.06 ng/mL and 0.6 U/mL, respectively.

Another critical factor affecting the sensitivity of LFA is the time for the immunoreaction between the analyte and the capture antibody pre-deposited on the test line, which depends on the migration time of the sample over the test line [82] . The decrease in the reaction time causes insufficient time for the antibody-antigen reaction [83] , so a test should be long enough for a sufficient antibody-antigen reaction. An increase in the distance from the conjunction pad to the test line can increase the reaction time [84] . An increase in the pore size of a nitrocellulose membrane can decrease the amount of bound protein and increase the flow rate. And, the rapid migration times caused a high signal-noise ratio [85] . More importantly, some engineering methods, such as flow block and NC membrane size change, have been developed for LFA sensitivity enhancement.

Rivas et al. [86] developed delay hydrophobic barriers fabricated by wax printing to improve LFA sensitivity (Fig. 4A) . When running buffer flows through the wax barrier, microfluidics delay and pseudo-turbulent flow were generated in the columnar region, which improved the sensitivity of almost 3-folds in comparison to a commercial barrier-free LFA.

However, the wax barrier on the NC membrane of LFA might melt during the process of heating [89] . A piece of paper-based shunt and a polydimethylsiloxane (PDMS) barrier were integrated with LFA by Choi et al. [87] to achieve optimal fluidic delays, and tenfold signal enhancement was obtained for detecting hepatitis B virus (HBV) nucleic acid (Fig. 4B) . In further studies, Choi et al. [88] used agarose as the barrier due to its strong permeability, excellent mechanical properties, easier fluid control, and tunable pore size and porosity (Fig. 4C) . Remarkably, this detecting strategy enhanced the sensitivity nearly 10-folds with a detection Fig. 3 Mechanism of magnetic fluorescence-based LFA platform for CEA and CA153 detection [81] limit of 100 copies of dengue viral RNA, which yielded comparable or more sensitive result than that of the published techniques of enzyme enhancement [90] , temperature and humidity control [91] , and fluidic control by hydrophobic barriers [86] .

Katis et al. [92] used spatial constrictions in the flow path as a route to increase the sensitivity and lower the LOD of LFA, due to the slower flow rate and the smaller test zone area (Fig. 5A ). The liquid photopolymer was locally deposited onto the paper substrate with a deposition nozzle. A laser beam subsequently followed the deposition head, illuminated the deposited patterns, and induced the photopolymerization of the polymer (Fig. 5B) . The polymerized patterns defined the fluidic walls, which served as demarcation barriers to confine and transport the liquids within the paper device. The LOD of C-reactive protein (CRP) was 5 ng/mL with a 1-mm-wide constriction, which was a 30-fold enhancement compared with that of the standard LFA with the width of 5 mm. [87] . C Schematic diagram of fluidic control in a paper-agarose hybrid material-based LFA [88] Fig. 5 Sensitivity enhancement based on NC membrane size change [92] . A Schematic of the flow path constriction device (a) and a standard lateral flow device (b). B Schematic of the modified laser-based direct-write procedure

With an increase in the particle size of AuNPs, the molar extinction coefficient is significantly enhanced [93, 94] . Therefore, a larger particle size of AuNPs as the labeling nanomaterial is more conducive to improve the sensitivity [95] .

Choi et al. [96] used two different sizes of AuNPs to realize the sensitive detection of cardiac troponin I (cTnI) by LFA (Fig. 6A ). The first conjugate was AuNPs (10 nm) coated with anti-troponin I antibody and blocked with bovine serum albumin (BSA), and the second conjugate was AuNPs (40 nm) coated with anti-BSA antibody and blocked with human serum albumin. Double AuNP-based LFA can detect as low as 0.01 ng/mL of cTnI within 10 min, which was enhanced about 100 times compared with that of Posthuma-Trumpie' research [97] . This dual-labeling strategy was subsequently optimized for the on-site and sensitive detection of melamine in milk, offering a 10-to 25-fold improvement [98] . Later, this method was used in detecting bisphenol A (BPA) [99] , Hg 2+ [100] , and procalcitonin (PCT) [101] .

Inspired by GNSs, the method of silver staining was developed to change the shape of AuNPs.

Silver staining is another method for signal amplification via the color change at the test line based on chemical reactions [106] . These reactions involve the catalytic reduction of silver ions on gold nanoparticles, which produces larger absorbance values for gold nanoparticles and darker colors at the test lines of LFA [107] .

Yang et al. [108] used silver staining in LFA for the first time. When a visible red color appeared on the detection area, the NC membrane was covered with an AgNO 3 pad, and on which the reducer pad was placed. The produced larger size of silver particles was used to change the color of the detection line from red to black which made the contrast more obvious. A 100-fold improvement in sensitivity with a detection limit of 0.1 ng/mL for abrin-a was obtained. Kim et al. [102] used core-shell hybrid nanofibers and silver staining technique to detect cTnI. AgNO 3 and silver-reducing reagent of hydroquinone solutions were separately encapsulated by electrospinning (Fig. 6C) . The silver ions were reduced to metallic silver around AuNPs and the color of the test line was darkened. The obtained detection limit for cTnI was 0.24 ng/mL, and the sensitivity was enhanced by up to 10 times compared with that of the commercial LFA. Anfossi et al. [103] used this method to realize the detection of ochratoxin A (OTA) by competitive LFA (Fig. 6D) , and the sensitivity was enhanced by 10 Fig. 6 Sensitivity enhancement based on colorimetric methods. A Dual AuNPs LFA was used for cTnI detection; the sizes of AuNPs were 10 nm and 40 nm, respectively [96] . B Schematic of a hybrid nanofiber-deposited LFA kit and the time-dependent changes of the conjugate pad (P), electrospun nanofibers E, test line (T), and control line C during the signal-enhanced assay [102] . C Expected effects of silver staining on LFA sensitivity enhancement [103] . D (Left) Results of LFA for different concentrations of human IgG and the different substrates. (Right) Results were obtained with the strip reader [90] . E Schematic of AuNP-assisted signal amplification on LFA for pathogen detection [104] . F (a) Schematic of EASE. (b) The relationship between dopamine accumulation and time in the presence of HRP [105] times compared with that of the traditional LFA for OTA detection [109] .

Inspired by the wide use of enzymes as labels in bioassays, the nano-carrier-enzyme probes have been used in LFA to improve the detecting performance of various optical and electronic biosensing systems [110] [111] [112] [113] .

In the study of Parolo et al. [90] , AuNPs were used not only as labels for antibodies, but also as carriers for enzymes (Fig. 6E) . When acting as direct labels, AuNPs turned red at the test line and the control line of LFA. However, after AuNPs conjugating with antibody and blocking with horseradish peroxidase (HRP), the produced insoluble chromogens cannot move by the flow and then darken the color of the lines. By comparing three substrates (TMB for blueviolet, AEC for red [114] , and DAB for gray-black [115] ), it was found that TMB is optimal for signal enhancement maintaining at an order of magnitude.

Cho et al. [104] used the abovementioned signal amplification technique for E. coli O157:H7 detection (Fig. 6F) . The obtained detection limit was 100 CFU/mL, which was about 1000 times lower than that of the traditional AuNPbased LFA.

Li et al. [105] developed a universal "add-on" technique called enzyme-accelerated signal enhancement (EASE) (Fig. 6G) . EASE depended on the ultrafast and localized deposition of polydopamine (PDA) at the test line [94] , permitting a large number of signal molecules to be captured and leading to sensitivity enhancement over three orders of magnitude. Under the normal conditions of using DAB as the substrate, p24 at the concentration of 10 ng/mL can be detected by LFA, while by EASE, the detection limit can be obtained at the level of 10 pg/mL, allowing the ultrasensitive detection of HIV antigens with naked eyes.

In the excitation region of some specially prepared metal conductor surfaces or solutions, a stronger Raman signal caused by surface roughness can be observed, which is called surface-enhanced Raman scattering (SERS). Compared with traditional Raman scattering, SERS can realize 6 orders of magnitude or more [116] .

Covian et al. [117] developed SERS-based LFA to detect pneumolysin by using gold-core-silver-shell nanoparticles as the plasmonic platform and rhodamine B isothiocyanate as Raman tag. Compared with the results of the electrochemical immunosensor with the detection limit of 0.6 ng/ mL [118] and the chemiluminescence immunoassay with the detection limit of 5.5 pg/mL [119] , the sensitivity of SERS-based LFA was enhanced with the detection limit of 1 pg/mL.

It has been proved that SERS nanotags have the coding capacity by absorbing different Raman dyes on the surface of the metal [120] , which made it possible to realize multiple detections. Zhang et al. [121] encapsulated Raman dye Nile Blue A (NBA) in the interface of the core-shell structure (Fig. 7A) , and based on the core-shell SERS nanotags, a novel LFA was developed to realize rapid quantification of creatine kinase isoenzyme (CK-MB), cTnI, and myoglobin (Myo) on three test lines with a detection limit of 0.55, 0.44, and 3.2 pg/mL, respectively, which decreased the LOD nearly three orders of magnitude than that of the colorimetric detection [122, 123] . In the follow-up study, Zhang et al. [124] encapsulated Raman dyes methylene blue (MB), Nile blue A (NBA), and rhodamine 6G (R6G) in the core-shell interface to achieve rapid quantification of three cardiac biomarkers on a single test line with the similar detection limit (Fig. 7B) .

The stability of Raman dye plays a pivotal role in sensitive and accurate detection. Gao et al. [126] developed Au nanostar @ Raman dye @ silica sandwich nanoparticles for the detection of neuron-specific enolase (NSE), a marker of traumatic brain injury (TBI), with the LOD of 0.86 ng/ mL. By wrapped between AuNPs and thin silica, Raman dyes malachite green isothiocyanate (MGITC) can be effectively stabilized. Compared with the traditional colorimetric method, the SERS-based method exhibited excellent performance especially in the matrix of plasma [127] . Hwang et al. [125] combined hollow gold nanospheres (HGN) with Raman dye MGTTC to achieve the detection of staphylococcal enterotoxin B (SEB) (Fig. 7C ). With the advantage of HGN enhancing SERS signal, high-sensitivity detection with a LOD of 1 pg/mL was realized, and more than 30 times enhancement was obtained compared with that of the traditional ELISA.

Li et al. [128] developed a quantitative photothermalsensing LFA for enrofloxacin detection with the detection limit of 0.023 ng/mL (Fig. 8A) . Black phosphorus (BP)-Au nanosheets showed good photothermal properties at the wavelength of 808 nm, and the photothermal conversion efficiency was enhanced by 12.9% compared with that of the black phosphorus nanosheets alone. Qin et al. [129] developed a thermal contrast-based technique to improve the sensitivity of LFA (Fig. 8B) . The sensitivity can be enhanced by 32 times compared with that of the FDA-approved LFA for cryptococcal antigen (CrAg) detection.

Wang et al. [131] developed a thermal contrast magnification (TCA) reader, which was composed of an emitter for lasers of multiple wavelengths emitting, an infrared camera for the generated heat reading, and software for data reading and analysis. The reader can significantly increase the accuracy of antigen quantification by LFA. Compared with naked eyes or colorimetric readers (such as BD VeritorTM system readers), the TCA reader possessed a higher sensitivity of 8 times for detection of malaria and C. difficile [97, 132] .

Laser speckle is the high-contrast random granular pattern, which is extremely sensitive to the refractive index and physical displacement of the medium [133, 134] . NC Fig. 7 Sensitivity enhancement based on SERS. A Schematic illustration of the core-shell SERS nanotag-based multiplex LFA for three cardiac biomarkers detection [121] . B Schematic illustration of quantitative LFA for three cardiac biomarkers detection on a single T line with different roman dyes encoded core-shell SERS nanotags [124] . [129] . C Schematic of the PT-LSI sensor [130] . (a) A 780-nm light illuminated the NC membrane of LFA. (b) The absorbed light energy was converted into heat, and the resultant temperature increase altered the speckle pattern. (c) Exemplary speckle images before (green) and after (blue) photothermal illumination membrane is composed of randomly oriented nanofibers, so it can be used as a diffusion medium to generate highcontrast speckle patterns. Song et al. [130] developed a photothermal laser speckle imaging (PT-LSI)-based LFA (Fig. 8c) . The sensitivity can be enhanced by 68 times compared with that of the FDA-approved LFA for CrAg detection. The detecting ability of the developed PT-LSILFA was verified for CrAg detection by US FDAapproved LFA, and it was found that the detection sensitivity of PT-LSI was enhanced by 68 times.

All the parameters of the abovementioned LFA for rapid detection are compared and summarized in Table 1 .

LFA has been proven to be a rapid, sensitive, and costeffective method for point-of-care and in-field diagnosis in resource-limited areas such as developing countries and rural areas. However, there are long-standing criticisms of LFA as POCT, such as limited sensitivity, limited ability for quantification, inability for multistep performing, and inability to multiplexing.

In this paper, recent development and breakthroughs of the sensitivity enhancement for LFA are reviewed, such as sample pretreatment, changes in structure, materials, and labels, with an objective evaluation. For sample pretreatment, various isothermal nucleic acid amplification techniques, such as RCA, LAMP, and RPA, have been used in LFA, which makes the detection more sensitive. However, there are still challenges associated with the integration of amplification and detection into a single device. In addition, the reproducibility of complex enzymatic reactions should be considered. Changing the flow rate to enhance sensitivity through the flow barrier extends the time for antibody-antigen reaction; however, structural changes increase the difficulty of engineering and undoubtedly limit the application of LFA to some extent. AuNPs are the most popular labels for LFA. AuNPs integrated with other materials such as silver, gold, enzymes, or catalytic metals can further enhance the sensitivity of LFA, but this strategy has limitations regarding the preparation, purification, storage, and detection steps. [128] [129] [130] [131] Accordingly, the latest research indicates that there is still a large development space for LFA with smaller demand volume, shorter analysis time and the absence of hook effect, and higher accuracy and sensitivity. Here, several possible directions for sensitivity enhancement of LFA are summarized as follows.

Firstly, the development of new materials, including new labels, probes, and paper-based materials. The super-strong signal characteristics of aggregation-induced emission (AIE) molecules in the solid phase are promising to become an excellent label for LFA. Novel capturing/detecting probes, such as nanobodies, short peptides, and aptamers, are also being developed to enhance stability, to increase detection sensitivity, and to minimize the cross reaction. In addition, with the smaller molecular weight, they can be used to target small molecules or epitopes that are inaccessible for conventional antibodies.

Secondly, for the detection of nucleic acid, a certain nucleic acid amplification method is currently used for sample pretreatment. However, a single nucleic acid amplification method may not satisfy the detecting requirements. Therefore, a cascade amplification detection method that uses two or even multiple nucleic acid amplification methods integrated with LFA will be great development potential.

Finally, miniaturization and optimization of LFA devices are another vital goal for the sensitivity enhancement of LFA. It must be noted that among LFA detection methods, optical methods based on AuNPs and their derivatives are most likely to be one of the most viable POCT devices, given their simplicity and easy integration in conventional LFA. Therefore, significant engineering efforts should be focused on miniaturizing the whole process to be used in portable devices, which will be affordable and portable in field conditions and resource-limited settings. 

Emerging design strategies for constructing multiplex lateral flow test strip sensors

Strategies for developing sensitive and specific nanoparticle-based lateral flow assays as point-of-care diagnostic device

Diagnostic point-of-care tests in resource-limited settings

Microfluidic chips for point-of-care immunodiagnostics

Tutorial: Design and fabrication of nanoparticle-based lateral-flow immunoassays

Point-of-care detection of extracellular vesicles: sensitivity optimization and multiple-target detection

Carbon nanoparticles in lateral flow methods to detect genes encoding virulence factors of shiga toxin-producing escherichia coli

Carbon nanotubebased lateral flow biosensor for sensitive and rapid detection of DNA sequence

Mwcnts based high sensitive lateral flow strip biosensor for rapid determination of aqueous mercury ions

Improved serodetection of mycobacterium bovis infection in badgers (meles meles) using multiantigen test formats

Photo luminescent lateral-flow immunoassay revealed by graphene oxide: highly sensitive paper-based pathogen detection

Aptamer-based fluorometric lateral flow assay for creatine kinase mb

Rapid and background-free detection of avian influenza virus in opaque sample using nir-to-nir upconversion nanoparticle-based lateral flow immunoassay platform

Liposome-enhanced lateralflow assays for the sandwich-hybridization detection of rna

Setting up the cut-off level of a sensitive barcode lateral flow assay with magnetic nanoparticles

Scanning magneto-inductive sensor for quantitative assay of prostate-specific antigen

Magnetic immunochromatographic test for histamine detection in wine

Electrochemical lateral flow devices: towards rapid immunomagnetic assays

Preparation of paper-based devices for reagentless electrochemical (bio)sensor strips

DNA detection using recombination proteins

Isothermal DNA amplification combined with lateral flow dipsticks for detection of biothreat agents

Detection of root-infecting fungi on coolseason turfgrasses using loop-mediated isothermal amplification and recombinase polymerase amplification

Sherlock: nucleic acid detection with crispr nucleases

Rapid and sensitive detection method for karlodinium veneficum by recombinase polymerase amplification coupled with lateral flow dipstick

Development of a rapid and sensitive recombinase polymerase amplification-lateral flow assay for detection of burkholderia mallei

Visual signal generation for the detection of influenza viruses by duplex recombinase polymerase amplification with lateral flow dipsticks

Recombinase polymerase amplification combined with lateral flow strip for listeria monocytogenes detection in food

Nucleic acid biosensor synthesis of an all-in-one universal blocking linker recombinase polymerase amplification with a peptide nucleic acid-based lateral flow device for ultrasensitive detection of food pathogens

An integrated lateral flow assay for effective DNA amplification and detection at the point of care

A paper-based device for performing loop-mediated isothermal amplification with real-time simultaneous detection of multiple DNA targets

Paper-origami-based multiplexed malaria diagnostics from whole blood

A pdms/paper/glass hybrid microfluidic biochip integrated with aptamer-functionalized graphene oxide nano-biosensors for one-step multiplexed pathogen detection

A portable and integrated nucleic acid amplification microfluidic chip for identifying bacteria

A simple cassette as point-of-care diagnostic device for naked-eye colorimetric bacteria detection

Paper machine" for molecular diagnostics

Point-of-care and visual detection of p. Aeruginosa and its toxin genes by multiple lamp and lateral flow nucleic acid biosensor

Multiplex reverse transcription loop-mediated isothermal amplification combined with nanoparticle-based lateral flow biosensor for the diagnosis of covid-19

Battery operated preconcentrationassisted lateral flow assay

Two orders of magnitude improvement in detection limit of lateral flow assays using lsotachophoresis

Simultaneous concentration and detection of biomarkers on paper

Improved sensitivity of lateral flow assay using paper-based sample concentration technique

Enhancing the lateral-flow immunoassay for viral detection using an aqueous two-phase micellar system

Enhancing the lateral-flow immunoassay for detection of proteins using an aqueous two-phase micellar system

Immunochromatographic strip for rapid detection of cronobacter in powdered infant formula in combination with silica-coated magnetic nanoparticles separation and 16s rrna probe

Lateral flow biosensor for DNA extraction-free detection of salmonella based on aptamer mediated strand displacement

Detection of bacillus anthracis spores by super-paramagnetic lateral-flow immunoassays based on "road closure

Lateral flow biosensor for multiplex detection of nitrofuran metabolites based on functionalized magnetic beads

Fluorescence quenching-based signal amplification on immunochromatography test strips for dual-mode sensing of two biomarkers of breast cancer

Lateral flow assays: principles, designs and labels. Trac-trend

Development of nanocolloidal gold based immunochromatographic assay for rapid detection of transgenic vegetative insecticidal protein in genetically modified crops

Immunochromatographic colloidal carbon-based assay for detection of methiocarb in surface water

Quantitative immunochromatographic strip biosensor for the detection of carcinoembryonic antigen tumor biomarker in human plasma

Improving sensitivity of gold nanoparticlebased lateral flow assays by using wax-printed pillars as delay barriers of microfluidics

Polydimethylsiloxane-paper hybrid lateral flow assay for highly sensitive point-of-care nucleic acid testing

Lateral flow assay based on paper-hydrogel hybrid material for sensitive point-ofcare detection of dengue virus

Multi-responsive janus liquid marbles: The effect of temperature and acidic/basic vapors

Enhanced lateral flow immunoassay using gold nanoparticles loaded with enzymes

Sensitive biomolecule detection in lateral flow assay with a portable temperature-humidity control device

Improved sensitivity and limit-of-detection of lateral flow devices using spatial constrictions of the flow-path

Application of gold nanoparticles produced by laser ablation for immunochromatographic assay labeling

Reverse fluorescence enhancement and colorimetric bimodal signal readout immunochromatography test strip for ultrasensitive large-scale screening and postoperative monitoring

Development of immunochromatographic colloidal gold test strip for rapid detection of haemophilus influenzae in clinical specimens

A dual gold nanoparticle conjugate-based lateral flow assay (lfa) method for the analysis of troponin i

Lateral flow (immuno) assay: its strengths, weaknesses, opportunities and threats. A literature survey

Gold nanoparticles based lateral flow immunoassay with largely amplified sensitivity for rapid melamine screening

One-step signal amplified lateral flow strip biosensor for ultrasensitive and on-site detection of bisphenol a (bpa) in aqueous samples

Ultrasensitive detection of mercury with a novel one-step signal amplified lateral flow strip based on gold nanoparticle-labeled ssdna recognition and enhancement probes

Hierarchical nanogold labels to improve the sensitivity of lateral flow immunoassay

Enhanced sensitivity of lateral flow immunoassays by using water-soluble nanofibers and silverenhancement reactions

Increased sensitivity of lateral flow immunoassay for ochratoxin a through silver enhancement

Rapid pathogen detection by lateral-flow immunochromatographic assay with gold nanoparticle-assisted enzyme signal amplification

Dramatic enhancement of the detection limits of bioassays via ultrafast deposition of polydopamine

Development of the sensitive lateral flow immunoassay with silver enhancement for the detection of ralstonia solanacearum in potato tubers

Silver and gold enhancement methods for lateral flow immunoassays

A colloidal gold probe-based silver enhancement immunochromatographic assay for the rapid detection of abrin-a

A lateral flow immunoassay for the rapid detection of ochratoxin a in wine and grape must

Double-codified gold nanolabels for enhanced immunoanalysis

Ultrasensitive electrochemical immunosensor for clinical immunoassay using thioninedoped magnetic gold nanospheres as labels and horseradish peroxidase as enhancer

Dual signal amplification of glucose oxidase-functionalized nanocomposites as a trace label for ultrasensitive simultaneous multiplexed electrochemical detection of tumor markers

Multi-functional crosslinked au nanoaggregates for the amplified optical DNA detection

Ultrasensitive nucleic acid biosensor based on enzyme-gold nanoparticle dual label and lateral flow strip biosensor

Disposable nucleic acid biosensors based on gold nanoparticle probes and lateral flow strip

Dual dye-loaded au@ag coupled to a lateral flow immunoassay for the accurate and sensitive detection of mycoplasma pneumoniae infection

Au@ag serrs tags coupled to a lateral flow immunoassay for the sensitive detection of pneumolysin

A specific and ultrasensitive chemiluminescent sandwich ELISA test for the detection and quantitation of pneumolysin

Kinetically controlled seeded growth synthesis of citrate-stabilized gold nanoparticles of up to 200 nm: Size focusing versus ostwald ripening

Highly sensitive detection of high-risk bacterial pathogens using sers-based lateral flow assay strips

Quantitative and ultrasensitive detection of multiplex cardiac biomarkers in lateral flow assay with core-shell sers nanotags

Development of lateral flow immunoassay system based on superparamagnetic nanobeads as labels for rapid quantitative detection of cardiac troponin i

Simultaneous detection of high-sensitivity cardiac troponin i and myoglobin by modified sandwich lateral flow immunoassay: proof of principle

Quantitative detection of multiplex cardiac biomarkers with encoded sers nanotags on a single t line in lateral flow assay

Application of a sers-based lateral flow immunoassay strip for the rapid and sensitive detection of staphylococcal enterotoxin b

Paper-based surface-enhanced raman scattering lateral flow strip for detection of neuron-specific enolase in blood plasma

Rapid analytical methods for on-site triage for traumatic brain injury

A high-sensitivity thermal analysis immunochromatographic sensor based on au nanoparticle-enhanced twodimensional black phosphorus photothermal-sensing materials

Significantly improved analytical sensitivity of lateral flow immunoassays by using thermal contrast

Highly sensitive paper-based immunoassay using photothermal laser speckle imaging

Thermal contrast amplification reader yielding 8-fold analytical improvement for disease detection with lateral flow assays

Nanomaterial-enhanced paper-based biosensors. Trac-trend

Recent advances in high-sensitivity detection methods for paper-based lateral-flow assay

Nanoparticle-based photoacoustic analysis for highly sensitive lateral flow assays

Evaluation of nucleic acid sequence based amplification using fluorescence resonance energy transfer (fret-nasba) in quantitative detection of aspergillus 18s rrna

Magnetic field assisted preconcentration of biomolecules for lateral flow assaying

Magnetic focus lateral flow sensor for detection of cervical cancer biomarkers

A sersbased lateral flow assay biosensor for highly sensitive detection of hiv-1 DNA

Quantitative analysis of thyroid-stimulating hormone (tsh) using sers-based lateral flow immunoassay

The authors declare no competing interests.