key: cord-303978-z3888e3g authors: Hong, Ka Lok; Sooter, Letha J. title: Single-Stranded DNA Aptamers against Pathogens and Toxins: Identification and Biosensing Applications date: 2015-06-23 journal: Biomed Res Int DOI: 10.1155/2015/419318 sha: doc_id: 303978 cord_uid: z3888e3g Molecular recognition elements (MREs) can be short sequences of single-stranded DNA, RNA, small peptides, or antibody fragments. They can bind to user-defined targets with high affinity and specificity. There has been an increasing interest in the identification and application of nucleic acid molecular recognition elements, commonly known as aptamers, since they were first described in 1990 by the Gold and Szostak laboratories. A large number of target specific nucleic acids MREs and their applications are currently in the literature. This review first describes the general methodologies used in identifying single-stranded DNA (ssDNA) aptamers. It then summarizes advancements in the identification and biosensing application of ssDNA aptamers specific for bacteria, viruses, their associated molecules, and selected chemical toxins. Lastly, an overview of the basic principles of ssDNA aptamer-based biosensors is discussed. Target detection in diagnostics and sensors relies on successful molecular recognitions. Traditionally, antibodies have been used in biosening applications due to their target specificities and affinities. However, the inherent properties of proteins give rise to many shortcomings of antibodies. In 1990, the Gold Laboratory first described a process, termed Systematic Evolution of Ligands by Exponential Enrichment (SELEX) [1] , which identifies one or few molecular recognition elements (MREs) with high affinity and specificity toward their intended targets. MREs can be short sequences of single-stranded DNA, RNA, small peptides, or antibody fragments. All types of MREs are capable of binding to user-defined targets with high affinity and specificity, and these targets include proteins, small molecules, viruses, whole bacteria cells, and mammalian cells [2] . In order to identify nucleic acid MREs, the SELEX process generally begins from a very large random library consisting of 10 13 to 10 15 different molecules. An individual nucleic acid MRE is composed of two constant regions for primer attachment during polymerase chain reaction (PCR) amplification flanked by 20-80 bases of random region [3] . The target of interest is first incubated with the library under specific ionic and temperature conditions. Library molecules that bind to the target are retained and amplified by PCR, while nonbinding library molecules are discarded. Negative or counter selections are often performed to increase the specificity of the library or direct the enrichment process away from binding to negative targets. Negative targets are often chosen for their structural similarities or the likelihood to coexist in the native environment with the target of interest. In this case, library molecules that bind to negative targets are discarded and those that do not bind are retained and amplified and thus completing one round of in vitro selection ( Figure 1 ). It is expected that the library is enriched enough after approximately 12 rounds of SELEX. One or few nucleic acid MREs with high specificity and affinity toward their targets can be identified. Both DNA and RNA MREs can conform into three dimensional structures, which include stem-loop, bulges, and/or hairpin regions and give rise to binding pockets for their respective targets [4] . There are reports suggesting that RNA MREs generally have a higher affinity for their target than their DNA counterparts [5] . However, unmodified RNA molecules are more susceptible to nuclease degradations than DNA. Modification on the 2 hydroxyl of RNA molecules can increase their stabilities but may have negative impact on their binding affinities [6, 7] . It is also more difficult to amplify RNA MREs during selection, as reverse transcription to DNA must be performed prior to PCR. For these given reasons, there is a bigger hurdle to successfully identify and apply RNA MREs in molecular detection, and thus this review has chosen to focus on the discussion of ssDNA MREs in biosening applications. Single-stranded DNA MREs have high affinity and specificity toward their targets that is comparable to antibodies. In addition, ssDNA MREs have several advantages over antibodies. Firstly, ssDNA MREs are more thermostable and can be reversibly denatured. This reusability is particularly desired for molecular sensing applications. Secondly, ssDNA MREs can be identified for targets that are nonimmunogenic or toxic to cells, as the SELEX process can be performed completely in vitro and independent of living systems. Lastly, identified ssDNA MREs with known sequences can be chemically synthesized at low cost and without batch to batch variations [8] . Different modifications such as thiol or amino functional groups can also be easily incorporated onto the 3 and/or 5 ends of oligonucleotides during synthesis and utilized for immobilization on solid platforms. Similarly, labeling molecules such as biotin or FITC can also be covalently attached and serve as reporters in sensing applications. The attractive features of ssDNA MREs allow researchers to investigate the translational application of biosensors. This review focuses on the recent advancements in the identification and biosensing application of ssDNA MREs specific for bacteria, viruses, their associated biomolecules, virulence factors, and selected biological and chemical toxins. Detection of these targets has been shown to be important in medical diagnosis, food safety, and environmental monitoring. Additionally, major principles in MRE based biosensors are briefly discussed. Recognition Elements 2.1. General Methodology of SELEX. The general process of in vitro selection of ssDNA MREs starts from design and chemical synthesis of ssDNA library. ssDNA library consists of two predetermined constant regions for primer attachment during PCR amplification flanking a random region. This random region gives raise to the diversity of the library, which can be designated by 4 , where is the number of bases in the random region. Longer random regions not only may result in increased library diversity, but also may risk inhibition of PCR amplification due to secondary structure formation. Therefore, the overall libraries lengths are usually designed to be less than 150 bases in total length, including a random region of 20 to 80 bases, and are chemically synthesized using phosphoramidite chemistry [3] . The SELEX process begins by incubating up to 10 15 different ssDNA molecules with the target of interest. One of the key steps in the SELEX process is the separation of bound MREs from unbound MREs. The separation process is often achieved by target immobilization. Immobilization options include nitrocellulose membranes that can be used to adsorb protein targets [9] and histidine tags on recombinant proteins that can be with a metal affinity chromatography column [10] . However, ssDNA molecules may nonspecifically adsorb to immobilizing substrates. A round of negative selection is typically performed prior to the start of the first round of positive selection to reduce the nonspecific adsorption between the library and immobilizing substrates. Magnetic beads have also been used to immobilize a wide range of targets [11] [12] [13] [14] . The terminal primary amine or a surface lysine on a protein can be used to conjugate onto carboxylic acid coated magnetic beads via EDC/NHS reactions. Small molecule targets or target analogs with available functional groups can also be biotinylated and immobilized on streptavidin coated magnetic beads based on the strong affinity between biotin and streptavidin [14, 15] . Magnets can then be used for the separation of bound and unbound molecules. However, this technique runs the risk of selecting MREs bound to magnetic beads and/or streptavidin. Sooter and coworkers successfully showed that competitive elution with free target can effectively isolate ssDNA MREs specific for the target of interest and not for the immobilizing substrates or analog molecules [14] [15] [16] . Amplification of the ssDNA library is also crucial to the success of the in vitro selection process. PCR conditions have to be determined and optimized before the selection process. After the retrieval of target bound ssDNA molecules for each round of selection, a small-scale PCR can be carried out to determine the cycles of PCR needed to successfully amplify the library. Large-scale PCR can subsequently be performed based on the determined number of reaction, and thus decreasing the chance of overamplification and the generation of undesired PCR amplicons. It is necessary to obtain ssDNA from double-stranded PCR product prior to the subsequent rounds of selection. Several techniques have been shown to effectively isolate the single-stranded binding element from double-stranded DNA, such as asymmetric PCR, biotin-streptavidin separation, lambda exonuclease digestions, and size separation on denaturing urea polyacrylamide gel electrophoresis. Asymmetric PCR uses a different ratio of forward and reverse primer in the reaction mixture to generate both dsDNA and ssDNA allowing the two types of DNA molecules to be visualized and separated using agarose gel electrophoresis. The ssDNA is then excised and purified [17] . Biotin-streptavidin separation uses a biotin-tagged primer in the PCR amplification process to generate biotinylated dsDNA. The dsDNA can then be captured by streptavidin coated beads. The unbound strand of DNA can be retrieved using sodium hydroxide [18] . Lambda exonuclease can selectively digest a phosphorylated strand of the dsDNA in 5 to 3 direction. PCR reactions carried out with a phosphorylated reverse primer can be selectively digested by lambda exonuclease, leaving only the forward strand [19] . Modified primers can be used to create size differences between the forward and reverse strands and be detected by using urea denaturing PAGE, and subsequently ssDNA can be excised and purified [20] . The general process of SELEX has been modified over the past two decades. These modifications mostly focus on increasing the efficiency in separating bound and unbound MREs, increasing specificity of the selected MREs, eliminating the need for immobilizing target molecules, selecting against live whole cells, and decreasing the overall labor intensiveness of the SELEX process. Selected modified SELEX methods pertinent to this review are briefly discussed. Negative or counter selection is incorporated into the normal SELEX process by introducing negative targets that have structural similarity to the target of interest or are likely to coexist in the target's environment. This modification is to increase the overall specificity of the library during selection and thus identify MREs that are highly specific to the target. Williams and coworkers identified ssDNA MRE target for herbicide, atrazine, with 2.1-fold higher binding affinity to atrazine than to a closely related herbicide, simazine, by introducing multiple negative selection rounds and increasing stringency during the selection [14] . This stringent negative selection scheme was utilized to obtain two other ssDNA MREs that bind to their respective targets with high affinity and specificity [15, 16] . Capillary electrophoresis can separate molecules based upon their charges. Target bound and unbound DNA molecules migrate at different rates due to differences in their overall charges, and therefore different species can be separated and collected at different time points. Mendonsa and Bowser were the first to use capillary electrophoresis to identify a ssDNA MRE specific for human IgE. Due to its high efficiency in separating different molecules, MREs can generally be identified in 4 to 6 rounds of capillary electrophoresis based SELEX (CE-SELEX) [21] . CE-SELEX can also select MREs bound to free targets in solution and without the need of immobilization. A variant of CE-SELEX utilizes nonequilibrium capillary electrophoresis of equilibrium mixtures (NECEEM) to achieve separation (Non-SELEX) has also been developed. In Non-SELEX, repetitive rounds of selection are performed without PCR amplification. Berezovski and coworkers were the first to use Non-SELEX to identify a high affinity MRE ( : 0.3 nM) specific for hRas protein [22] . Park and coworkers developed an immobilization-free SELEX method based on -stacking interaction between DNA and graphene oxide (GO-SELEX). In GO-SELEX, ssDNA library is adsorbed on graphene oxide and then incubated with the target. In the presence of the target, a portion of the ssDNA library is released from graphene oxide and bind preferentially to the target, while unbound ssDNA remains adsorbed and can be separated by centrifugation [23] . This method was used to isolate ssDNA MREs specific for bovine viral diarrhea virus type 1 [24] . A highthroughput modification of GO-SELEX was also developed by Nguyen and coworkers to identify flexible ssDNA MREs that are specific for multiple pesticides with affinities in the nanomolar range [25] . Nutiu and Li developed a different target immobilization-free SELEX method using a ssDNA library containing a 15-base constant region, sandwiched by two random regions, and finally encompassed by two constant primer hybridization regions at both 3 and 5 ends [26] . The 15 bases constant region can hybridize with biotinylated complementary strand and can be captured by streptavidin coated beads. Binding of the ssDNA library to target molecules induces conformational changes, thus releasing the binding-strand from the complementary strand. This method has been adapted to screen for ssDNA MREs specific for multiple pesticides [27, 28] . FluMag-SELEX was developed by Stoltenburg and coworkers by immobilizing targets on magnetic beads, using fluorescently labeled forward primer during PCR amplification [29] . Magnetic separation of bound and unbound MREs is performed similarly to traditional magnetic bead based SELEX. However, the overall binding capacity of the library can be monitored precisely with the presence of fluorescence tag. The selection process can then be terminated when the overall library binding affinity toward the target reaches a plateau. A similar technique has been incorporated in single microbead SELEX described by Tok and Fischer. In their work, only 2 cycles of SELEX were performed to identify multiple ssDNA MREs specific for botulinum neurotoxin with low micro-to nanomolar values [30] . The usage of fluorescence tag in the library is further investigated by Lauridsen and coworkers by performing a one-step selection against alpha-bungarotoxin [31] . Microfluidic chips are also being investigated to facilitate the SELEX process (M-SELEX). Microfluidic chips are capable of manipulating a very small amount of immobilized target on magnetic beads, thus achieving a more efficient separation of bound MREs [32] . Qian and coworkers were able to identify ssDNA MREs specific for Botulinum neurotoxin type A with low nanomolar binding affinity after only one round of selection [32, 33] . Recently, MREs with nanomolar binding affinity specific for whole influenza A/H1N1 virus were selected using M-SELEX [34] . Complex targets such as live mammalian and bacteria whole cells have become popular targets for selection. These types of selection are called cell-SELEX or whole cell-SELEX. Early works mostly focused on identifying MREs specific for tumor cells [35] [36] [37] [38] . The general methodology of cell-SELEX is very similar to traditional SELEX, but fluorescence-activated cell sorting (FACS) can be utilized to achieve a very high level of separation of MRE bound and unbound cell targets. Multiple pathogenic bacteria genera, such as Salmonella, Pseudomonas, Staphylococcus, Listeria, and Escherichia have been chosen as a selection target. The selection and biosening application of ssDNA MREs targeting bacteria, viruses, and associated biomolecules are discussed in the following section. Singlestranded DNA MREs targeting bacteria can be classified into two general categories, (1) targeting whole cells with known or unknown molecular targets and (2) targeting predefined bacteria cell surface targets or bacteria spores (Table 1) . Multiple virulent strains of the gram-negative bacteria, Escherichia coli, have been chosen as targets for the selection of specific ssDNA MREs due to their enterotoxigenic effects and the potential of contaminating food and water [39] . Peng et al. enriched ssDNA MRE library specific for E. coli K88 whole bacteria [40] . They also developed a sandwich detection system, in which biotinylated antibodies targeting the K88 strain were immobilized on magnetic beads as the capturing element and the 5 FITC labeled ssDNA library from round 13 selection served as the reporter in a fluorescent assay. A lower limit of detection (LOD) of 1100 CFU/mL was achieved in pure culture. Artificial contaminated fecal samples were also tested with a LOD of 2200 CFU per gram. However, no individual ssDNA MRE was able to achieve the same degree of binding affinity as the whole library and ssDNA MRE with high affinity and specificity against K88 fimbriae protein was selected after 11 rounds [41] . A fluorescence binding assay was used to obtain the affinity of the selected MRE candidates. The reported equilibrium dissociation constant ( ) for the best candidate MRE was 25±4 nM. Kim et al. performed 10 rounds of selection against a fecal strain of E. coli along with multiple negative selections against other species of bacteria. They identified four candidate sequences with high affinity for the target strain. All four candidates were highly selective against negative target bacteria. However, they all showed cross-binding activity with other strains of E. coli. This suggested that the selected candidates potentially bound to common antigens expressed in multiple strains of E. coli [42] . Savory et al. identified ssDNA MRE with high specificity and affinity ( = 110 nM) for an uropathogenic strain of E. coli. Quantitative PCR was used to monitor the SELEX process in order to minimize the number of rounds of SELEX required. After 5 rounds of SELEX, a selected ssDNA MRE containing a guaninequadruplex sequence motif showed low cross-binding activities toward other strains of E. coli [43] . In addition to selecting whole E. coli bacteria as targets, outer membrane protein from E. coli 8739 (Crook's strain) and lipopolysaccharide from O111:B4 strains were also chosen as targets for selection. A fluorescence resonance energy transfer (FRET) assay was developed to detect E. coli 8379 with a LOD of 30 CFU/mL [44] . The ssDNA MRE targeting lipopolysaccharide showed antibacterial effects on both O111:B4 and K12 strains [45] . However, values were not reported in either study. Several ssDNA MREs have been selected against species of foodborne bacteria including Salmonella, Listeria, and Vibrio. Dwivedi et al. identified ssDNA MRE specific for whole cell Salmonella enterica serovar Typhimurium with a reported of 1.73 ± 0.54 M after eight rounds of selection [46] . Two rounds of negative selection against a mixture of nontarget bacteria were also performed to enhance the selectivity of the library. A detection application was developed using immobilized biotinylated MREs on streptavidin coated magnetic beads as the capturing elements and was coupled with quantitative PCR. The reported LOD of this assay was between 100 to 1000 CFU in a 290 L sample volume. Duan et al. performed a similar selection on the same organism with nine rounds of target selection and two rounds of negative selection against mixtures of nontarget bacteria [47] . The best candidate ssDNA MRE had a value of 6.33 ± 0.58 nM and high specificity based upon flow cytometry analysis. A fluorescence bioassay achieved a LOD of 25 CFU/mL. Another similar study performed by Moon et al. showed relatively high affinities and specificities of selected candidate sequences after ten rounds of target and six rounds of negative selections. However, no values were reported in the study [48] . Outer membrane proteins of Salmonella enterica serovar Typhimurium were chosen as selection target by Joshi et al. In that study seven rounds of selection were performed with three rounds of negative selection against E. coli outer membrane proteins and lipopolysaccharides. A magnetic bead based quantitative real-time PCR assay was developed using immobilized ssDNA MRE as the capturing element. Food and environmental samples were tested to demonstrate the translational usage of the assay. A LOD of less than 10 CFU per gram of artificially contaminated bovine feces was reported. Additionally, 10 to 100 of CFU were detected in 9 mL of artificially contaminated whole carcass chicken rinse sample solution in a pull-down assay [49] . Two recent studies identified ssDNA MREs specific for two serovars of Salmonella, Typhimurium, and Enteritidis [50, 51] . Park et al. truncated out the random region (29 to 30 mer) of selected candidates and identified three ssDNA MREs with values in micromolar range toward their respective serovars after ten rounds of mixed target and counter target selection. Poly-D-lysine was conjugated to the selected MREs and achieved an approximately 20-to 100-fold enhancement in their binding affinities [51] . Kolovskaya et al. also performed a similar selection on the two serovars of Salmonella [50] . After twelve rounds of selection, two ssDNA MREs with values range in nanomolar were identified (Enteritidis: = 7nM; Typhimurium: = 25nM). to identify an MRE with high affinity ( = 47 ± 3 nM) and specificity toward Paratyphi A. LOD of 1000 CFU/mL was achieved using chemiluminescence assay based on selfassembled single-walled carbon nanotubes and DNAzymeslabeled MRE as detection elements [52] . MRE with high specificity toward Salmonella O8 was identified by Liu et al. after eleven rounds of positive and two rounds of negative selection. The selected MRE had a reported of 32.04 nM. A preliminary fluorescent in situ labeling assay was developed with the MRE. However, no LOD was reported [53] . Consumption of uncooked or undercooked seafood contaminated by Vibrio bacteria can lead to food poisoning [54] . Two different species, Vibrio parahaemolyticus and Vibrio alginolyticus were chosen as selection targets. Nine rounds of cell-SELEX using flow cytometry were carried out to identify ssDNA MRE with high affinity and specificity for Vibrio parahaemolyticus ( = 16.88 ± 1.92 nM) [55, 56] . Tang et al. performed 15 rounds of cell-SELEX on inactivated Vibrio alginolyticus. Negative selection was performed every third positive target round to improve the library specificity. The study did not characterize affinities and specificities of candidate ssDNA MREs from the last round of selection. Instead, the whole library was characterized to have a value of 27.5 ± 9.2 nM and was highly specific toward the target. The enriched library was able to detect 100 CFU/mL of the bacteria based on a PCR amplification assay [56] . Listeria monocytogenes is a foodborne gram-positive bacterium that can cause serious illnesses and even death. FDA and European Union both have zero tolerance of L. monocytogenes in ready-to-eat food products. Suh et al. conducted two studies to identify ssDNA MREs specific for L. monocytogenes [57, 58] . In their earlier study, MRE with a micromolar value was identified after six rounds of positive and two rounds of negative selections. The MRE showed low cross-binding to negative target bacteria but had similar binding affinity for other members of the Listeria genus. A magnetic bead based capture assay coupled with quantitative PCR was developed. The assay was able to detect less than 60 CFU in 500 L of binding buffer containing a mixture of non-Listeria bacteria [58] . In their later study, the affinities of selected candidate MREs were improved with reported values of in the nanomolar range and were specific for the target bacteria at different growth phases [57] . Duan et al. performed similar whole cell in vitro selection on L. monocytogenes. The selected MRE had high affinity ( = 48.74 ± 3.11 nM) and was highly specific toward the target. A fluorescent cross-binding assay showed significantly lower binding activities toward negative bacteria targets and other bacteria species in the Listeria genus. A sandwich fluorescent bioassay was developed and demonstrated a LOD of 75 CFU/mL [59] . Most recently, Liu et al. performed eight rounds of selection to identify ssDNA MREs specific for L. monocytogenes. The best candidate MRE reported to have a value of 60.01 nM and had high specificity. A fluorescent based detection assay was developed to enable the observation of binding between the MRE and target bacteria using fluorescent microscope, but the LOD was not reported [60] . Ohk et al. selected ssDNA MRE specific for internalin A of L. monocytogenes. Internalin A is a major invasion protein expressed on the cell surface of L. monocytogenes [61] . A highly specific sandwich style fiber optic biosensor was developed by using the selected MRE and antibody. A reported LOD of 1000 CFU/mL was achieved. The sensor also successfully detected the bacteria in artificially contaminated ready-to-eat meat products. However, affinity data was not reported in the study [62] . Shigella dysenteriae is a gram-negative bacterium that causes severe epidemic diarrhea in many countries [63] . Duan et al. used cell-SELEX methodology to identify ssDNA MRE specific for S. dysenteriae [47, 55, 59, 64] . The best candidate MRE had a reported value of 23.47 ± 2.48 nM and low cross-binding activities toward negative bacteria targets. A fluorescent based detection assay demonstrated a LOD of 50 CFU/mL [64] . Campylobacter jejuni is a highly infectious gram-negative bacterium that is one of the leading causes of acute diarrheal sickness worldwide [65] . Bruno et al. performed an in vitro selection by extracting surface proteins of C. jejuni and immobilizing them on magnetic beads. No values of were reported in the study. However, a fluorescent assay based on magnetic beads and quantum dot was developed to detect the bacteria in different food matrices. The assay showed low cross-binding activities with other species of bacteria but was not able to distinguish between bacteria in the Campylobacter genus. The reported LODs were 2.5 CFU and 10 to 250 CFU in buffer solution and in different food matrices, respectively [66] . CE-SELEX was employed by Stratis-Cullum et al. to identify MREs specific for C. jejuni. Killed bacteria were used as target in their study. A qualitative capillary electrophoresis immunoassay was developed with a LOD of 6.3 × 10 6 cells/mL [67] . Dwivedi et al. performed cell-SELEX on live C. jejuni. A total of ten positive rounds and two negative rounds were carried out to identify ssDNA MREs with high affinity and specificity toward the target bacteria ( = 292.8 ± 53.1 nM) [68] . Bacteria that are associated with common infectious diseases, such as Streptococcus, Staphylococcus, and Pseudomonas, are also popular targets for in vitro selection. Identification of MREs targeting infectious bacteria could be potentially used to facilitate diagnosis and thus decreasing the time between culture collections to specific antibiotic treatment. Savory et al. performed cell-SELEX on Proteus mirabilis, a common cause of catheter associated urinary tract infections in long-term catheterized patients. MREs specific for two different strains of P. mirabilis with low nanomolar range values were identified after 6 rounds of in vitro selection. Additionally, an in silico maturation (ISM) process was performed to increase the specificity of the selected MRE. It was reported that a 36% higher specificity was achieved after the ISM process [69] . This same technique was again employed to select MRE specific for Streptococcus mutants, the main causative pathogen of dental caries. The affinity of the identified MRE was improved up to 16-fold and the specificity was increased 12-fold after ISM. A gold colloids based colorimetric flow-through assay was developed and demonstrated the detection S. mutants in the range of 10 5 -10 8 CFU/mL [70] . Streptococcus pyogenes (Group A Streptococcus) is often the causative pathogen of a wide range of infectious diseases, such as streptococcal pharyngitis and streptococcal toxic shock syndromes [71] . Different M-types of live S. pyogenes were chosen for selection by Hamula et al. After 20 rounds of target selection, the two best candidate MREs yielded high affinity for Group A Streptococcus ( = 9-10 nM). It was noteworthy that the candidate MREs showed good specificities, even though the authors did not perform any negative selections [72] . Staphylococcus aureus is a gram-positive bacteria associated with numerous of infections in human [73] . Cao et al. selected a panel of ssDNA MREs specific for S. aureus after several rounds of target and counter target selection. The reported values of individual candidate MREs were in the nanomolar range with high specificity. The study showed that the combination of the panel of MREs yielded a better sensitivity in recognizing S. aureus than any single MRE [74] . Change et al. selected two ssDNA MREs with high affinities and specific toward S. aureus ( = 35 and 129 nM). The reported values of improved to 3.03 and 9.9 nM, respectively, after thiol-modification and conjugation to gold nanoparticles. Subsequently, the MRE conjugated gold nanoparticles were utilized to capture target bacteria and a resonance light-scattering signal demonstrated the detection of single S. aureus cell in 1.5 hours [75] . Pseudomonas aeruginosa is a gram-negative bacterium that is commonly associated with nosocomial infections [76, 77] . Wang et al. performed 15 rounds of positive and 2 rounds of counter target selection to identify ssDNA MREs with values in the low nanomolar range. The selected MRE showed negligible binding to counter bacteria cell targets. A fluorescence in situ hybridization (FISH) assay was developed to show rapid detection of P. aeruginosa. However, the detection ranges were not reported [78] . Mycobacterium tuberculosis is the etiologic pathogen for tuberculosis [79] . Chen et al. reported ssDNA MRE with an apparent association constant ( ) between 10 5 -10 6 M and was highly specific. The authors reported an antibacterial effect of the selected MRE with both in vitro and in vivo models [80] . Highly infectious bacteria and bacteria spores have been considered as potential biological warfare agents, and it is important to detect these biological threats rapidly [81] . Bruno and Kiel 1999 performed an in vitro selection of ssDNA MREs targeting Bacillus anthracis spores, the causative agent of anthrax. Autoclaved anthrax spores were used in the selection. MRE-magnetic bead electrochemiluminescence sandwich assay was developed with a reported detection range of 10-10 6 spores [82] . Ikanovic et al. performed a selection of ssDNA MREs specific for Bacillus thuringiensis spores, a closely related species to B. anthracis. In this study, the methodology was adopted from Bruno and Kiel 1999. A fluorescent assay based on cadmium selenide quantum dots was developed with a reported detection limit at about 1000 CFU/mL [83] . Bruno and Carrillo 2012 revisited the selection of Bacillus spores. In this later study, anthrose sugar on anthrax spores was chosen as target for selection. MRE beacon based on fluorescent signals was developed and generated strong signal at spore concentrations greater than 30,000 spores/mL. The authors also compared the MRE sequences pattern to previous studies and identified similarities in sequences composed of T/G rich bases. It was also reported that MREs specific for whole spores did not generate fluorescent signals in the presence of anthrose sugar, suggesting that the selected spore specific MREs possibly bound to a different epitope and warranting further research [84] . Francisella tularensis is an encapsulated, gram-negative coccobacillus that is highly infectious. Reports show as few as 25 organisms in aerosol can cause diseases [85] . Vivekananda and Kiel performed ten rounds of selection on Francisella tularensis subspecies japonica bacterial antigen. A cocktail of 25 ssDNA MREs was reported to have high specificity toward the target bacteria. MRE modified enzyme linked immunosorbent assay was developed, and demonstrated binding to the target and other subspecies of F. tularensis but not to other species of bacteria and chicken lysozyme or chicken albumin. In addition, the assay was able to achieve better sensitivity then traditional ELISA using anti-tularemia antiserum and anti-tularemia polycolonal antibodies. The reported LOD is 1700 bacteria/mL [86] . Peptidoglycan is a macromolecule universally expressed on bacteria outer cell wall [87] . Ferreira et al. identified two ssDNA MREs with sub-to low micromolar values that can bind specifically to both gram-positive and gram-negative bacteria. Neither MRE bounded to human fibroblasts or Candida albicans and could potentially be used as generic detection elements for bacteria [88] . Lipopolysaccharide (LPS or endotoxin) is expressed in the outer membrane of gram-negative bacteria and can illicit strong immune response upon entering into mammalian cells. [89, 90] Kim et al. used nonequilibrium capillary electrophoresis of equilibrium mixtures (NECEEM) based non-SELEX to identify multiple ssDNA MREs with high affinities toward lipopolysaccharide in only three rounds of selection. Selected MREs also demonstrated very low cross-binding activities to bovine serum albumin and other intracellular molecules, such as DNA, RNA, glucose, and sucrose, in an electrochemical assay. This assay resulted in a target detection range of 0.01 to 1 ng/mL [91] . There is a wealth of literature describing ssDNA MREs targeting various virus life cycle regulator proteins with the purpose of therapeutic application. In contrast, there is a lesser amount of research on ssDNA MREs for virus biosensing application ( Table 2 ). For the focus of this review, those MREs with therapeutic applications are listed in the following table without further detail discussions (Table 3) . In recent years, there has been an increase in the interest in the application of ssDNA MREs for virus detection. [10] . GO-SELEX was utilized to identify ssDNA MREs specific for bovine viral diarrhea virus. After five rounds of positive and negative selections, three best candidate MREs had reported values of 4.08 × 10 4 , 4.22 × 10 4 , and 5.2 × 10 4 TCID 50 /mL, respectively, by SPR kinetics analysis. All candidate MREs showed very high specificity toward the target. A sandwich SPR detection assay was developed wherein a biotinylated MRE was immobilized on streptavidin coated gold chip as the capturing MRE, and a second different MRE with thiol modification was conjugated to gold nanoparticle as the reporting MRE. A LOD of 800 copies of virus/mL was reported with this assay [24] . Hepatitis C virus (HCV) envelope surface glycoprotein E2 was chosen as target for selection by Chen et al. E2 protein was expressed on a murine colon carcinoma cell line, CT26 cells, and used as a target for positive selection. The native CT26 cells were used as counter target. After 13 rounds of selection, the best candidate MRE showed high affinity and specificity toward E2-positive cells. An ELISA virus capture assay was developed by using biotinylated MRE as reporter and demonstrated the detection of HCV in clinical human serum samples. In addition, the MRE, termed ZE2 also displayed therapeutic effect by inhibiting E2 protein binding to CD81 and blocking HCV infection of human hepatocytes in vitro [100] . Dengue virus is a member of family Flaviviridae, genus flavivirus. It is a mosquito-borne RNA virus that can cause gangue fever, dengue hemorrhagic fever, and dengue shock syndrome [101] . Gandham (Table 4) . Staphylococcus aureus can secrete a group of thermostable enterotoxins that have been shown to contaminate food. Reports suggest that these toxins are a common cause of foodborne illnesses [104] . There are many types and subtypes of staphylococcus enterotoxins. Bruno and Kiel first selected ssDNA MREs that bind to enterotoxin B by using magnetic bead immobilized target. An electrochemiluminescence assay was developed to demonstrate a detection limit of less than 10 pg of enterotoxin B. However, no kinetic data or crossing-binding profiles were presented in the study [105] . DeGrasse recently identified ssDNA MRE specific for enterotoxin B after fourteen rounds of mixed target and negative targets selection. MRE based precipitation assay was used to analyze the selectivity of candidate MREs in cellfree culture supernatant from multiple strains of S. aureus. The high selectivity of candidate MREs was confirmed by capturing only the target toxin in the precipitation assay. However, no quantitative binding data was presented in the study [11] . Enterotoxin subtype C1 was chosen as a target for selection by Huang et al. After twelve rounds of selection, the best candidate MRE demonstrated high affinity for enterotoxin C1 ( = 65.14 ± 11.64 nM). Crossbinding experiments showed that the selected MRE had high specificity and low cross-binding activities on staphylococcus enterotoxin A, enterotoxin B, and other protein molecules. A graphene oxide based fluorescence detection assay was developed and achieved a reported LOD of 6 ng/mL in artificially contaminated buffer-diluted milk samples [106] . Bruno and Kiel 2002 selected ssDNA MRE against cholera toxin. An enzyme linked colorimetric assay showed a detection limit of less than 10 ng of cholera toxin and electrochemiluminescence assay shows a detection limit of less than 40 ng. However, affinity, crossing-binding data, and MRE sequences were not presented in the study [105] . Toxigenic strains of Clostridium difficile can produce toxins A and toxin B, which are the contributing factor of C. difficile induced diarrhea. Rapid diagnosis of the condition is crucial in facilitating patient recovery and disease control [107] . Some strains of C. difficile also secret a binary toxin that can inhibit actin polymerization [108] . Ochsner et al. selected several slow off-rate modified ssDNA MREs (SOMAmer) specific for toxins A, B, and binary toxin. Several DNA libraries with modifications, such as 5-benzylaminocarbonyl-dU (BndU), 5-naphthylmethylaminocarbonyl-dU (NapdU), 5-tryptaminocarbonyl-dU (TrpdU), 5-phenylethyl-1-aminocarbonyl (PEdU), 5-tyrosylaminocarbonyl-dU (TyrdU), or 5-(2-naphthylmethyl) aminocarbonyl (2NapdU) were used in selections. Truncated recombinant toxins were used as targets. Equilibrium dissociation constants of selected SOMAmers were in pico to nanomolar range. The affinities for native toxins were slightly lower but were remain in the low nanomolar range for majority of the candidate sequences. Pull-down capture, dot blots, and antibody sandwich assays were developed with a reported LOD of 300 pg/mL. Selected SOMAmers were able to detect all three toxins in cellfree culture supernatants of toxigenic C. difficile [109] . Ochsner et al. performed another in vitro selection on C. difficile binary toxin with sandwich SELEX. The advantage of sandwich SELEX is to select SOMAmer pairs that target different epitopes of the target protein. The reported values of selected SOMAmers ranged from 0.02 to 2.8 nM. A SOMAmer sandwich assay was developed with a reported LOD in the low picomolar range. The authors claimed that these studies showed the high potential for the development of sensitive and specific diagnostic kits [110] . Hong et al. performed twelve rounds of positive in vitro selection against C. difficile toxin B and eleven rounds of negative selection. SPR binding study determined the selected ssDNA MRE had a value of 47.3 ± 13.7 nM. Fluorescence plate based cross-binding assay showed the selection ssDNA MRE was two to five times more selective on toxin B than negative targets. A proof-of-concept modified ELISA using ssDNA as the toxin capturing element was developed and able to detect toxin B at 50 nM concentration in human fecal matter [111] . Tuberculosis (TB) remains to be a challenging disease in developing countries. Recent discovery of multidrug resistant strains of Mycobacterium tuberculosis has further increased public concerns, however, current diagnostic techniques for TB are either time-consuming or insensitive [112] [113] [114] . Rotherham et al. performed a selection on CFP-10.ESAT6 heterodimer, a specific biomarker for TB infections. After six rounds of selection, SPR binding studies showed that candidate ssDNA MREs had affinities in the nanomolar range. One of the candidate MRE was tested in an enzyme linked oligonucleotide assay (ELONA). The authors reported that the assay had 100% sensitivity and 68.75% specificity in clinical sputum samples using Youden's index. However, the time needed for assay completion and crossing-binding activities to other antigens were major limitations of the assay [9] . Tang et al. performed a selection on the same CFP-10.ESAT6 heterodimer. After seventeen rounds of selection, values of candidate MREs were in the low nanomolar range. Two ssDNA MREs (CE24, CE15) were used in an ELONA assay. The reported sensitivity and specificity of CE24 MRE based ELONA were 100% and 94.1%, respectively. CE15 MRE based ELONA had a lower sensitivity of 89.6%, but the specificity was the same. Assays were tested both pulmonary and extrapulmonary with serum samples from TB patients [115] . MPT64 is a secreted protein of M. tuberculosis and can be used as biomarker for active TB infections [116] . Qin et al. performed twelve rounds of selection on MPT64. Affinities of truncated candidate ssDNA MREs, containing only a 35-base central random region, were qualitatively observed using streptavidin-horse radish peroxidase (HRP) binding to protein-bound biotin-tagged MREs. A colorimetric sandwich assay using two different MREs was developed to detect the presence of MPT64 in culture filtrates. The sandwich assay achieved sensitivity and specificity of 86.3% and 88.5%, respectively [117] . Protective antigen (PA) is a secreted virulence factor of Bacillus anthracis that binds to anthrax toxin receptors on mammalian cells and subsequently causes cell dysfunction and death [118] . Cella et al. utilized CE-SELEX to identify ssDNA MRE targeting PA with high affinity and specificity. After six rounds of CE-SELEX, the best candidate had Alpha toxin Filter --- [155] a reported of 112 nM. An electrochemical biosensor was developed by immobilizing 5 amino modified MRE on 1-pyrenebutanoic acid succinimidyl ester (PASE) modified single wall carbon nanotubes (SWNT). The sensor showed low cross-binding activity toward human and bovine serum albumin at 100 nM concentration. The sensor surface could be regenerated using 1 L of 6 M guanidine hydrochloride for 15 minutes followed by a wash with 10 mM phosphate buffer. A reported LOD of 1 nM was achieved [119] . Choi et al. performed an in vitro selection on PA. After eight rounds of selection, four candidate sequences had high affinities for PA ( in low nanomolar range), and two of the four candidates had low cross-binding activities toward bovine serum albumin and bovine serum [120] . Botulinum neurotoxins (BoNT) are produced by Clostridium botulinum. In addition to its medical uses, it can also cause serious foodborne illness and may potentially be used as a biological weapon [121] . Tok and Fischer used a novel single microbead SELEX to perform selection of ssDNA MREs specific to aldehyde-inactivated BoNT type A toxin (BoNT/A-toxoid) and BoNT type A heavy chain peptide (BoNT/A Hc-peptiod). Targets were immobilized onto Ni-NTA agarose or amine-functionalized polystyrene TentaGel beads. A single target-immobilized microbead was incubated with the ssDNA library and retrieved for PCR amplification of bound ssDNA molecules. After only two rounds of selection, five candidate sequences specific for BoNT/A Hc-peptiod had values ranging from 1.09 M to 4.20 M. Three candidate sequences specific for BoNT/Atoxoid had values ranging from 3 nM to 51 nM. The authors reported that all MREs specific to BoNT/A Hc-peptoid were able to competitively inhibit the binding between the toxin peptide and anti-BoNT antibody and potentially be used as a therapeutic agent [30] . Lou et al. utilized a novel microfluidic device to facilitate the partitioning of a small volume of target coated magnetic beads (M-SELEX). The library achieved a very high overall affinity ( = 33 ± 8 nM) against BoNT/A light chain after only one round of selection. Four candidate sequences had a range of values between 34 and 86 nM. The authors claimed that their M-SELEX could be readily adapted to any bead immobilized targets or whole cell target [33] . Bruno et al. immobilized BoNT/A light chain on magnetic beads and performed 10 rounds of selection. The best candidate MRE was fluorescently tagged and used as a reporter for target detection. The reported LOD of 1 ng/mL was achieved in buffer. However, the MRE reporter also bound to structurally similar targets, BoNT type B, type E holotoxins, and heavy or light chain components, in a soil dilution. The author compared their MRE sequence to previous ssDNA MRE specific for BoNT and found consensus short sequence segments. This suggested that the binding between BoNTs and MREs may be conserved within these consensus segments [122] . Microcystin is a hepatotoxin produced by cyanobacteria. Three different analogs of microcystin were used in the study performed by Nakamura et al. Microrocystin LR, containing a leucine substituent, was immobilized and used for twelve rounds of target selection. However, surface plasmon resonance binding data indicated a higher binding level between the selected MRE and microcystin YR, an analog containing a tyrosine substituent. There was also significant binding to microcystin RR, an analog containing an arginine substituent. The reported binding affinity ( ) was low, at approximately 10 3 M −1 . This early work did not demonstrate the high affinity and specificity properties of MREs; however, it did show the possibility of using MREs as a binding molecule in a label-free detection system [123] . Cylindrospermopsin (CYN) is another water soluble and heat stable alkaloid secreted by a large group of fresh water cyanobacteria. It has a variety of toxic effects in human bodies upon exposure to cylindrospermopsin usually through drinking water or food [124] . Elshafey et al. recently selected ssDNA MRE with high affinity and specificity toward CYN, with a reported of 88.78 nM. Circular dichroism measurements showed that MRE had a conformational change upon binding to CYN. This property was exploited in a labelfree impedimetric biosensor. The reported LOD of the sensor was 100 pM with a linear range of 80 nM. It also showed negligible responses toward coexistent cyanobacterial toxins of microcystin-LR and Anatoxin-a. CYN was recoverable in a spike test with tap water [125] . Saxitoxin is a small neurotoxin produced by few dinoflagellates and certain cyanobacteria that affect marine organisms [248] . Handy et al. were the first to select ssDNA MRE against target saxitoxin. In their study, saxitoxin was conjugated to keyhole limpet hemocyanin (KLH) via a spacer compound, 2,2 -(ethylenedioxy)bis(ethylamine), or JEFFAMINE and then the protein-toxin conjugate immobilized on magnetic beads. Ten rounds of selection were performed, and negative selection against KLH-bead was carried out from round four to the round ten, in order to decrease nonspecific binding to KLH and beads. One candidate sequence was analyzed by SPR and demonstrated a concentration-dependent and selective binding to saxitoxins. However, the of the selected MRE was not presented in the study [145] . Okadaic acid (OA) is a phycotoxin produced by Dinophysis and Prorocentrum algae. It can accumulate in shellfish due to its lipophilic and heat-stable nature. Human consumption of OA can lead to a variety of gastrointestinal symptoms [249] . Eissa et al. identified ssDNA MRE with high affinity and specificity toward OA after eighteen rounds of mixed target and negative target selection. The candidate MRE with the highest affinity ( = 77 nM) was chosen for circular dichroism analysis. A conformational change in the MRE was observed upon binding of OA. A label-free electrochemical impedimetric biosensor was developed with this MRE and achieved a LOD of 70 pg/mL. It demonstrated no crossbinding activity toward structurally similar toxins, including dinophysis toxins-1 and -2 and microcystin-LR [12] . Ochratoxin A (OTA) is a mycotoxin produced by members of the Aspergillus and Penicillium genera. It is a nephrotoxin and has potential carcinogenic effects in humans. It has been shown as a contaminant in many food products, such as grains and wine [250] . However, the current detection method for OTA is both expensive and time-consuming [251] . Cruz-Aguado and Penner identified ssDNA MRE specific for OTA after thirteen rounds of selection. The best candidate MRE reported had a value of 200 nM. It did not bind nonspecifically to warfarin, N-acetyl-L-phenylalanine, or ochratoxin B in a fluorescent based cross-binding assay [146] . Subsequently, the authors developed a detection system based on a fluorescence polarization displacement assay. The author reported that the assay was sensitive to OTA but not to warfarin and N-acetyl-L-phenylalanine, with a LOD of 5 nM. However, the detection assay did not test ochratoxin B (OTB) binding activity or sensitivity in food sample [147] . Barthelmebs rounds of selection. After binding and cross-binding analysis, the best candidate had a value of 96 nM with minimal binding to OTB and phenylalanine. It was incorporated into an ELISA and ELAA assays for the detection of OTA spiked in pretreated wine samples. Different ELAA and ELISA assays were compared, and a direct competitive ELAA had the lowest detection limit of 1 ng/mL with the shortest analysis time of 125 minutes [148] . McKeague et al. performed fifteen rounds of in vitro selection to identify ssDNA MREs specific for OTA. Two candidate MREs had reported values of 110 ± 50 nM (designated B08) and 290 ± 150 nM (designated A08). A08 ssDNA MRE was utilized in a labelfree fluorescence detection assay and achieved a LOD of 9 nM. It also had low cross-binding activity on OTB and warfarin. The authors reported a truncated version of A09 also had similar specificity and binding affinity profiles [149] . Fumonisins are heat-stable mycotoxins present in most corn and are produced by fungi, Fusarium verticillioides and Fusarium proliferatum. Fumonisin B 1 (FB 1 ) is a nephrotoxin and potential carcinogen in humans. As the toxin cannot be inactivated by cooking in high temperature, it is crucial to monitor its level during food production [252] . McKeague et al. performed eight rounds of selection to identify ssDNA MRE with high binding affinity toward FB 1 . Unmodified magnetic beads (immobilization substrate), L-homocysteine, L-cysteine, and L-methionine L-glutamic acid were used as negative targets in the selection. Six candidate MREs were identified, and the best candidate MRE had a reported of 100 nM. However, the authors did not test the specificity of the selected MRE on other mycotoxins [13] . Zearalenone (ZEN; F-2 toxin) is a nonsteroidal estrogenic mycotoxin produced by many fungus species in the Fusarium genus. It has been shown to be present in many grains worldwide, such as oats, wheat, rice, and their derived food products [253] . Chen et al. performed fourteen rounds of selection, and the best candidate MRE had reported of 41 ± 5 nM and high specificity. Cross-binding assays showed insignificant binding to other mycotoxins, -zearalenol, aflatoxin B1, aflatoxin B2, fumonisin B 1 , and fumonisin B 2 . Circular dichroism measurement showed a conformational change of the MRE after binding of zearalenone. A detection assay using MRE immobilized magnetic beads and the bluegreen florescence property of zearalenone was developed. A LOD of 0.785 nM was achieved in pretreated beer samples [150] . T-2 toxin (T-2) is a trichothecene mycotoxins produced by many species in the Fusarium genus and is harmful to humans. It is a very stable small molecule biological toxin that is resistant to high temperature and is present in variety of grains, such as oats, barley, and wheat. Currently, it can only be detected by labor intensive and costly instruments and it is thus difficult to monitor its level in food [254] . Chen et al. recently utilized ten rounds of GO-SELEX to identify ssDNA MRE specific for T-2 with high affinity and specificity. Fluorescent binding and cross-binding assay showed that the of the best candidate MRE was in the nanomolar range, with insignificant cross-binding activities on FB 1 , ZEN, OTA, and aflatoxin B1. There was a conformational change upon MRE-T-2 binding. The authors also developed a fluorescent assay to detect spiked T-2 level in beer. A LOD of 0.4 M was achieved [151] . Aflatoxins are highly toxic natural compounds produced by many species of filamentous fungi and can contaminate agricultural products. The LD 50 can be as low as 0.5 mg/kg, and acute toxicity is even higher than many chemical toxins, such as cyanide or arsenic [255, 256] . Ma et al. performed an in vitro selection on a subtype of aflatoxins, aflatoxins B1 (AFB1). After ten rounds of target and negative target selection, the best candidate MRE had a reported of 11.39 ± 1.27 nM and with minimal cross-binding activities on aflatoxins B2, G1, G2, OTA, and FB 1 . A fluorescent assay similar to the authors' previous study on ZEN and T-2 specific MRE was developed to detect spiked levels of AFB1 in methanol-extracted peanut oil. The assay achieved a LOD of 35 ng/L [152] . Malhotra et al. perform two selections (SELEX1 and SELEX2) using slightly different methodologies to identify ssDNA MREs specific for both AFB1 and aflatoxins M1 (AFM1). In SELEX1, lambda exonuclease was used to generate ssDNA from amplified dsDNA. AFM1 coated magnetic beads were used as a positive target from round 1 to round 10, and AFB1 coated magnetic beads were used as positive target at round 11 (last round) only. Free targets were used to competitively elute ssDNA that bound to toxin coated beads in round 10 and round 11. In SELEX 2, each round started from preincubation with counter targets (uncoated beads, AFB1 beads) followed by incubation with AFM1 beads. Snap cooling was used to obtain ssDNA from dsDNA. In SELEX 2, only eight rounds were carried out. Multiple candidate MREs were analyzed and their values were in the nanoto low micromolar range. One MRE with the best affinity ( = 35.6 ± 2.9 nM), designated AFAS3, was used in developing a colorimetric assay based on MRE immobilized gold nanoparticles. This assay had a detection range of 250 to 500 nM of AFM1 and only minor interaction with AFB1. However, there were no reported cross-binding data on other mycotoxins [153] . Two studies identified ssDNA MREs specific for biological toxins with therapeutic intentions. Alpha-Bungarotoxin is a toxic substance in krait snake venom and can bind irreversibly to acetylcholine receptors and eventually lead to death in victims [257, 258] . Lauridsen et al. performed a rapid one-step SELEX and identified ssDNA MRE with relatively high binding affinity toward Alpha-Bungarotoxin ( = 7.58 M). The authors claimed that rapid selection technique could potentially be used with a chemically modified nucleic acid library and generate MREs suitable for diagnostic and therapeutic purposes [31] . Vivekananda et al. selected ssDNA MRE specific for alpha-toxin of Staphylococcus aureus. Several candidate sequences showed cell rescuing effects when coadministrated with alpha toxin in multiple in vitro neutralization assays. The authors claimed that it was possible to generate MREs against alpha-toxin for the treatment of S. aureus infections [155] . Hong et al. also performed an in vitro selection against S. aureus alpha toxin. Twelve rounds of positive and eleven rounds of negative rounds of negative selection were performed to identify the candidate ssDNA MRE. The reported determined by SPR single cycle kinetics was 93.7 ± 7 nM. Acetamiprid Immobilization free 4.98 M -- [27] Fluorescence plate based cross-binding assay showed the ssDNA MRE was approximately two to five times more selective on the alpha toxin than negative targets. A proofof-concept modified ELISA using the selected ssDNA MRE had a reported sensitive target detection at 200 nM in human serum [154] . Toxins. The detection of chemical toxins is important in both food safety and environmental monitoring. Environmental and food contamination by various kinds of chemical toxins have been reported and even at low concentrations can still be detrimental to human health. Currently, the majority of small chemical toxins can only be detected by labor intensive and costly laboratory equipment such as liquid and/or gas chromatography coupled with mass spectrometry. In order to address these current limitations, there has been an increase in the identification and biosensing applications of MREs with high affinity and specificity to capture and detect chemical toxins. However, the in vitro selection of ssDNA MREs targeting small molecule chemical toxins has several inherent challenges, such as difficulties in efficient separation between bound and unbound DNA molecules, limited chemical motifs on target surfaces for sufficient binding, lack of chemical functional groups for target immobilization, and candidate MREs that may not have sufficient specificities to distinguish molecules with very similar chemical structures if selection schemes are not carefully designed. For these reasons, there are a limited number of ssDNA MREs specific for chemical toxins currently in the literature (Table 5) However, due to the small molecular weight of E2, there were no observable binding events by SPR. An electrochemical platform measured under SWV was eventually utilized to detect E2 with a LOD of 0.1 nM in buffer solutions [156] . Alsager et al. selected a 75-mer ssDNA MRE specific for E2 with a of 50 nM after eighteen rounds of selection. The 5 amino-modified MRE was covalently conjugated to carboxylated nanoparticles and dynamic light scattering/resistive pulse sensing was used to observe size contraction in particle size upon E2 binding. A detection range of 5 nM to 100 nM was achieved with this detection platform. Progesterone, testosterone, Bis (4-hydroxyphenyl) methane (BPF), and bisphenol-A (BPA) were also tested for the specificity of the selected MRE. The assay showed minimal binding to both BPA and BPF; however, the MRE was not able to distinguish the other two steroids [157] . Bisphenol A (BPA) is an estrogen mimicking chemical that has been classified as an endocrine-disrupting compound. It is used in the manufacture of polycarbonate plastic products, such as plastic bottles and containers. It has been shown to be released into food after heating and can accumulate in human [259] . Jo et al. selected ssDNA MRE specific for Bisphenol A with high affinity and specificity. The reported was 8.3 nM with only minimal binding to structurally related chemical molecules, including 6F biophenol A, bisphenol B, and 4, 4 -bisphenol. A cy-3 labeled MRE pair was immobilized on sol-gel biochip and a sandwich detection assay was developed with nanomolar range sensitivity. However, the authors acknowledged the assay system can only detect a limited range of BPA concentrations [158] . Polychlorinated biphenyls (PCB) are a group of chlorinated hydrocarbons that are used in varies of industrial settings. PCBs are highly toxic and are reported to be an environmental contaminant affecting water bodies and food sources [260] . Mehta et al. identified PCB binding ssDNA MREs with nanomolar range affinity. In their study, two PCB compounds with hydroxyl functional group were immobilized on magnetic beads and used as target for selection. After nine rounds of selection, three candidate sequences were chosen for characterization. Two of the three candidate sequences (9.1 and 9.3) showed comparable binding affinities to both immobilized targets. In subsequent crossingbinding analysis, candidate 9.1 showed broad substrate binding affinity to other PCB compounds, while candidate 9.2 showed a high specificity for the two PCBs with hydroxyl functional groups. The study did not test specificity on other hydrocarbons that are structurally similar to PCB [160] . Xu et al. immobilized a primary amine modified PCB compound (PCB77-NH 2 ) on epoxy-activated Sepharose agarose as the target for in vitro selection. After 11 rounds of selection, four candidate sequences were characterized to have affinity in the low micromolar range. Cross-binding assays showed only minimal binding toward other hydrocarbons and agarose substrate. A fluorescent based detection assay was developed using the fluorescence quenching property of gold nanoparticle. Upon binding to target, the fluorescent signal was released. A detection range of 0.1-100 ng/mL was achieved. This assay detected other PCB compounds with different sensitivities [159] . The current detection method for herbicides and pesticides environmental contaminants in the environment relies on using time-consuming and labor intensive laboratory based equipment. MREs have been investigated as binding elements in rapid, field deployable detection systems. Atrazine is a widely used herbicide worldwide [261] . Sanchez utilized CE-SELEX to identify ssDNA MRE specific for atrazine with a of 890 nM. However, the MRE did not show specificity in binding between atrazine and structurally closely related simazine at concentration below approximately 2 M in a fluorescence polarization detection assay [161] . Williams et al. also performed an in vitro selection of ssDNA MRE specific for atrazine. A derivative of atrazine, desethyl-atrazine was first biotinylated and then immobilized on streptavidin coated magnetic beads. The selection scheme was designed with increasing selection stringency, by incorporating negative selections on streptavidin magnetic beads, simazine, metabolites of atrazine, and other commonly used pesticides. Competition selection was also performed to ensure the library bound only to free atrazine in solution, but not to desethyl atrazine. As a result, ssDNA MRE with subnanomolar affinity and high specificity was identified after twelve rounds of selection. A magnetic bead based capture assay coupled with capillary electrophoresis was developed to detect atrazine in artificially contaminated river water samples. The assay was able to detect atrazine in the nanomolar range [14] . Similar in vitro selection methodology was also employed by Williams et al. to identify MREs specific for a commonly used organophosphate pesticide, malathion. In their second selection, the selected MRE had high nanomolar range affinity, and minimal binding to metabolites of malathion and other herbicides. However, the author noted that the cross-binding activity was high on bovine serum albumin possibility due to the large, globular characteristics of the protein [15] . William et al. subsequently performed another selection on an herbicide, bromacil. This study further validated the methodology the authors employed to identify MREs with high affinity and low cross-binding activities on structurally similar compounds and compounds that were likely to coexist in the environment. The authors noted that these properties were particularly important for incorporating ssDNA MREs as sensing elements in biosensors [16] . As noted above, not every chemical toxin can be readily immobilized for portioning during selection. In order to circumvent this limitation, Wang et al. utilized an immobilization free in vitro SELEX developed by Li and coworkers to select ssDNA MREs specific for four different organophosphorus pesticides, phorate, profenofos, isocarbophos, and omethoate [26, 28] . After twelve rounds of selection, two candidate sequences reported values in the low micromolar range for all four targets. Cross-binding assays showed good specificities for the selected two MREs, with only minimal observed binding to eight other different pesticides [28] . The same group of researchers later developed a fluorescence polarization assay using the selected MREs to detect phorate, profenofos, isocarbophos, and omethoate at a LOD of 19.2, 13.4, 17.2, and 23.4 nM, respectively [247] . He et al. employed immobilization-free SELEX to identify ssDNA MRE specific for pesticide, acetamiprid. After eighteen rounds of selection, the best candidate MRE was reported to have a of 4.96 M. Specificity of the selected MRE was tested and cross-binding data showed no significant change in fluorescent signals in the presence of three other pesticides, imidacloprid, nitenpyram, and chlorpyrifos. The authors noted that the affinity of the selected MRE was lower than typical antibodies [27] . GO-SELEX was used to identify three ssDNA MREs specific to three different pesticides: tebuconazole, mefenacet, and inabenfide [25] . The reported values of were in the range of 10 to 100 nM. High specificity of each identified MRE was also determined by isothermal titration calorimetric and gold nanoparticle colorimetric assays. A simple, rapid detection method using gold nanoparticles was developed with LOD ranges from 100 to 400 nM. In recent years, a large number of researches have taken place in applying ssDNA MREs for the use in biosensors. Major detection methods can be categorized into three classes: (1) electrical/electrochemical, (2) optical, and (3) mass sensitive. The following section highlights the basic principles of the general classes of detection methods that have been utilized Influenza H5N1 Surface plasmon resonance -0.128 HAU Poultry [183] widely in the development of ssDNA MRE based biosensors. The relative portability of different detection methods is also briefly discussed. Recent literatures describing the detection of pathogens and toxins using ssDNA MREs biosensors are summarized in Tables 6, 7 , and 8. The principle of electrochemical detection is based on measuring changes in electrical properties of the sensing platform. In this method, ssDNA MRE is usually immobilized on a gold electrode via thiol-gold linkage. A redox label, such as methylene blue, can be used to detect binding between MRE and the target [262] . In a "signal on" system, the redox label is away from the electrode surface, and the binding of target causes a conformational change in the MRE and brings the redox label into close proximity with the electrode, thus causing a measurable change in electrical properties ( Figure 2) . A "signal off " system behaves similarly, but the binding of target causes the redox label to move [192] Aflatoxin B1 Fluorescence dipstick -0.3 ng/g Corn [193] Aflatoxin M1 Electrochemical redox current Magnetic nanoparticles 8 ng/L Milk [194] Ochratoxin A Colorimetric -20 nM - [195] Ochratoxin A Electrochemical impedance Graphene oxide, gold nanoparticles 0.74 pM Red wine [196] Ochratoxin A Fluorescence -1 ng/mL Beer [197] Ochratoxin A Electrochemical redox current Gold nanoparticles 0.75 pM Red wine [198] Ochratoxin A Electrochemiluminescence Loop-mediated isothermal amplification 10 fM Red wine [199] Ochratoxin A Fluorescence -2 pg/mL Wheat [200] Ochratoxin A Localized surface plasmon resonance -1 n M C o r n p o w d e r [201] Ochratoxin A RT-qPCR -1 fg/mL Red wine [202] Ochratoxin A Fluorescence -0.2 ng/mL Red wine [203] Ochratoxin Ochratoxin A Fluorescence -0.01 ng/mL Maize flour [232] away from the electrode. This system can also be modified as a "label-free" system, in which the redox molecule is intercalated in a hairpin structure of a MRE in a target unbound state, and binding of the target causes the release of the redox molecule ( Figure 2 ). In addition to measuring redox current, the changes in impedance upon binding of the target can also be measured. In this case, no labeling of MRE is required and the conformational changes in MRE upon target binding cause a measurable change in impedance that can be recorded by voltammetry [212] . Nanomaterials can also be incorporated into electrochemical sensor to enhance signals. Single-walled carbon nanotube field effect transistors (SWCNT-FET) can be used to build electrochemical biosensors (Figure 3 ). In this system, MREs are immobilized on SWCNTs and SWCNTs are sandwiched between a source and a drain electrode. When the immobilized MREs bind to the target, there is a measurable change in the conductance of the system [240] . Gold nanoparticles (AuNP) are also widely used as signal enhancers. AuNPs can be coated on electrodes and greatly increase the surface area. As a result, more MREs can be immobilized on the electrode, thus enhancing the system's sensitivity. AuNPs can also be coated with a second MRE and reporting probes in a sandwich assay (Figure 3 ). In this case, the target first binds to a primary capturing MRE, followed by the binding a secondary reporting MRE along with a redox molecule, which can generate an enhanced signal for sensitive detection [263] . In general, electrical/electrochemical detection systems are relatively smaller and more easily adapted into portable, chip-based platforms. This allows the ssDNA MREs biosensors to be used for on-site target detection [211, 212] . 3.2. Optical. Optical detection methods can be classified into three major categories: (1) fluorescence detection, which require specialized instruments to measure fluorescent signals; (2) colorimetric detection, which color changes can be observed by the naked eye or measured in terms of optical density; (3) absorbance assay can enhance detection signals, and subsequently be measured by instruments as well. Fluorescence. The principle of fluorescence detection is based on the generation or quenching of fluorescence signals upon target binding. Various fluorescence molecules and quantum dots can be linked to ssDNA MREs. Conformational changes induced by target binding can alter the fluorescence signal generated by the fluorophore and therefore can be measured (Figure 4 ) [264] . Quenching molecules can also be linked to the other end of the ssDNA MRE. In this system, the quencher completely blocks the fluorescence signal from the fluorophore and target binding can move the quencher away from the fluorophore and have "signal on" detection ( Figure 4 ) [265] . The same principle can also be applied for a "signal off " system. Carbon nanotubes and graphene can also be used as quenchers, where fluorescent labeled ssDNA MREs is adsorbed on the carbon quenchers via -stacking interactions. Fluorescence resonance energy transfer (FRET) can also be utilized as measurements when the distance of the two fluorescence molecules linked to MREs is changed upon target binding. Fluorescence based detection systems are frequently developed because of their high sensitivity and the ease of fluorescently labeling ssDNA MREs. Traditionally, the complete detection system requires large, costly components, including lasers, filters, and detectors. A recent study reported a portable ssDNA MRE based biosensor utilizing an optic fiber for sensitive detection of BPA [233] . Gold nanoparticles (AuNP) have been widely used in various colorimetric assays. AuNPs aggregate in salt solution and appear in purple color. When they are dispersed, they are in red color. This special absorbance property of AuNPs allows observation of target binding by naked eye. MREs in salt solution can bind to AuNPs, dispersing the AuNPs. When targets are introduced into the system, MRE preferably bind to the targets, therefore causing AuNPs to aggregate, and a red to purple color change is observed ( Figure 5 ) [266] . Alternatively, ssDNA MREs can be used to link AuNPs that are functionalized with probe strands. In this case, the initial state of the MRE/AuNPs solution is aggregated purple. Upon target binding, the linked AuNPs are released, and a purple to red color change is observed ( Figure 5 ) [267] . Furthermore, AuNPs can be used in a sandwich colorimetric assay, in which the secondary reporting MRE linked AuNP can grow in size when the detection system is placed in a growth solution containing HAuCl 4 , thus enhancing the detection limit [268] . Colorimetric detection systems are attractive for onsite target sensing due to the ease of observation with the naked eye. These systems are often developed into hand-held laminar flow devices [163, 204, 226] . Nucleic acid MREs have been used in modified enzyme linked immunoassays, usually substituting for either the capturing or the reporter antibodies. In a direct oligonucleotide enzyme link assay, often the protein target is adsorbed on plate and biotinylated MREs bind to the target and then followed by the addition of streptavidin-horse radish peroxidase (HRP) conjugate and enzyme substrate for signal development [148] . In a sandwich assay, biotinylated MREs can be immobilized on streptavidin plate and then followed by the addition of the protein target, HRP linked antibody, and enzyme substrate [98] . This detection method is mostly limited to clinical laboratory settings and detection of protein targets for which antibodies have been isolated ( Figure 6 ). Mass sensitive detection is a class of label-free detection system that can be subdivided into four Surface plasmon resonance (SPR) sensors measure a change in the refractive index and resonance angle when a mass change occurs upon target binding. MREs are often biotin-tagged and immobilized on streptavidin coated gold chip. When targets in solution pass through the flow cell, the binding between targets and immobilized MREs cause a change in mass on the sensor chip surface and is subsequently translated into a change in the refractive index. This change in resonance is proportional to the amount of target bound to the immobilized MREs and therefore providing a realtime detection of the target in solution (Figure 7 ) [183] . Commercially available SPR systems are typically large and limited to bench top use. One study reported a portable SPR biosensor based on ssDNA MREs for the detection of H5N1 influenza virus [183] . A Quartz crystal microbalance (QCM) is an acoustic wave resonator based on the piezoelectric property of quartz crystal. Nucleic acid MREs can be immobilized on goldcoated quartz. The binding between target and MRE increases the mass on the surface of the crystal and leads to a detectable decrease in the resonance frequency of the crystal (Figure 8 ) [181] . The detection principle of surface acoustic wave (SAW) based biosensor is similar to QCM. Nucleic acid MREs have been utilized to fabricate a special type of Love-wave sensor that uses shear horizontal waves to enhance the surface sensitivity and achieve ultrasensitive detection of the target [269] . Micromechanical cantilevers have been investigated for MRE based biosensors. The major advantage of this type of sensor is that it can be readily scale up and perform parallel analysis for multiple analytes with low background interference [270] . When the target binds to the MRE on the surface of the cantilever, a nanometer scale deflection in the cantilever can be detected optically ( Over the last two decades, there has been a continuous increase in the research of molecular recognition elements. Single-stranded DNA MREs have several advantages over antibodies, in terms of stability, reusability, and production cost. However, ssDNA MREs are not without limitations. The binding affinity of MREs is highly dependent on their three-dimensional structure and is influenced by factors including the ionic condition, temperature, and pH of the binding condition [4] . Challenges remain in eliminating cross-binding activities to other molecules in native environments. These limitations hinder the use of MRE for detection in many real world complex samples, such as biological fluids and food matrices. A carefully designed selection scheme can greatly improve the specificity of the identified MRE, which can better distinguish closely related molecules at low concentrations. Using modified bases in PCR amplification or performing base modifications after selection can also help improving resistance to nucleases in many biological fluids, such as human serum [271] . As the field of ssDNA MRE based biosensors continues to grow, improvements in SELEX methodology will be necessary to more rapidly isolate MREs with the desired affinity and specificity. Improvements will also be necessary to allow MREs against more targets and a wider variety of targets to be isolated. The development of MRE based sensors is becoming an increasingly diverse field. Scientist and engineers from many disciplines must work together in order to create the optimal end product. Portable ssDNA MRE based biosensors may be utilized in a variety of settings, such as food safety, environmental monitoring, and health care. The many attractive features of ssDNA MREs prompt researchers to continue to investigate and optimize their applications in biosensing. The commercialization of these devices should continue to increase in the future. Systematic evolution of ligands by exponential enrichment: RNA ligands to bacteriophage T4 DNA polymerase Aptamers: an emerging class of molecules that rival antibodies in diagnostics Design, synthesis, and amplification of DNA pools for in vitro selection Structure, recognition and adaptive binding in RNA aptamer complexes Biophysical characterization of DNA and RNA aptamer interactions with hen egg lysozyme Modified-RNA aptamer-based sensor for competitive impedimetric assay of neomycin B Selection of 2 -fluoromodified RNA aptamers for alleviation of cocaine and MK-801 inhibition of the nicotinic acetylcholine receptor Aptamers as functional nucleic acids: in vitro selection and biotechnological applications Selection and application of ssDNA aptamers to detect active TB from sputum samples Novel system for detecting SARS coronavirus nucleocapsid protein using an ssDNA aptamer A single-stranded DNA aptamer that selectively binds to staphylococcus aureus enterotoxin B Selection and identification of DNA aptamers against okadaic acid for biosensing application Screening and initial binding assessment of fumonisin B 1 aptamers In vitro selection of a single-stranded DNA molecular recognition element against atrazine In vitro selection of a single-stranded DNA molecular recognition element for the pesticide malathion In vitro selection of a single-stranded DNA molecular recognition element specific for bromacil Generation of singlestranded DNA by the polymerase chain reaction and its application to direct sequencing of the HLA-DQA locus Direct solid phase sequencing of genomic and plasmid DNA using magnetic beads as solid support Efficient preparation of singlestranded DNA for in vitro selection Use of PCR primers containing a 3 -terminal ribose residue to prevent cross-contamination of amplified sequences In vitro selection of high-affinity DNA ligands for human IgE using capillary electrophoresis Nonequilibrium capillary electrophoresis of equilibrium mixtures: a universal tool for development of aptamers Immobilization-free screening of aptamers assisted by graphene oxide An ultra-sensitive detection of a whole virus using dual aptamers developed by immobilization-free screening Multiple GO-SELEX for efficient screening of flexible aptamers In vitro selection of structure-switching signaling aptamers Isolation and identification of the DNA aptamer target to acetamiprid Selection of DNA aptamers that bind to four organophosphorus pesticides FluMag-SELEX as an advantageous method for DNA aptamer selection Single microbead SELEX for efficient ssDNA aptamer generation against botulinum neurotoxin Rapid one-step selection method for generating nucleic acid aptamers: development of a DNA Aptamer against alpha-bungarotoxin Generation of highly specific aptamers via micromagnetic selection Micromagnetic selection of aptamers in microfluidic channels Influenza A virus-specific aptamers screened by using an integrated microfluidic system Neutralizing aptamers from whole-cell SELEX inhibit the RET receptor tyrosine kinase A tenascin-C aptamer identified by tumor cell SELEX: systematic evolution of ligands by exponential enrichment Aptamers evolved from live cells as effective molecular probes for cancer study Selection of aptamers for molecular recognition and characterization of cancer cells Presence of faecal coliforms, Escherichia coli and diarrheagenic E. coli pathotypes in ready-to-eat salads, from an area where crops are irrigated with untreated sewage water Rapid fluorescent detection of Escherichia coli K88 based on DNA aptamer library as direct and specific reporter combined with immunomagnetic separation Aptamer selection for the detection of escherichia coli k88 Isolation and characterization of DNA aptamers against Escherichia coli using a bacterial cell-systematic evolution of ligands by exponential enrichment approach Selection of DNA aptamers against uropathogenic Escherichia coli NSM59 by quantitative PCR controlled Cell-SELEX A novel screening method for competitive FRET-aptamers applied to E. coli assay development In Vitro antibacterial effects of antilipopolysaccharide DNA aptamer-C1qrs complexes Selection of DNA aptamers for capture and detection of Salmonella Typhimurium using a whole-cell SELEX approach in conjunction with cell sorting Selection and characterization of aptamers against salmonella typhimurium using wholebacterium systemic evolution of Ligands by exponential enrichment (SELEX) Identification of Salmonella typhimurium-specific DNA aptamers developed using whole-cell SELEX and FACS analysis Selection, characterization, and application of DNA aptamers for the capture and detection of Salmonella enterica serovars Development of bacteriostatic DNA aptamers for salmonella Development of ssDNA aptamers for the sensitive detection of Salmonella typhimurium and Salmonella enteritidis Highly specific and cost-efficient detection of Salmonella paratyphi A combining aptamers with single-walled carbon nanotubes Screening and preliminary application of a DNA aptamer for rapid detection of Salmonella O8 Infectious diseases associated with molluscan shellfish consumption Selection and identification of a DNA aptamer targeted to Vibrio parahemolyticus Selection of aptamers against inactive Vibrio alginolyticus and application in a qualitative detection assay Selection and characterization of DNA aptamers specific for Listeria species Nucleic acid aptamers for capture and detection of Listeria spp Selection, identification and application of a DNA aptamer against Listeria monocytogenes In vitro selection of DNA aptamers and fluorescence-based recognition for rapid detection Listeria monocytogenes Internalins: a complex family of leucine-rich repeat-containing proteins in Listeria monocytogenes Antibody-aptamer functionalized fibre-optic biosensor for specific detection of Listeria monocytogenes from food Global burden of Shigella infections: implications for vaccine development and implementation of control strategies In vitro selection of a DNA aptamer targeted against Shigella dysenteriae Risk factors for sporadic Campylobacter infection in the United States: a case-control study in FoodNet sites Plastic-adherent DNA aptamer-magnetic bead and quantum dot sandwich assay for Campylobacter detection Evaluation of relative aptamer binding to Campylobacter jejuni bacteria using affinity probe capillary electrophoresis Selection and characterization of DNA aptamers with binding selectivity to Campylobacter jejuni using whole-cell SELEX In silico maturation of binding-specificity of DNA aptamers against Proteus mirabilis Simultaneous improvement of specificity and affinity of aptamers against Streptococcus mutans by in silico maturation for biosensor development Invasive group a streptococcal disease: epidemiology, pathogenesis and management DNA aptamers binding to multiple prevalent M-types of streptococcus pyogenes Staphylococcus aureus infections Combining use of a panel of ssDNA aptamers in the detection of Staphylococcus aureus Rapid single cell detection of Staphylococcus aureus by aptamer-conjugated gold nanoparticles Pouring salt on a wound: pseudomonas aeruginosa virulence factors alter Na+ and Clflux in the lung Opportunistic infections in lung disease: pseudomonas infections in cystic fibrosis Utility of aptamer-fluorescence in situ hybridization for rapid detection of Pseudomonas aeruginosa Treatment of tuberculosis Aptamer from whole-bacterium SELEX as new therapeutic reagent against virulent Mycobacterium tuberculosis Bioterrorismrelated inhalational anthrax: the first 10 cases reported in the United States In vitro selection of DNA aptamers to anthrax spores with electrochemiluminescence detection Fluorescence assay based on aptamer-quantum dot binding to bacillus thuringiensis spores Development of aptamer beacons for rapid presumptive detection of Bacillus spores Nature of protective immunity to Francisella tularensis Anti-Francisella tularensis DNA aptamers detect tularemia antigen from different subspecies by Aptamer-Linked Immobilized Sorbent Assay From the regulation of peptidoglycan synthesis to bacterial growth and morphology Selection of peptidoglycanspecific aptamers for bacterial cells identification The lipooligosaccharides of pathogenic gram-negative bacteria Receptor-dependent mechanisms of cell stimulation by bacterial endotoxin Harnessing aptamers for electrochemical detection of endotoxin Noroviruses: the leading cause of gastroenteritis worldwide Ultrasensitive norovirus detection using DNA aptasensor technology Selection, characterization and application of nucleic acid aptamers for the capture and detection of human norovirus strains Selection of a DNA aptamer against norovirus capsid protein VP1 Understanding the symptoms of the common cold and influenza Selection and characterization of DNA aptamers for use in detection of avian influenza virus H5N1 Selection of DNA aptamers that bind to influenza A viruses with high affinity and broad subtype specificity Characterization of monoclonal antibody against SARS coronavirus nucleocapsid antigen and development of an antigen capture ELISA CS-SELEX generates high-affinity ssDNA aptamers as molecular probes for hepatitis C virus envelope glycoprotein E2 Dengue virus life cycle: viral and host factors modulating infectivity Thioaptamers targeting dengue virus type-2 envelope protein domain III Capillary electrophoresis-SELEX selection of aptamers with affinity for HIV-1 reverse transcriptase Foodborne illness acquired in the United States-major pathogens Use of magnetic beads in selection and detection of biotoxin aptamers by electrochemiluminescence and enzymatic methods Selection and characterization of DNA aptamers against Staphylococcus aureus enterotoxin C1 Clinical recognition and diagnosis of Clostridium difficile infection Production of a complete binary toxin (actin-specific ADP-ribosyltransferase) by Clostridium difficile CD196 Detection of Clostridium difficile toxins A, B and binary toxin with slow off-rate modified aptamers Systematic selection of modified aptamer pairs for diagnostic sandwich assays In vitro selection of single-stranded DNA molecular recognition elements against Clostridium difficile toxin B and sensitive detection in human fecal matter Multidrug-resistant and extensively drug-resistant tuberculosis: a threat to global control of tuberculosis Fluorescence versus conventional sputum smear microscopy for tuberculosis: a systematic review Sputum processing methods to improve the sensitivity of smear microscopy for tuberculosis: a systematic review CFP10 and ESAT6 aptamers as effective Mycobacterial antigen diagnostic reagents Clinical evaluation of MPT-64 and MPT-59, two proteins secreted from Mycobacterium tuberculosis, for skin test reagents The selection and application of ssDNA aptamers against MPT64 protein in Mycobacterium tuberculosis Anthrax toxin Nano aptasensor for protective antigen toxin of anthrax Screening and characterization of high-affinity ssDNA aptamers against anthrax protective antigen Botulinum toxin: bioweapon & magic drug An aptamer beacon responsive to botulinum toxins Usage of a DNA aptamer as a ligand targeting microcystin Freshwater cyanobacteria (blue-green algae) and human health In vitro selection, characterization, and biosensing application of high-affinity cylindrospermopsin-targeting aptamers DNA aptamers selected against the HIV-1 RNase H display in vitro antiviral activity Novel aptamer inhibitors of human immunodeficiency virus reverse transcriptase High-affinity ssDNA inhibitors of the reverse transcriptase of type 1 human immunodeficiency virus DNA aptamers to human immunodeficiency virus reverse transcriptase selected by a primer-free SELEX method: characterization and comparison with other aptamers DNA aptamers derived from HIV-1 RNase H inhibitors are strong anti-integrase agents Structure-activity of tetrad-forming oligonucleotides as a potent anti-HIV therapeutic drug DNA aptamers selected against the HIV-1 trans-activation-responsive RNA element form RNA-DNA kissing complexes In vitro selection of DNA aptamers against the HIV-1 TAR RNA hairpin Inhibition of hepatitis C virus (HCV) RNA polymerase by DNA aptamers: mechanism of inhibition of in vitro RNA synthesis and effect on HCVinfected cells An aptamer targets HBV core protein and suppresses HBV replication in HepG2.2.15 cells Differential inhibitory activities and stabilisation of DNA aptamers against the SARS coronavirus helicase A DNA aptamer prevents influenza infection by blocking the receptor binding region of the viral hemagglutinin Potent inhibition of human influenza H5N1 virus by oligonucleotides derived by SELEX Neutralizing DNA aptamers against swine influenza H3N2 viruses DNA aptamers against the receptor binding region of hemagglutinin prevent avian influenza viral infection Single-stranded DNA aptamer that specifically binds to the influenza virus NS1 protein suppresses interferon antagonism Isolation of ssDNA aptamers that inhibit rabies virus Use of cell-SELEX to generate DNA aptamers as molecular probes of HPV-associated cervical cancer cells One-step selection of Vaccinia virus-binding DNA aptamers by MonoLEX First report of the use of a saxitoxin-protein conjugate to develop a DNA aptamer to a small molecule toxin Determination of ochratoxin A with a DNA aptamer Fluorescence polarization based displacement assay for the determination of small molecules with aptamers Enzyme-Linked Aptamer Assays (ELAAs), based on a competition format for a rapid and sensitive detection of Ochratoxin A in wine Selection and characterization of a novel DNA aptamer for label-free fluorescence biosensing of ochratoxin A Selection and identification of ssDNA aptamers recognizing zearalenone Screening and identification of DNA aptamers against T-2 Toxin assisted by graphene oxide Selection, identification, and application of Aflatoxin B1 aptamer Selection of aptamers for aflatoxin M1 and their characterization In vitro selection of single-stranded DNA molecular recognition elements against S. aureus alpha toxin and sensitive detection in human serum DNA aptamers as a novel approach to neutralize Staphylococcus aureus -toxin Electrochemical detection of 17beta-estradiol using DNA aptamer immobilized gold electrode chip Small molecule detection in solution via the size contraction response of aptamer functionalized nanoparticles Development of single-stranded DNA aptamers for specific bisphenol a detection Selection of DNA aptamers against polychlorinated biphenyls as potential biorecognition elements for environmental analysis Selection and characterization of PCB-binding DNA aptamers DNA Aptamer Development for Detection of Atrazine and Protective Antigen Toxin Using Fluorescence Polarization, Microbiology A simple aptamer biosensor for Salmonellae enteritidis based on fluorescence-switch signaling graphene oxide Lateral flow biosensor for DNA extraction-free detection of salmonella based on aptamer mediated strand displacement amplification A visual detection method for Salmonella Typhimurium based on aptamer recognition and nanogold labeling An aptamer-based electrochemical biosensor for the detection of Salmonella Aptamer-based impedimetric sensor for bacterial typing Gold nanoparticle-based enzymelinked antibody-aptamer sandwich assay for detection of Salmonella typhimurium A dual-color flow cytometry protocol for the simultaneous detection of Vibrio parahaemolyticus and Salmonella typhimurium using aptamer conjugated quantum dots as labels Dual-color upconversion fluorescence and aptamer-functionalized magnetic nanoparticlesbased bioassay for the simultaneous detection of Salmonella Typhimurium and Staphylococcus aureus Label-free detection of Staphylococcus aureus in skin using real-time potentiometric biosensors based on carbon nanotubes and aptamers Graphene-based potentiometric biosensor BioMed Research International for the immediate detection of living bacteria A sensitive gold nanoparticlebased colorimetric aptasensor for Staphylococcus aureus A new aptamer/SWNTs IDE-SPQC sensor for rapid and specific detection of Group A Streptococcus Aptamer cocktails: enhancement of sensing signals compared to single use of aptamers for detection of bacteria Aptasensors for rapid detection of Escherichia coli O157: H7 and Salmonella typhimurium A rapid and sensitive aptamer-based electrochemical biosensor for direct detection of Escherichia coli O111 Realtime potentiometric detection of bacteria in complex samples Potential of fluorophore labeled aptamers for Pseudomonas aeruginosa detection in drinking water Simultaneous aptasensor for multiplex pathogenic bacteria detection based on multicolor upconversion nanoparticles labels A PDMS/paper/ glass hybrid microfluidic biochip integrated with aptamerfunctionalized graphene oxide nano-biosensors for one-step multiplexed pathogen detection Hydrogel based QCM aptasensor for detection of avian influenza virus Aptamer-based viability impedimetric sensor for viruses A SPR aptasensor for detection of avian influenza virus H5N1 An aptamerfunctionalized gold nanoparticle biosensor for the detection of prion protein Aptamer biosensor for sensitive detection of toxin A of Clostridium difficile using gold nanoparticles synthesized by Bacillus stearothermophilus Target-induced aptamer release strategy based on electrochemical detection of staphylococcal enterotoxin B using GNPs-ZrO2-Chits film Attomole sensitivity of staphylococcal enterotoxin b detection using an aptamer-modified surface-enhanced Raman scattering probe Aptasensor for Staphylococcus enterotoxin B detection using high SNR piezoresistive microcantilevers Evanescent wave DNA-aptamer biosensor based on long period gratings for the specific recognition of E. coli outer membrane proteins A label-free DNA aptamer-based impedance biosensor for the detection of E. coliouter membrane proteins Aptamer-based electrochemical biosensor for Botulinum neurotoxin Development of an ultrasensitive aptasensor for the detection of aflatoxin B1 An aptamerbased dipstick assay for the rapid and simple detection of aflatoxin B1 Label-free detection of aflatoxin M1 with electrochemical Fe 3 O 4 /polyaniline-based aptasensor Aptamer-based colorimetric biosensing of Ochratoxin A using unmodified gold nanoparticles indicator Amplified impedimetric aptasensor based on gold nanoparticles covalently bound graphene sheet for the picomolar detection of ochratoxin A A simple and sensitive approach for ochratoxin A detection using a label-free fluorescent aptasensor Ultrasensitive electrochemical aptasensor for ochratoxin A based on two-level cascaded signal amplification strategy Ultrasensitive electrochemiluminescent aptasensor for ochratoxin A detection with the loop-mediated isothermal amplification A fluorescent aptasensor based on DNA-scaffolded silver-nanocluster for ochratoxin A detection A regeneratable, label-free, localized surface plasmon resonance (LSPR) aptasensor for the detection of ochratoxin A Femtogram ultrasensitive aptasensor for the detection of Ochratoxin A Fluorescent sensing ochratoxin A with single fluorophore-labeled aptamer Signal amplified strategy based on target-induced strand release coupling cleavage of nicking endonuclease for the ultrasensitive detection of ochratoxin A Highly sensitive ochratoxin A impedimetric aptasensor based on the immobilization of azido-aptamer onto electrografted binary film via click chemistry Electrochemical grafting of long spacer arms of hexamethyldiamine on a screen printed carbon electrode surface: application in target induced ochratoxin A electrochemical aptasensor Design of PEGaptamer two piece macromolecules as convenient and integrated sensing platform: application to the label free detection of small size molecules Electrochemical DNA aptamer-based biosensor for OTA detection, using superparamagnetic nanoparticles Development of an automated flow-based electrochemical aptasensor for on-line detection of Ochratoxin A An aptamer-based chromatographic strip assay for sensitive toxin semi-quantitative detection Fluorescent strip sensor for rapid determination of toxins An electrochemical competitive biosensor for ochratoxin A based on a DNA biotinylated aptamer Fabricated aptamer-based electrochemical 'signal-off ' sensor of ochratoxin A An electrochemical biosensor based on hairpin-DNA aptamer probe and restriction endonuclease for ochratoxin A detection Ultrasensitive one-step rapid detection of ochratoxin A by the folding-based electrochemical aptasensor Aptamerfunctionalized magnetic nanoparticle-based bioassay for the detection of ochratoxin A using upconversion nanoparticles as labels Electrochemical aptasensor for the determination of ochratoxin A at the Au electrode modified with Ag nanoparticles decorated with macrocyclic ligand Development of an electrochemical method for Ochratoxin A detection based on aptamer and loop-mediated isothermal amplification A simple and rapid biosensor for ochratoxin A based on a structure-switching signaling aptamer A signal-on fluorescent aptasensor based on Tb3+ and structure-switching aptamer for label-free detection of Ochratoxin A in wheat Analytical performances of a DNA-ligand system using timeresolved fluorescence for the determination of ochratoxin A in wheat Impedimetric DNA aptasensor for sensitive detection of ochratoxin A in food Gold nanoparticle-based fluorescence resonance energy transfer aptasensor for ochratoxin A detection Simply amplified electrochemical aptasensor of Ochratoxin A based on exonuclease-catalyzed target recycling Double-probe signal enhancing strategy for toxin aptasensing based on rolling circle amplification PVP-coated graphene oxide for selective determination of ochratoxin A via quenching fluorescence of free aptamer Electrochemiluminescent aptamer biosensor for the determination of ochratoxin A at a gold-nanoparticles-modified gold electrode using N-(aminobutyl)-N-ethylisoluminol as a luminescent label Aptamer-DNAzyme hairpins for biosensing of Ochratoxin A Rapid high-throughput analysis of ochratoxin A by the selfassembly of DNAzyme-aptamer conjugates in wine Single-walled carbon nanotubes based quenching of free FAM-aptamer for selective determination of ochratoxin A Polyaniline Langmuir-Blodgett film based aptasensor for ochratoxin A detection An aptamer-based fluorescence assay for ochratoxin A A portable optic fiber aptasensor for sensitive, specific and rapid detection of bisphenol-A in water samples Resonance light scattering determination of trace bisphenol A with signal amplification by aptamer-nanogold catalysis An electrochemical aptasensor based on gold nanoparticles dotted graphene modified glassy carbon electrode for label-free detection of bisphenol A in milk samples Functionalized aptamers as nano-bioprobes for ultrasensitive detection of bisphenol-A Ultrasensitive one-step rapid visual detection of bisphenol A in water samples by label-free aptasensor One-step signal amplified lateral flow strip biosensor for ultrasensitive and on-site detection of bisphenol A (BPA) in aqueous samples A highly sensitive and selective resonance Rayleigh scattering method for bisphenol A detection based on the aptamer-nanogold catalysis of the HAuCl 4 -vitamin C particle reaction Aptamer sandwich-based carbon nanotube sensors for single-carbon-atomic-resolution detection of non-polar small molecular species Asymmetric plasmonic aptasensor for sensitive detection of bisphenol a A femtomolar level and highly selective 17 -estradiol photoelectrochemical aptasensor applied in environmental water samples analysis Label-free aptamer-based electrochemical impedance biosensor for 17 -estradiol Aptamer-based optical biosensor for rapid and sensitive detection of 17 -estradiol in water samples Aptamer-based colorimetric sensing of acetamiprid in soil samples: sensitivity, selectivity and mechanism A highly selective electrochemical impedance spectroscopy-based aptasensor for sensitive detection of acetamiprid Organophosphorus pesticides detection using broad-specific single-stranded DNA based fluorescence polarization aptamer assay Non-traditional vectors for paralytic shellfish poisoning Determination of okadaic acid content of dinoflagellate cells: a comparison of the HPLCfluorescent method and two monoclonal antibody ELISA test kits Ochratoxin A from a toxicological perspective Analytical methods for determination of mycotoxins: a review US Food and Drug Administration's monitoring and surveillance programs for mycotoxins, pesticides and contaminants in food Review on the toxicity, occurrence, metabolism, detoxification, regulations and intake of zearalenone: an oestrogenic mycotoxin T-2 toxin, a trichothecene mycotoxin: review of toxicity, metabolism, and analytical methods Mycotoxins Aflatoxin contamination in foods and foodstuffs in Tokyo: 1986-1990 A controlled clinical trial of a novel antivenom in patients envenomed by Bungarus multicinctus Three-finger -neurotoxins and the nicotinic acetylcholine receptor, forty years on Parent bisphenol a accumulation in the human maternal-fetal-placental unit Levels and congener distributions of PCDDs, PCDFs and dioxin-like PCBs in environmental and human samples: a review Impacts of atrazine in aquatic ecosystems Labelfree electronic detection of thrombin in blood serum by using an aptamer-based sensor Impedimetric aptasensor with femtomolar sensitivity based on the enlargement of surfacecharged gold nanoparticles Affinity analysis of DNA aptamer-peptide interactions using gold nanoparticles Aptamer biosensor for protein detection using gold nanoparticles Unmodified gold nanoparticles as a colorimetric probe for potassium DNA aptamers Fast colorimetric sensing of adenosine and cocaine based on a general sensor design involving aptamers and nanoparticles Aptamerfunctionalized Au nanoparticles for the amplified optical detection of thrombin A Love-wave biosensor using nucleic acids as ligands Nanomechanical microcantilever operated in vibration modes with use of RNA aptamer as receptor molecules for label-free detection of HCV helicase Improving the stability of aptamers by chemical modification This work was supported by the National Science Foundation Cooperative Agreements (NSF-1003907 and NSF-0554328), Department of Defense Cooperative Agreement (W911NF-09-2-0044), and West Virginia University. The authors declare that there is no conflict of interests regarding the publication of this paper.