Highlights
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Covalent organic frameworks (COFs) show enormous potential for building high-performance electrochemical sensors due to their high porosity, large specific surface areas, stable rigid topology, ordered structures, and tunable pore microenvironments.
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The basic properties, monomers, and general synthesis methods of COFs in the electroanalytical chemistry field are introduced, with special emphasis on their usages in the fabrication of chemical sensors, ions sensors, immunosensors, and aptasensors.
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The emerged COFs in the electrochemiluminescence realm are thoroughly covered along with their preliminary applications.
Abstract
Covalent organic frameworks (COFs), a rapidly developing category of crystalline conjugated organic polymers, possess highly ordered structures, large specific surface areas, stable chemical properties, and tunable pore microenvironments. Since the first report of boroxine/boronate ester-linked COFs in 2005, COFs have rapidly gained popularity, showing important application prospects in various fields, such as sensing, catalysis, separation, and energy storage. Among them, COFs-based electrochemical (EC) sensors with upgraded analytical performance are arousing extensive interest. In this review, therefore, we summarize the basic properties and the general synthesis methods of COFs used in the field of electroanalytical chemistry, with special emphasis on their usages in the fabrication of chemical sensors, ions sensors, immunosensors, and aptasensors. Notably, the emerged COFs in the electrochemiluminescence (ECL) realm are thoroughly covered along with their preliminary applications. Additionally, final conclusions on state-of-the-art COFs are provided in terms of EC and ECL sensors, as well as challenges and prospects for extending and improving the research and applications of COFs in electroanalytical chemistry.
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1 Introduction
Since the discovery of boron-containing covalent organic frameworks (COFs) by Yaghi’s group in 2005 [1], this new class of porous crystalline materials has attracted widespread attention across several scientific communities [2,3,4,5]. Typically, COFs are formed via the polymerization of light elements, which are known to form robust covalent bonds in well-established and useful topologies [2, 3]. As a kind of porous polymer, crystalline COFs are characterized by a large specific surface area, high porosity, stable rigid topology, and tunable pore structure [4, 5]. Thus, with the rapid development of synthetic strategies and the properties disclosure of COFs in all aspects, a huge surge has emerged in their research and usage, especially in the fields of sensing, catalytic technology, optoelectronic devices, energy storage, pollutants treatment, etc. [6,7,8,9,10,11].
Electrochemistry has been recognized as a versatile analytical tool over the past few decades and remains competitive in the face of growing demands in life analysis, environmental monitoring, and food inspection [12, 13]. Known for superiorities in high sensitivity, low cost, fast response, simple equipment, and easy miniaturization, electrochemical (EC) sensors are devices that convert EC data between target analytes or sensing elements into analytical signals with application values [14,15,16]. Electrochemiluminescence (ECL), an important branch of EC technology, describes the light-emitting phenomenon initiated by the reactions of electro-generated radicals [17, 18]. During this process, the EC signals are converted into optical outputs, effectively avoiding EC background interference [19]. Since the luminescence source comes from the redox reactions on the electrode surface, ECL requires no external light source, displaying almost zero background [20]. Thus, ECL methodology, with characteristics of high sensitivity, outstanding controllability, and low-cost instruments, has aroused extensive research interest in clinical diagnosis, environmental monitoring, food analysis, etc. [17,18,19,20]. No matter the EC or ECL analysis, however, the essence is an EC reaction, that is, the electron-gain and loss reaction of electroactive species in the vicinity of the electrode [21]. Therefore, the established electrode surfaces afford the analytical performance of EC sensors, which is crucial for improving the key technical indicators such as sensitivity, stability, repeatability, and selectivity [17, 22].
It is known that EC sensors rely most on multifarious electroactive or catalytic materials on the electrodes, even though the EC detection methods are much the same [22,23,24,25]. Thus, developing and searching for high-quality electrode materials is particularly significant [26,27,28]. Microporous frameworks, such as inorganic zeolites, metal–organic frameworks (MOFs) [29,30,31,32,33,34], and organic COFs with high porosity and crystallinity are demonstrated to significantly enhance the analytical performance of EC sensors [35, 36]. Each one has its own superiorities and unique selling points [37,38,39,40,41,42], and their comparisons are summarized in Table 1 [43,44,45]. Thereinto, COFs as a brand-new category of porous crystalline materials have rapidly become a study focus in this area. The essence is that the super-micropores, high specific surface area, excellent stability, and modest conductivity of COFs guarantee sufficient active sites and favorable energy/mass transfer, while remarkable diversity and designability of the pore size, skeleton structure, and composition can regulate their EC behaviors.
Considering the great potential of the emerging COFs for building high-performance EC devices [45], this review primarily focuses on the corresponding analysis usages in electroanalytical chemistry (Fig. 1). To the best of our knowledge, there are only a few reviews partly regarding COFs in EC sensing [46,47,48,49], and no specific review that describes the role of COFs in the ECL domain to date. Hence, this review aims to make a comprehensive summary of the reports on COFs in electroanalytical chemistry in the last few years. We summarize the basic characteristics, monomers, and synthesis methods of COFs used in this field. Then, we introduce the EC analytical applications based on functional COFs systematically, including the fabrication of chemical sensors, ions sensors, immunosensors, and aptasensors. Also, COFs directly designed as ECL active emitters and non-ECL active matrixes, as well as their preliminary ECL sensing applications, are further highlighted. Finally, we discuss the challenges and future trends that COFs will face in the field of electroanalytical chemistry.
2 Basic Characteristics and Synthetic Methods
Thanks to several impressive reviews on the structural features and synthesis of COFs [2, 3, 5], deep dives into this part will be attempted only regarding COFs in terms of electroanalytical chemistry in this review. Generally, COFs are created by the polymerization of monomers with symmetric reactive groups following specific geometries. During condensation, covalent bonds are spatially confined in either a two- or three-dimensional (2D or 3D) manner or geometrically directed to generate extended and ordered 2D or 3D crystal structures [50, 51]. Metal ions coordination or functional groups can be predesigned into the motifs or introduced through post-modification [6]. Moreover, the presence of heteroatoms within COFs creates special microenvironments for redox-active centers or specific target binding [52, 53]. As such, COFs will advance fundamental understanding and applications to shine in the field of EC analysis.
Nowadays, various types of COFs are reported based on their dynamic covalent bonds, such as boronate ester, imine, olefin, β-ketoenamine, hydrazine, azine, and enamine [2,3,4,5, 54]. To the best of our knowledge, the formula of the monomers and their abbreviations used for the construction of COFs-based EC sensors are collected in Fig. 2B, mainly containing aldehyde, amino, cyano, triazine, hydroxyl, carbonyl, and boronic acid groups. The earliest reported boroxine/boronate ester-based COFs might be not stable enough to obtain available EC sensors in aqueous solutions or humid environments because of the electron-deficient nature of boron [1]. Triazine-containing COFs, also referred as covalent triazine skeletons, can be created by cyclic trimerization/hydroxyl aldol condensation reactions of nitrile. In comparison with boron-COFs, they have better stability and several EC usages, but they are commonly synthesized under harsh reaction conditions and with poor crystallinity [55, 56]. The imine-linked COFs are Schiff bases formed by condensation of amino and aldehyde groups, which have excellent crystallinity and structural regularity [57]. In particular, COFs with the imine linkage exhibit good chemical and thermal stability [4, 23]. For example, Xu et al. designed a porous imine-based COF with remarkable stability against water, strong bases, and strong acids by incorporating methoxy motifs into pore skeletons to enhance the interlayer interactions [4]. Until now, imine is still the most reported linkage in COFs preparation for EC sensing applications. Nevertheless, the electrical conductivity of these all-organic COFs is still limited due to the poor charge transfer ability of the linkages between the aromatic motifs [58]. The sp2 carbon-conjugated COFs with olefin linkages allow for acceptable electrical conductivity, beneficial to constructing EC sensors [59]. For the reader’s convenience, Table 2 summarizes the monomers and linkages of idiographic COFs in EC sensors.
At present, most COFs applied in the EC sensing scope are still dominated by a traditional solvothermal synthetic method [105]. Figure 2A depicts the synthesis diagram of the first reported COF products with the triboronate ester linkage as an example [1]. Briefly, the reactant monomers, catalysts, and solvents are uniformly mixed in a Pyrex tube, possibly with the aid of sonication. Subsequently, this charged tube is flash-frozen with liquid nitrogen and degassed by a pump. Undergoing multiple freeze–pump–thaw cycles to remove oxygen, it was sealed under a vacuum. The crude products are produced at a suitable temperature for some time, and the precipitates are collected, washed, and dried to obtain the final products [47]. Although COFs structure at the macroscopic level can be regulated, this method involves tedious preparation procedures and harsh reaction conditions. Several simplified synthetic methods have been attempted, that are, for example, the preparation using a stainless-steel reactor lined with a Teflon vessel [2, 83, 88, 106], and direct polycondensation under ambient conditions without vacuuming and heating processes [60, 92]. Certainly, exploring facile and green synthetic strategies is a new trend in manufacturing COFs-based EC sensors, such as water-mediated, solid-phase, vapor-assisted, hydrothermal, and micelle-assisted synthesis approaches [107].
3 COFs in EC Sensing
Crystalline COFs exhibit prominent advantages in achieving high-performance EC sensing compared with traditional covalent polymers and quite similar MOFs [2,3,4,5, 30, 32, 108,109,110,111]. First, COF networks built by π-stacking or extended π-conjugated backbones allow fast charge transport along the self-assembled molecular channel and show modest electrical conductivity. Second, the generally high specific surface area endows their high-load capacity of EC-active substances and a large electrode active area. Third, their macrostructures and nanosized pores can be tailored to accommodate specific guests via the non-covalent interaction (i.e., hydrogen bonds, π–π, hydrophobic, and electrostatic interactions), facilitating selective identification and enrichment of target molecules. Fourth, electroactive COFs with given redox patterns are utilized to develop accurate ratiometric EC sensing. Fifth, COFs with good flexibility are well distributed on the electrode surface without the assistance of membrane forming-reagents (e.g., Nafion and chitosan). Last but not least, COFs typically exhibit low toxicity, good biocompatibility, as well as high chemical and thermal stability, benefiting the development of repeatable and reproducible EC sensors, especially for the usages in biosensing. The relevant advances in COFs-based EC sensors including electrode materials, EC methods, analytes, and the limit of detection (LOD) are summarized in Table 2, and several representative ones are described in detail below.
3.1 Chemical Sensors
Chemical sensors are involved in all aspects of life, including physiological check, drug evaluation, food testing, environmental monitoring, etc. [112]. Most chemical molecules have their own characteristic EC redox activities, making them easy and convenient to be directly recognized according to their electro-redox attributes. Thus, versatile sensors by means of EC technologies, especially differential pulse voltammetry (DPV), square wave voltammetry (SWV), and amperometry (i-t), have been widely designed for chemical sensing because of their superiorities of sensitivity, portability, automation, and low price [83, 85]. Importantly, highly adaptable structural and functional design, specific recognition, electroactivity, unique catalytic capabilities, as well as inherent natures including high specific surface areas, ordered channels, and acceptable stability, make COFs promising electrode substrates for chemical detection. Thanks to the ample examples of chemical sensors, in this section, these improvement strategies of COFs-based analysis are further classified into the following four parts according to the improvement strategies.
3.1.1 For Good Electroconductivity
Despite these advantages, current COFs as electrode materials are still limited due to their poor affinity and conductivity. Hybridization with carbon materials might be the simplest and most economical way to achieve conductivity improvement [113]. Carbon nanotubes (CNTs) contain sp2 hybridized carbon atoms in a graphite sheet-like manner, owning large delocalized π orbitals and high electrical conductivity [60]. Further, mainly through π–π stacking, the conjugated COFs can be non-covalently assembled on the outer surface of CNTs. For instance, following an one-pot synthesis at a mild reaction condition, COFTAPB-TPA was immobilized in situ on an NH2–CNTs matrix with the building monomers of 1,3,5-tris(4-aminophenyl)benzene (TAPB) and terephthaldicarboxaldehyde (TPA). The resultant COFTAPB-TPA/NH2–CNTs presented nice conductivity and a large specific surface area, enabling the fabrication of a furazolidone EC sensor with a low LOD of 77.5 nM and acceptable recoveries ranged from 87.8 to 126.9% [60]. A similar work reported the growth of β-ketoenamine-linked COFBTH-Tp on NH2–CNTs by dehydration condensation between benzene-1,3,5-tricarbohydrazide (BTH) and 1,3,5-triformylphloroglucinol (Tp). Based on the composite, an EC sensor displayed excellent performances for nitrofural detection with a LOD of 3.2 nM [61]. Li et al. proposed an ultrasonic-mediated method for the self-assembly of COFTAPB-Dva (Dva: 2,5-divinylterephthalaldehyde)@graphitized multi-walled CNTs (MWCNTs) via the π–π conjugation effect. This silkworm-cocoon-like nanohybrid was further employed for the reliable detection of diuron in food samples, achieving a LOD of 0.08 μM and satisfactory recoveries from 96.40 to 103.20% [62]. Besides, conductive polymers can serve as conductive carriers for the in-situ loading of COFs. Using p-aminobenzoyl hydrazide (ABH) and 2,4,6-tris-(4-formylphenoxy)-1,3,5-triazine (TFPOT) as the monomers, Pan et al. accomplished a facile one-pot approach for in-situ growth of COFABH-TFPOT on the polyaniline, which amplified the response signal of sulfamethoxazole (SMX). This COFs-based EC sensor displayed a broad linear range (1–450 μM) and a low LOD (0.107 μM) for SMX, and was used for reliable testing of environmental water samples [65].
Nobel metal nanoparticles (NPs), known for excellence in conductivity, biocompatibility, and catalytic activity [66, 67], can be controllably grown and confined within the regular pore channels of COFs in a well-dispersed manner, thus fully exploiting the capabilities of COFs. For example, Lu and co-workers prepared COFTAPB-TPA/AuNPs via an in-situ growth method for enrofloxacin (ENR) detection. These loaded AuNPs-assisted redox reactions by lowering the overpotential, stabilizing reversibility, and accelerating charge transfer, thereby achieving a low LOD of 0.041 μM and good recoveries of 96.7–102.2% [66]. Similarly, Zhang and her colleagues fabricated an active and repeatable EC sensor for chlorogenic acid measurement based on COFs-supported AuNPs. In this work, AuNPs were prepared by in-situ chemical reduction and landed on the COFTAPB-DMTP (DMTP: 2,5-dimethoxyterephaldehyde) surface due to the firm electrostatic absorption of the remaining –NH2 of COFs (Fig. 3) [67]. In another work, Guan et al. obtained a new COF by a Schiff-base reaction between 2,6-diaminopyridine (DP) and 4,4′,4″,4‴-(pyrene-1,3,6,8-tetrayl)tetrabenzaldehyde (TFPPy) through a tube oven heating program. Further compounded with AuNPs, the resultant COFDP-TFPPy/AuNPs were directly utilized for the fabrication of a sensitive EC sensor to evaluate theophylline and caffeine in compound paracetamol capsules and black tea samples, and the LODs were 0.19 and 0.076 μM, respectively [68].
The synergy of multiple conductive species usually contributes to better EC activity. For instance, Zhang et al. synthesized the spherical COFBD-Tp (BD: benzidine) by a facile solution-phase method and loaded PtNPs by in-situ chemical reduction of H6PtCl4. After further integration of MWCNTs, the resultant ternary composites exhibited outstanding catalytic performance and electrical conductivity, affording effective drug sensing of tanshinol with a sensitivity up to 10.089 μA mM−1 and a LOD down to 0.018 μM [22]. Zhao and her colleagues developed an electrode matrix of COFTAPB-DMTP co-decorated with AuNPs and MWCNTs. This dual conductive species-supported COFs sensor exhibited excellent stability, reproducibility, and selectivity for doxorubicin detection with a low LOD of 16 nM [70]. Chen et al. fabricated a paper-based EC sensor for the furazolidone detection based on the nanocomposites of PtNPs/COFDHzDS-TFPB (DHzDS: 2,5-bis (3-(ethyl thiol) propoxy) p-benzoyl hydrazine; TFPB: 1,3,5-tris(p-formylphenyl) benzene)@reduced graphene oxide (rGO) [71]. In addition, Guan et al. established an EC sensing platform based on the composite of COFPDA-TFPPy, MWCNTs, and AuNPs. In this work, COFPDA-TFPPy was prepared by aminaldehyde condensation between 1,4-phenylenediamine (PDA) and TFPPy. The synergy of two EC active substances endowed this COFs-based biosensor with high conductivity, extraordinary stability, and large specific surface area, thus achieving simultaneous detection of uric acid (UA) and dopamine (DA) with LODs of 0.29 and 0.21 μM, respectively [72].
Additionally, conductive COFs can be built directly for chemical sensors. For example, Pan et al. prepared COFTABQ-TQ via a condensation reaction of tetraaminobenzoquinone (TABQ) and triquinoyl (TQ). This nitrogen-rich COF presented high crystallinity and good electrical conductivity (6.06 × 10−3 S cm−1), which was directly employed for the simultaneous analysis of guanine and adenine. The LODs were as low as 0.20 and 0.33 μM, respectively [73]. Wei and co-workers developed an interfacial perturbation growth method to obtain an ultrathin (≈ 1.95 mm) nitrogen and sulfur-rich bithiazole-based 2D-COF nanosheets (NSs) using the monomers of 2,2′-diamino-4,4′-bithiazole (DABTZ) and Tp. Owing to their remarkable electrical conductivity and abundant edge unsaturated sites, a high-performance biosensor was fabricated with acetylcholinesterase (AChE) as the biometric element for effective monitoring of organophosphorus pesticides [74].
3.1.2 For Enhanced Hydrophilicity
Since COFs are mostly composed of hydrophobic units, their poor hydrophilicity hinders efficient dispersion and causes weak contact between substances and reaction centers, inevitably affecting their EC activity and stability. To solve this problem, Lin’s group first prepared N, O-rich COFTTA-Tp through a condensation reaction of 4,4′,4″-(1,3,5-triazine-2,4,6-triyl) trianiline (TTA) and Tp. Post-carboxylation was adopted for enhanced hydrophilicity, supplying sufficient electron donors of O and N heteroatoms. Then, HAuCl4 was attached and reduced in situ to anchor highly dispersed AuNPs. Meanwhile, the decorated –COOH showed a greater affinity for gallic acid (GA) than for UA through hydrogen bonding, resulting in their oxidation peaks being separated on the sensor. Accordingly, the constructed sensor realized simultaneous analysis of GA and UA, displaying wide linear responses (1–175 μM; 1–150 μM) and low LODs (0.19 and 0.25 μM), respectively (Fig. 4) [75]. In another work, AuNPs were immobilized on COFPDA-Tp via supramolecular host–guest recognition of pillar [n]arenes. Specifically, macrocyclic hosts of dihydroxylatopillar [6]arene (2HP6) decorated AuNPs (2HP6@AuNPs) were prepared via in-situ reduction. Next, 2HP6@AuNPs were recognized on the cationic pillar [6]arene (CP6)@COFPDA-Tp. The final heterogeneous composites of 2HP6@AuNPs@CP6@COFPDA-Tp with enhanced hydrophilicity were utilized for rapid EC monitoring of sodium picrate by virtue of the electrocatalysis of AuNPs, the recognition and enrichment of 2HP6 and CP6, as well as the outstanding supporting of COFPDA-Tp [76].
3.1.3 For High Catalytic Performance
Enzymatic EC biosensors have received special attention because of the high efficiency and specificity of enzymatic reactions [14]. Nevertheless, native enzymes are vulnerable and prone to aggregation and inactivation during the construction and storage of sensors. Thus, immobilizing enzymes on COFs-supported matrices makes it possible to act synergically for both properties and advantages, sufficiently maintaining bioactivity, and distribution of enzymes. Yildirim et al. synthesized 2D triazine-based COFCTF-1 through cyclic trimerization using a single terephthalonitrile (TPN) monomer. Based on COFCTF-1 as the enzymatic support and superoxide dismutase (SOD) as the recognition element, an EC biosensor enabled the inspection of superoxide radicals in clinical samples with a 0.5 nM detection limit [55]. Xiao et al. covalently coupled AChE with the N, O-rich COFBTH-DHNDA (DHNDA: 2,6-dialdehyde-1,5-dihydroxynaphthalene). Further using anionic [Fe(CN)6]3−/4− as the sensing indicator, a turn-off EC biosensor based on a flexible carbon paper electrode enabled the carbaryl detection with a low LOD of 0.16 μM [77]. Wang et al. utilized the dual-pore COFETTA-TPA (ETTA: 4,4′,4″,4‴-(ethane-1,1,2,2-tetrayl) tetraaniline) to carry double enzymes of microperoxidase-11 (MPO-11) and glucose oxidase (GOD) for ratiometric EC biosensing of glucose, and the LOD was down to 4.97 μM. In this work, through pore encapsulation and hydrogen bonding, the two enzymes were well supported in different-sized pores of COFETTA-TPA, further allowing their firm attachments onto the electrode surface [78].
Although COFs can indeed protect enzymes from harsh conditions, the micropores of COFs restrict the free conformation of enzymes, which inevitably affects their catalytic activity. To improve the freedom of the enzyme configuration, Liang et al. designed a multienzyme microcapsule with a COF shell and a 600 nm-sized cavity to encapsulate native enzymes. Specifically, three model enzymes of AChE, horseradish peroxidase (HRP), and GOD were first loaded into zeolitic imidazolate framework-8 (ZIF-8). Subsequently, a robust COFDBD-TFPB shell was grown in situ outside the enzymes@ZIF-8 with 4,4′-diaminobiphenyl-2,2′-dicarboxylic acid (DBD) and TFPB via amine-aldehyde condensation. Ultimately, ZIF-8 was etched away to form a cavity loaded with multienzymes capable of free conformation. In comparison with those enzymes roughly stacked on the electrode surface, the biosensor constructed with this multienzyme microcapsule displayed superior catalytic performances, and the LODs achieved 0.85 μM, 2.81 nM, and 0.3 pg L−1 for glucose, H2O2, and malathion detection, respectively (Fig. 5) [14].
Some transition metal oxides and complexes also possess mimic catalytic centers without being limited by the fragility of natural enzymes any more. To avoid aggregation, these centers can be doped into the COFs with good dispersion and unique catalytic activity for non-enzymatic EC sensing. For example, Chen’s group proposed a shape-tailored controlled assembly method for growing COFTAPB-DMTP on the Co3O4 dodecahedrons. The core–shell composite exhibited uniform size, ultrahigh effective surface area, and excellent thermochemical stability, thus affording the tert-butylhydroquinone (TBHQ) EC sensing with a LOD as low as 0.02 μM. In this architecture, the Co3O4 core guaranteed the superior electronic and catalytic attributes, and 2D COFTAPB-DMTP with multilayered columnar channels facilitated the facile shuttling of TBHQ toward the active Co3+ sites (Fig. 6A) [23]. In addition, Zha et al. synthesized a core–shell structured FeNi@COFTAPB-DMTP nanocomposite with outstanding EC oxidation response toward GA and realized its sensing accordingly [79]. This group also prepared a similar CuO nanorods@COFTAPB-DMTP core–shell composite for DA detection with a LOD of 0.023 μM [80].
Iron-porphyrin with Fe3+/Fe2+ electroactive centers exhibits peroxidase biomimetic activity, which can catalyze many EC reactions, such as the reduction of O2, H2O2, and phenolic oxides. For instance, Xie et al. prepared an iron-porphyrin-based COF with monomers of 1,3,5-triformylbenzene (TFB) and 5,10,15,20-tetrakis (4-aminophenyl)-21H,23H-porphine (TAPP) via an aldehyde-ammonia reaction. After the post-chelation with Fe2+, the resultant COFTAPP-TFB/Fe2+ served as a mimic peroxidase with remarkable EC redox and proton activity, enabling enzyme-free evaluation of H2O2 and pH (Fig. 6B) [81]. Chu et al. prepared three 2D metalloporphyrin COFs by altering the central metal atoms of Fe, Mn, and Cu. The authors demonstrated that the Fe porphyrin-COF/GCE sensor displayed the best electrocatalytic performance in the EC sensing of butylated hydroxy anisole [114]. In addition to porphyrin, some metal ions can also act as catalysts directly. Zhang et al. functionalized COFTAPB-DMTP with β-cyclodextrin (β-CD) porous polymers and the catalytic Pd2+ element to fabricate a non-enzyme EC sensor for norfloxacin drug checking, showing two linear ranges of 0.08–7.0 μM and 7.0–100.0 μM with a LOD of 0.031 μM [82].
3.1.4 For Accurate Sensing Strategy
Ratiometric EC sensors based on two electrical signals are considered a significant advance due to their self-calibration, which can effectively avoid the errors caused by environmental or human factors, ensuring accurate target quantification [115]. It is exciting to note that the multiple redox peaks derived from electroactive COFs can directly serve as the response or reference signals for ratiometric sensing. For example, 2D COFThi-TFPB was synthesized from thionine (Thi) and TFPB via dehydration condensation and was further enwound by CNTs. With the improved stability and dispersibility, the COFs-supported CNTs exhibited prominent catalytic activity toward the oxidation of ascorbic acid (AA). Meanwhile, a pair of redox peaks assigned to electroactive COFThi-TFPB were inert to AA. As a result, a ratiometric strategy using the reference EC signal of COFThi-TFPB allowed for accurate AA sensing with a low LOD of 17.68 μM [83]. This group also grew COFThi-TFPB vertically on 3D macroporous carbon (3D-MC) to fabricate a carbon paste electrode for dual-signal ratiometric EC assays of riboflavin (RF) with a LOD as low as 44 nM. In this work, target RF molecules were first oxidized at + 0.6 V, and the partially formed oxidized RF (RFox) further oxidized COFTFPB-Thi (COFox). During the negative potential scanning (+ 0.6 ~ − 0.6 V), the reduction pattern of the composite remained unchanged at − 0.23 V, whereas COFox and RFox were successively reduced at − 0.08 and − 0.45 V. Therefore, both the ratio results of j−0.08/j−0.23 V and j−0.45/j−0.23 V can be considered as the response signals, which complemented each other and made the quantification more accurate and reliable (Fig. 7) [84]. In another work, COFTTA-DHTA prepared via aminaldehyde condensation between TTA and 2,5-dihydroxy terethaldehyde (DHTA) was also discovered with multiple redox-active states. Using COFTTA-DHTA as the active material for H2O2 electrocatalysis, the reduction responses at − 0.3 V and − 0.5 V were gradually increased with the continuous addition of H2O2, while the reduction peak at 0.3 V was nearly kept constant. Thus, both j−0.3 /j+0.3 V and j−0.5/j+0.3 V can serve as ratiometric results for H2O2 sensing [85].
Additionally, extra electroactive molecules can be introduced into the COFs-based EC system to accomplish the ratiometric analysis. For example, ferrocene (Fc) dicarboxylic acid molecules were directly introduced into the synthetic process of COFETTA-TPA nanospheres. The enwrapped Fc molecules not only increased the interlayer distance of COFETTA-TPA but also promoted the self-disproportionation of H2O2. Then, the produced O2 was electro-reduced by COFETTA-TPA at − 0.5 V. Meanwhile, the reduction response at + 0.45 V assigned to Fc molecules lowered with the increasing dosage of H2O2. Thus, an “on–off” nonenzymatic ratiometric EC platform enabled the H2O2 detection, showing a high sensitivity of 0.009 μM−1 and a low LOD of 0.33 μM [13]. Pang et al. electrodeposited AgNPs on a flexible carbon cloth and drop-coated COF-LZU1, which was prepared via the aminaldehyde condensation between PDA and TFB. Based on this, a stable EC response derived from AgNPs served as a standard signal, and COF-LZU1 enriched the targets, affording sensitive ratiometric responses toward bisphenol A (BPA) and bisphenol S (BPS) with a same LOD of 0.15 μM [86].
3.2 Ions Sensors
Accurate and selective ions sensing is of great importance in both environmental and biological fields [20, 116]. Given the different electro-redox properties of heavy metal ions (HMIs), anodic stripping voltammetry (ASV) is attractive for HMIs sensing because of its high sensitivity, simplicity, rapidity, and ease of online monitoring [52, 53]. Although ASV can play to its strengths, common problems such as poor stability and scarce identification elements still limit the detection of trace HMIs. By virtue of rich and diversiform absorption sites, COFs have attracted increasing attention in decorating high-quality HMIs sensing surfaces. For example, COFTAPB-DMTP, together with graphite powder and paraffin oil, was applied to manufacture carbon paste electrodes as ECL sensors, which achieved a remarkable current response to Pb2+ [52]. In another work, the sensitivity toward Pb2+ was significantly improved by modifying a glassy carbon electrode with an in-situ electroplated bismuth film and the nanocomposite of melamine (MA)-based COFs/Fe3O4 NPs [87].
The presence of COFs greatly enlarges the electroactive surface area, and these edge-terminal amino groups can serve as adsorption sites. However, marginal sites that rely on incomplete condensation of COFs are far from sufficient, while post-synthetic modifications with special functional groups can provide enough absorption sites. For instance, hydrosulphonyl functionalized COF (COF-SH) was synthesized via a solvothermal method with TAPB and Dva, followed by trithiocyanuric acid (TTC) post-modification. Using this COF-SH as the electrode substrate, abundant S and N sites accumulated HMIs, affording their sensitive EC quantification. The LODs were down to 0.3, 0.2, 0.2, and 1.1 μg L−1 for Cd2+, Pb2+, Cu2+, and Hg2+ detection, respectively [53].
Moreover, to avoid laborious and time-consuming post-processing, the N- or S-rich monomers of benzo [1,2-b:3,4-b′:5,6-b″] trithiophene-2,5,8-tricarbaldehyde (BTT) and TTA were selected for building rod-like COFTTA-BTT through one-step amine-aldehyde condensation. COFTTA-BTT was further employed for sensitive EC sensing of Hg2+, showing a low LOD of 0.18 nM due to its significant enrichment [88]. Also, COFMELE-BTDD with multiple active sites (N–S–N, –C=N) was prepared for the HMIs measurement by amine-aldehyde condensation of 2,5,8-triamino-s-heptazine (MELE) and 4,4′-(benzo[c] [1, 2, 5] thiadiazole-4,7-diyl)dibenzaldehyde (BTDD) [89]. The same group also synthesized lamellar COFMA-Tp using monomers of MA and Tp, and each unit displayed six adsorption sites (–C=N, –NH2, –C=O) for the selective capture of HMIs [90].
In order to increase the solubility of large-sized COFs, controlled assembly of COFBTLP-1 on 3D-MC derived from kenaf stem was achieved by directly introducing 3D-MC into the amine-aldehyde polymerization process between 1,4-benzenedithiol-2,5-diamino-hydrochloride (BDDH) and TFB. The resultant COFBTLP-1/3D-MC composite contained regular transport channels and twelve adsorption sites for both the transfer and adsorption of HMIs, which was further exploited for simultaneous detection of HIMs [24]. Besides, COFTAPB-DMTP was also selected for controllable growth on the surface of TiO2–NH2 via Schiff-base condensation. The nanocomposite was successfully employed for the determination of Mn2+ in Chinese liquor, and the LOD was as low as 0.0283 nM [91].
3.3 Immunosensors
Immunosensors relying on the highly specific recognition between antibodies (Abs) and antigens are prominent tools for the effective measurement of biomarkers [21]. During the past decades, EC immunological detection has aroused considerable concern because of its high sensitivity, splendid selectivity, simple operation, rapid response, and low sample consumption [117]. Generally, sandwich-type immunosensing has been recognized as one of the most popular modes, which utilizes captured Abs for target identification and reporter Abs tagged with probes or triggers to indicate signal changes [20, 118]. Thus, signal labels are the key points for signal stability and amplification. Using the spherical COFTAPB-DMTP as a carrier to sequentially load AuNPs, Abs, and HRP, a COF-supported signal probe was formed for the sandwiched EC immunosensing of cardiac troponin I (cTnI), a reliable biomarker of acute myocardial infarction, with a low LOD of 1.7 pg mL−1. Here, due to the enzymatic capacity of HRP, hydroquinone (HQ) was oxidized to benzoquinone (BQ) in the presence of H2O2, and BQ was then electro-reduced to output the amplified EC signals [92]. Also, COF-LZU1 was co-doped with AuNPs, Abs, and the electron mediator toluidine blue (TB) to behave as a signal probe. Further using polypyrrole-modified TiO2 NPs as the sensing substrate, a sandwich-type EC immunosensor realized the cTnI detection, exhibiting linearity ranging from 0.5 pg mL−1 to 10.0 ng mL−1 and a low LOD of 0.17 pg mL−1 [93]. Moreover, a magnetic COFBD-Tp carried methylene blue (MB) for signal amplification. Briefly, magnetic COFBD-Tp was synthesized by encapsulating Fe3O4 nanocrystals with an amorphous polyimine network through a Schiff-base reaction, which was further manipulated into crystalline imine-linked COFs under thermodynamic control. Through multi-noncovalent interactions, abundant MB molecules were incorporated into the macrocyclic supramolecular hosts of COFBD-Tp. Hence, using black phosphorene as a highly conductive matrix and this magnetic COFs-based probe for signal amplification, a sandwiched EC immunoassay realized the sensitive measurement of prostate specific antigen (PSA), an available serum biomarker of prostate tumors. The fabricated sensor achieved high analytical performance with a low LOD of 30 fg mL−1 (Fig. 8A) [94].
Another significant issue is to create a highly conductive, catalytic, and reusable sensing interface. The intrinsic properties of COFs make them favorable as an emerging class of electrode matrixes for supporting substances. In particular, 2D COFs with periodic layered arrays of π clouds can promote charge/carrier transport. For example, Liu et al. demonstrated the use of PtNPs-decorated COF-LZU1 as an EC platform for immunoassay. Meanwhile, AuNPs/MOFs (HKUST-1) complexes containing massive Cu2+ ions served as EC probes to show the expression of C-reactive protein (CRP), an effective indicator of infection, with a low LOD of 0.2 ng mL−1 [95]. Besides, Boyacıoğlu et al. fabricated a sandwich-typed EC immunosensor for kidney injury molecule-1 (kim-1) detection based on AuNPs/COFTAPB-TPA as the electrode substrate and NiCo2S4@CeO2 microspheres as the signal amplification tags. The prepared immunosensor exhibited good specificity, desirable stability, and acceptable reproducibility with a LOD down to 2.00 fg mL−1 [96]. Chen et al. developed a signal on–off ratiometric EC immunosensor to detect Amyloid-β oligomer (AβO), a reliable biomarker for the early diagnosis of Alzheimer’s disease. In this work, ultrasmall CuS NPs-loaded COFTAPB-DMTP acted as the electrode substrate to catalyze HQ oxidation for detectable signals. At the same time, electroactive Thi-decorated AuNPs served as another EC signal label. After AβO was introduced, the HQ signal decreased while the Thi signal increased, resulting in the ratios for the accurate AβO evaluation with a low LOD of 0.4 pM [97].
3.4 Aptasensors
Aptamers represent synthetic single-stranded DNA or RNA oligonucleotides with unique 3D configurations, which can non-covalently bind to target molecules specifically [119, 120]. Aptasensors have been excitingly exploited by virtue of the advantages of aptamers, such as easy synthesis, low cost, good stability, and specific recognition ability. It is worth noting that the attributes of COFs guarantee the high loading capacity of aptamers via multiple interaction forces, thus establishing effective EC aptasensing platforms [46].
Similar to the sandwich-type immunosensor, a “peptide-target-aptamer” EC biosensor was constructed for norovirus detection based on Au@black phosphorous NSs@Ti3C2-MXene nanohybrids as the electrode substance and Au@ZnFe2O4@COFTAPB-TPA as the magnetic tag. The redox probe TB can be further linked to the magnetic tags to output an increased EC signal. Thus, the biosensor achieved desirable selectivity, anti-interference, and stability with a low LOD of 0.003 copies mL−1, and it was successfully utilized for norovirus detection in stool samples without complex pretreatment [98]. Moreover, aptasensor can directly utilize the high-impedance target biomass to hinder the electron and mass transfer, thereby causing the decreased EC signals in a non-label manner. For example, Chen and his colleagues prepared the AuNPs@Ce-COFBpy-Tp (Bpy: 2,2′-bipyridine-5,5′-diamine) nanocomposite as the electrode matrix for aptamer immobilization. The sensors achieved the signal-off determination of zearalenone (ZEN) toxin, showing a low LOD of 0.389 pg mL−1 and a recovery in the range of 93.0–104.7% [99]. In another work, Song et al. synthesized Fc-based COFHHTP-BFc by connecting 2,3,6,7,10,11-hexahydroxytriphenylene (HHTP) and 1,1′-ferrocenediboronic acid (BFc) via boronate esters linkages, and its Fc moiety displayed remarkable voltammetric response. Then, a signal-on aptasensing strategy allowed for the label-free cTnI detection, because the affinity between cTnI and the specific aptamers drove away the aptamers from the COFHHTP-BFc surface, recovering its EC response [100].
Electrochemical impedance spectroscopy (EIS), a simple, sensitive, label-free, and rapid method, has been widely used to collect signals generated by binding the analyte to the specific aptamer-functionalized transducer interface. For example, Zhu et al. prepared COFTAPB-DMTP/AuNPs and COFTAPB-DMTP/CNTs as the covered substrates, which had a strong non-covalent affinity toward the aptamers of ciprofloxacin (CIP) and atrazine. Then, two EIS aptasensor achieved the detection of CIP and atrazine, showing low LODs of 7.06 fM and 3.11 pM, respectively [101, 102]. Wang et al. prepared an imine-linked COFMA-TFPPy by polycondensation of MA and TFPPy. COFMA-TFPPy showed strong immobilization of aptamers and fast charge-carrier mobility because of its high specific surface area, large pore cavities, rich surface groups, and extended π-conjugated frameworks. As such, a COFMA-TFPPy-based EIS aptasensor allowed for sensitive determination of antibiotics, ampicillin (AMP) and ENR, yielding extremely low LODs of 0.04 fg mL−1 and 6.07 fg mL−1, respectively [103]. This group also synthesized 2D porphyrin-based COFTAPP-TPA. The highly conjugated NSs structure not only possessed improved EC activity but also facilitated the attachment of aptamers and biomolecules. The COFTAPP-TPA-based aptasensor displayed remarkable analytical performance for living Michigan Cancer Foundation-7 (MCF-7) cells and epidermal growth factor receptor (EGFR) (Fig. 8B) [104]. In addition, a novel nanoarchitecture of Co-MOF@COFCTF-1 was synthesized by directly introducing the as-prepared COFCTF-1 into the Co-MOF synthesis process. This multilayered Co-MOF@COFCTF-1 was used for EIS detection of AMP, one of the most frequently used β-lactam antibiotics, with an ultra-low LOD of 0.217 fg mL−1 [56].
4 COFs in ECL Sensing
A surge of interest in COFs has emerged in the ECL realm, but ECL research on COFs is still in its infancy. The coreactant ECL mechanism describes an electro-triggered luminescence with the assistance of appropriate coreactants, which is the most common route because of its high efficiency and easy implementation. Taking the example of potassium persulfate (K2S2O8), a representative “reduction–oxidation” coreactant for ECL-active COFs, the ECL emitting route is described as the Reactions 1–4. Briefly, S2O82− is electro-reduced to produce the strong oxidant radical intermediate SO4·−. Meanwhile, ECL-active COFs undergo electro-reduction to form COFs·−. As a result, the radiative recombination of SO4·− and COFs·− generates high-energy COFs* to output ECL. To achieve high analytical sensitivity of ECL sensors, developing efficient ECL emitters and designing nanomaterials-based amplification strategies are the two main ways [31, 121,122,123,124,125], both of which can be realized by COFs.
Unlike MOFs with metal nodes that might extinguish the ECL [126,127,128], metal-free COFs seem to be more suitable as ECL luminophores [125, 129]. Likewise, their general properties, such as high specific surface area and porous structure, guarantee high loading capacity and easy mass transport. As such, COFs can be activated with strong ECL emission by constructing intra-reticular charge transfer (IRCT) using non-ECL active monomers [59, 129]. At the same time, the rigid framework can restrict the intramolecular rotations and vibrations of luminogens to achieve aggregation-induced emission (AIE) effects [130]. Additionally, pore confinement and enrichment of COFs are also exploited as reliable substrates for special and sensitive ECL sensing applications [57, 131]. Therefore, COFs show great potential for designing next-generation ECL sensing devices. In this section, the reported COFs used in the ECL field will be discusssed as ECL and non-ECL active ones.
4.1 ECL Active COFs
ECL depends on the charge transfer between luminophores and co-reactive groups or molecules [20, 132]. Thus, designing functional blocks to modulate the charge-transfer behaviors of the long-range ordered COFs can activate effective ECL emission. It is a promising approach to achieve efficient IRCT by integrating electron-donor and acceptor units into a reticular skeleton via topology-templated conjugation. For example, Luo et al. designed a type of donor–acceptor (D–A) COFs with triazine and triphenylamine motifs as strong ECL emitters. A control COF with slight D-A contrast was also prepared by replacing the triazine units with analogous benzene ones. By comparison, the optimal D–A COF regulated by strong IRCT displayed a 123-fold increase in ECL. Experiments and density functional theory (DFT) calculations confirmed that the ECL behaviors were related to the crystallinity and protonation of the COFs, indicating the presence of IRCT between the D–A units. Further, the IRCT-mediated competitive oxidation mechanism afforded the decoding of the dual-peak ECL pattern of this D–A COF [129]. In another work, Qiu’s group reported a general strategy for assembling a series of olefin-linked D–A COFs as ECL emitters. These D–A COFs are composed of two key acceptor subunits of 2,4,6-trimethyl-1,3,5-triazine (TMT) and 2,4,6-trimethylpyridine-3,5-dicarbonitrile (DCTP) with C3v and C2v symmetry, respectively, exhibiting different ECL responses. Through increasing chain length and blocks conjugation, the ECL efficiency was boosted. Further, efficient IRCT allowed robust ECL output without the need for exogenous toxic coreactants [59]. Following this work, the same group also investigated highly aligned D–A COFs with olefin linkages by co-crystallizing four electron-rich molecules (i.e., benzaldehyde,4,4′4″-phosphinidynetris (BAP), 2,4,6-tris(4-formylphenyl)-1,3,5-triazine (TAPT), TFPB, and tris(4-formylphenyl)amine (TFPA)) and two electron-deficient molecules (i.e., TMT and 2,4,6-trimethylbenzene-1,3,5-tricarbonitrile (TBTN)) separately. Among these COFs, a tunable ECL was activated, and COFBAP-TBTN displayed the maximum ECL efficiency (ФECL) of 32.1% in an aqueous solution with the coreactant of dissolved oxygen (O2). Quantum-chemical calculations suggested that the outstanding ECL performance was attributed to the reduced band gap and the good overlap of carriers within the excited COFs (Fig. 9A) [133]. Soon after, this group also regulated IRCT within two other olefin-linked COFs, assembled with an acceptor of TBTN and two donors of 4-[4-[3,5-bis[4-(4-formylphenyl)-phenyl]phenyl]phenyl]benzoic acid (DAFB) and 4-[4-[4-(4-formylphenyl)-N-[4-(4-formylphenyl)phenyl]anilino]phenyl]-benzaldehyde (BCBA), respectively. In a similar manner, the D-A couples-powered IRCT aroused the ECL emitting out of these non-ECL active monomers. With endogenetic O2 as the coreactant, COFTBTN-BCBA achieved prominent ФECL of 63.7% in a water medium, which was further employed for accurate ECL monitoring of UO22+ with a proportionable ECL increase (Fig. 9B) [134]. Following similar design concepts, in addition, this group also synthesized a class of ECL available COFs by conjugating BTT as a key electron donor and three electron receptors of TBTN, DCTP, and TMT via C=C bonding [130].
AIE refers to the fact that a material emits intense luminescence in the aggregated state, but no or weak light in the solution state [135, 136]. Developing AIE emitters is meaningful because ECL luminophores in practical use are usually randomly aggregated on the electrode surface and easily cause ECL quenching [135,136,137]. As it is, the rigid skeleton of COFs can restrict intramolecular vibrations and rotations of the AIE luminogens via intralayer covalent bonds and interlayer non-covalent π-interactions, resulting in reduced nonradiative transitions and the enhanced AIE effects. For example, an AIE unit, 4,4′,4″,4‴-(ethene-1,1,2,2-tetrayl)tetrabenzaldehyde (ETB), was utilized as a key monomer to prepare three olefin-linked COFs. These COFs exhibited predominant framework-induced ECL in aqueous solution, far exceeding those of monomeric aggregated states, because the ordered framework not only promoted efficient charge transfer for an excited-state generation but also reduced the ETB rotation-caused nonradiative loss [138]. Li et al. designed an AIE-COF by a Schiff base reaction between TAPT and 4,4′-diamino-2,2′-bipyridine (DB), appearing to an excellent ECL performance in the presence of H2O2. Further coupled with Co3O4 nanozyme for amplifying the signal, a molecularly imprinted polymer (MIP) ECL biosensor was constructed for antibiotic chloramphenicol testing with a LOD of 0.118 pM [139]. In another work, [(1,3,5-triazine-2,4,6-triyl)tris(benzene-4,1-diyl)]triboronic acid (TTBT) was used to design an AIE-COF material via boric acid dehydration condensation, which was further employed for the construction of a MIP ECL biosensor [140]. Zhang et al. synthesized pyrene-based sp2 carbon-conjugated COF NSs by C=C polycondensation between 2,2′-(1,4-phenylene) diacetonitrile (PDAN) and TFPPy. In this structure, the AIE-luminogens of cyano-substituted phenylenevinylene and the pyrene luminophores were topologically connected together to reduce the aggregation-caused quenching effect. Further using Bu4NPF6 as the coreaction accelerator of the COF NSs/S2O82− ECL system, an ECL genosensor enabled the microRNA-21 detection with a low LOD of 46 aM via three cascaded Exo III-mediated recycling processes for signal amplification [141].
Although COFs have a high assembling capacity for ECL phosphors or motifs, the intrinsic poor conductivity still limits the ECL performance (generally < 10−8 S m−1). To address this issue, Zhang et al. designed a conductive COF with a fully π-conjugated planar structure by connecting HHTP and 2,3,6,7,10,11-hexaaminotriphenylene (HATP) via pyrazine linkages. The splendid ECL emission was achieved as a result of the superior electronic conductivity (3.11 × 10−4 S m−1), the luminophores directly as building blocks, and the porous structure that allows free diffusion of electrolyte. Based on COFHHTP-HATP after prereduction electrolysis in S2O82− solution as an efficient solid-state ECL material, an “off–on” ECL platform was established for sensitive determination of thrombin through aptamer/target proximity binding-mediated 3D bipedal DNA walker for signal amplification [58]. Cui et al. prepared a fully-π conjugated COFDMTP-TCPB with sp2 carbon-linkage via Knoevenagel polycondensation of DMTP and 1,3,5-tris(4-cynomethylphenyl)benzene (TCPB), exhibiting high ECL efficiency for alkaline phosphatase detection [142].
Additionally, various ECL-active COFs are springing up, accompanying their ECL sensing applications. For instance, Yang et al. designed a stable Ru-complex-based metal-COF using a classic ECL luminophore, tris(4,4′-dicarboxylicacid-2,2′-bipyridyl)ruthenium(II) (Ru(dcbpy)32+), as a building motif. Owing to the topologically ordered and porous architectures, this Ru-MOF displayed strong ECL emitting and remarkable chemical stability for the microRNA-155 detection, achieving an ultralow LOD of 3.02 aM [143]. Song et al. demonstrated the synthesis of an aminal-linked COF using the luminescent monomers tetraphenylethylene (TPE) derivative and piperazine, which was further utilized to establish an ECL platform to selectively discriminate enantiomer of phenylalanine [144]. The same group also exploited this aminal-linked COF for glutathione (GSH) ECL assay with a LOD of 17 nM. In this work, target GSH can reduce the quencher of MnO2 NSs into Mn2+, restoring the ECL emission accordingly [145]. Lately, Qiu’s group designed structural isomerism of COFs with different ECL effects, which were further employed for the sensitive toxic As(V) detection with an ultralow LOD of 0.33 nM [146]. This group also constructed a COF-based host–guest system by guest molecular assembly with strong ECL emission and realized the nuclear contamination analysis of UO22+ [147]. Besides, ECL potential tunable COFs are realized by changing the electron and spatial in the precursor, and the generated COF skeleton with reduced potential and increased ECL intensity was used for the selective ECL detection of lutetium ion, showing a LOD as low as 1.6 nM [148].
4.2 Non-ECL Active COFs
In addition to being directly used as ECL emitters, COFs can also be made into microreactors to accumulate luminophores and coreactants, thus boosting ECL efficiency due to the confinement effect. For example, Zeng et al. loaded tris(2,2′-bipyridyl) ruthenium(II) (Ru(bpy)32+) onto COF-LZU1, displaying increased nearly fivefold ECL intensity with a standard of classical Ru(bpy)32+/tripropylamine (TPrA) system. In this work, COF-LZU1 can not only load massive Ru(bpy)32+ but also enrich a large amount of TPrA from the solution via the hydrophobic interaction. Thus, using COF-LZU1 as an ECL microreactor, a confined microenvironment was well created for the redox and survival of coreactants. Through Nt. BbvCI restriction endonuclease-powered DNA walker and T7 exonuclease-mediated target recycling for dual signal amplification, these microreactors were further employed for ultrasensitive ECL detection of aflatoxin M1, showing a low LOD of 0.009 pg mL−1 [131].
Microporous COFs can act as efficient adsorbents for small organic molecules due to the electrostatic, hydrophobic, hydrogen bonding, and π–π interactions [9, 57]. Thus, the presence of COFs can enrich target analytes and improve analytical behaviors. Our group designed a biomimetic hollow organic nanosphere by orderly hybridizing imine-linked COFs with hollow g-C3N4 nanosphere (Fig. 10). On the basis of the quenching effect of tetracycline (Tc) on the g-C3N4/O2 ECL system, these bioinspired nanospheres served as nanoprobes for ultrasensitive detection of Tc, and the LOD achieved a sub-part per billion level of 0.031 μg L−1. Experiments and theoretical derivation demonstrated that COF shells played an important role in enriching Tc, and the target amount is equivalent to being amplified around g-C3N4 accordingly. Besides, the Tc quencher and the coreactant radials traveled and mutually reacted within the narrow and long nanopore channels, ensuring again high quenching effect. Furthermore, a novel ECL technology utilizing the biomimetic self-responsiveness of these nanoprobes realized the evaluation of the photodegradation process [57].
In addition, COFs with high specific surface area and porosity can also serve as excellent electrode matrixes to support catalytic centers in a well-dispersed manner for amplified ECL outputs. For example, a liquid–liquid interface assembly strategy allowed for the polymerization of Zr-coordinated amide porphyrin-based COFs. This Zr-porphyrin-based COF adopted a 2D multilayer structure with high conductivity and electrocatalysis performance toward the luminol/H2O2 ECL system, which was further utilized to construct a novel MIP ECL sensor for Tc detection based on the gate control effect [149]. Li and co-workers exploited COFTAPB-Dva as a carrier to load abundant Au nanoclusters for Pb2+ ECL sensing. In comparison with solid-state aggregated Au nanoclusters, the COF-confined ones displayed a 3.3-fold enhancement in anodic ECL efficiency. As such, the fabricated ECL biosensor obtained sensitive detection of Pb2+ down to 7.9 pM [150]. Ma et al. prepared a carbon dots (CDs)-based COF via the condensation reaction of aldehyde-CDs and TAPB, leading to the regular arrangement of CDs with efficient ECL emission in the presence of K2S2O8 and Bu4NPF6. Further combined with a CRISPR/Cas12a trans-cutting strategy, a high-performance ECL biosensor realized the BPA sensing with a LOD as low as 2.21 fM [151]. Besides, N-(4-aminobutyl)-N-ethylisoluminol (ABEI) was also linked to COF-LZU1 as an ECL emitter for label-free signal-off detection of cytochrome c. This sensor exhibited a wide linear range of 1.00 fg mL−1–0.10 ng mL−1 and a low LOD down to 0.73 fg mL−1 [152].
5 Conclusions and Perspective
This review primarily provides an overview of the state-of-the-art COFs utilized in the field of electroanalytical chemistry, sketching the trajectory from basic characteristics and general synthesis strategies to the resultant sensing usages. The progress of elaborate COFs-based EC sensors is discussed systematically, including ions sensors, chemical sensors, immunosensors, and aptasensors. These COFs-based EC sensors demonstrated superior analytical performance. (1) Until now, imine-linked COFs formed by aminaldehyde condensation remain the most reported COFs for EC sensing applications due to their facile synthesis, high crystallinity, and stability. (2) Their high specific surface area provides a large electrode active area and high loading capacity, and the super-micropores and ordered channels ensure favorable energy/mass transfer. (3) Nano-sized pores and existing heteroatoms can trap guest targets through non-covalent interactions. (4) COFs generally exhibit flexibility, good biocompatibility, low toxicity, and high stability, beneficial for the fabrication of repeatable and reproducible EC sensors. (5) Framework networks designed by π-stacked or extended π-conjugated backbones, for example, that are COFs via pyrazine or olefin linkage, possess acceptable electrical conductivity. (6) Ratiometric EC sensing can be executed for accurate results based on the unique electroactive COFs.
In addition, ECL available COFs and their preliminary sensing applications are summarized in detail. (1) At present, modulating the IRCT behavior of COFs is a common strategy to activate ECL from non-ECL active monomers. (2) AIE-ECL COFs can be facilely achieved because the rigid framework restricts the intramolecular rotations and vibrations of luminogens. (3) Designing COFs with a fully π-conjugated planar structure can improve the conductivity and achieve fast charge injection. (4) The inherent characteristics of non-ECL active COFs make them the right microreactors, strong absorbents, and electrode matrices with high specific surface area, thereby improving the performance of ECL sensors.
Therefore, we believe that COFs are capable of taking a place in the field of electroanalytical chemistry, accompanied by the development of advanced synthetic methods and the disclosure of unique attributes in future work. Despite impressive progress, various obstacles remain to be addressed for the wide applications of COFs in electroanalytical chemistry. First, the solvothermal method still dominates the COFs preparation, but it usually requires tedious synthesis procedures and harsh reaction conditions. Second, COFs composed of non-conductive organic motifs are severely restricted as electroactive substances for EC sensing. The synthesis of highly conductive COFs is still relatively challenging work. Third, due to poor affinity, the assembly of COFs at the interface makes it difficult to achieve high efficiency and reproducibility. Most of the current works focus on the direct use of COFs while ignoring the vital role of modification strategies. Fourth, theoretical prediction of the covalent ordered structure of COFs and their EC behaviors is an arduous task. Lastly, the potential biotoxicity of COFs may affect their further commercial applications.
A few shallow outlooks are only for the reference of readers. In terms of the EC sensing aspect, it is a promising direction to develop conductive COFs with completely π-conjugated planar structures. Assembling COFs-derived composites with particular architecture can also access good conductivity and affinity. Usually, COFs prepared through the traditional solvothermal method exhibit nonuniform bulky morphology, so it is meaningful to develop synthetic strategies for special structures, such as hollow nanostructures mimicking containers, vesicles, and cells. Certainly, developing facile, green, and mild synthetic methods is a must for the large-scale manufacture of COFs-based EC sensors. Pre-functionalized monomers or post-synthetic modifications to exploit the diversity of species and functions of COFs have great potential for future development. Furthermore, most reported COFs possess only micropores, preventing guests (e.g., enzymes, quantum dots) from entering the active cavities or open channels, and creating hierarchical porosity in crystal COFs is highly desired accordingly. In particular, the in-situ interface assembly strategy of COFs awaits further exploration to establish stable and repeatable sensing platforms. In the ECL domain, although some ECL available COFs have been discovered, the ECL research on COFs is still in its initial stage. Future research is suggested to focus on the design of novel COFs emitters, the study of structure-related ECL behaviors, the dependence of their physicochemical properties and electronic structure on the ECL efficiency, the disclosure of underlying ECL reactions occurring in COFs, as well as expanding ECL assays.
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Acknowledgements
This research was supported by Natural Science Foundation of Jiangsu Province (BK20220405), National Natural Science Foundation of China (21834004, 22276100, 22304086), Key Laboratory for Organic Electronics & Information Displays, NJUPT (GZR2022010010, GZR2023010045), Nanjing Science and Technology Innovation Project for Chinese Scholars Studying Abroad (NJKCZYZZ2022-01), Research Fund for Jiangsu Distinguished Professor (RK030STP22001), Natural Science Research Start-up Foundation of Recruiting Talents of NJUPT (NY221006, NY223051), Natural Science Foundation of the Jiangsu Higher Education Institutions of China (23KJB150025), and State Key Laboratory of Analytical Chemistry for Life Science, Nanjing University (SKLACLS2311).
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Cao, Y., Wu, R., Gao, YY. et al. Advances of Electrochemical and Electrochemiluminescent Sensors Based on Covalent Organic Frameworks. Nano-Micro Lett. 16, 37 (2024). https://doi.org/10.1007/s40820-023-01249-5
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DOI: https://doi.org/10.1007/s40820-023-01249-5