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Review

Molecularly Imprinted Polymers for Chemical Sensing: A Tutorial Review

1
CNRS Enzyme and Cell Engineering Laboratory, Université de Technologie de Compiègne, Sorbonne Universités, Rue du Docteur Schweitzer, CS 60319, CEDEX, 60203 Compiègne, France
2
APSYS—An Airbus Company, ZI de Couperigne CTMA Bat B, 13127 Vitrolles, France
*
Authors to whom correspondence should be addressed.
Chemosensors 2021, 9(6), 123; https://doi.org/10.3390/chemosensors9060123
Submission received: 14 April 2021 / Revised: 13 May 2021 / Accepted: 20 May 2021 / Published: 26 May 2021
(This article belongs to the Section Materials for Chemical Sensing)

Abstract

:
The field of molecularly imprinted polymer (MIP)-based chemosensors has been experiencing constant growth for several decades. Since the beginning, their continuous development has been driven by the need for simple devices with optimum selectivity for the detection of various compounds in fields such as medical diagnosis, environmental and industrial monitoring, food and toxicological analysis, and, more recently, the detection of traces of explosives or their precursors. This review presents an overview of the main research efforts made so far for the development of MIP-based chemosensors, critically discusses the pros and cons, and gives perspectives for further developments in this field.

Graphical Abstract

1. Introduction

Molecularly imprinted polymers (MIPs) have seen a continuous development as sensing elements in bio-/chemo-sensors since the late 1990s [1,2,3,4,5,6]. MIPs are attractive not only for their recognition properties that are close to those of natural receptors and their availability for a wide range of targets but also for their superior chemical and physical stability compared to biological receptors. These advantages have led to the application of MIPs in fields as various as immunoassays, separation, depollution, sensing, cell imaging, and therapy [7,8,9]. The imprinting process consists of polymerizing functional and cross-linking monomers in the presence of a template. The removal of the later leaves cavities complementary in shape, size, and chemical functionality, therefore allowing for the template to rebind specifically.
According to the International Union of Pure and Applied Chemistry (IUPAC), a chemical sensor is “a device that transforms chemical information, ranging from the concentration of a specific sample component to total composition analysis, into an analytically useful signal. The chemical information, mentioned above, may originate from a chemical reaction of the analyte or from a physical property of the system investigated” [10]. Therefore, a suitable sensor has to fulfil specific criteria such as high sensitivity and selectivity, stability, low sample consumption, reliability, and reproducibility. Overall, an ideal sensor should also be inexpensive, portable, foolproof, able to instantaneously respond to the analyte of interest in any desired medium, and capable of generating a measurable signal in the required concentration range. Unfortunately, current sensors are far from being “ideal”, and chemical sensors in particular are generally narrowly optimized for a given application [11,12].
As mentioned above, a chemical sensor consists of two main elements (see Scheme 1): the chemical recognition element, called the receptor, and a physico-chemical transducer. The receptor transforms the binding event of the target into a form of energy that can be measured by the transducer. For chemical sensors, this binding event involves chemical species and the generation of a signal upon the change of a physico-chemical parameter (e.g., the formation/breaking of a bond, exchange of electrons, and mass change or refractive index modification). Subsequently, the transducer transforms the chemical information received from the receptor into a useful analytical signal. The transduction process can be based on several physical phenomena, such as optical or thermal changes, electrochemical reactions, and mass variations.
As a recent trend, the miniaturization of sensors and their readout deserves a special attention due to the increasing number of applications available for smartphones [13,14,15,16,17]. From a general point of view, receptor design is perhaps the crucial step in the process of sensor development because it has to match the requirements of high selectivity and sensitivity for a target with the particular characteristics of a given readout. Thus, the straightforward engineering, fine-tuning, and easiness of integration into the standard industrial process of MIPs makes them ideal candidates for recognition elements.
In this review, we describe the current state of the research field on MIP-based electrochemical, mass-sensitive, and optical sensors, and we highlight their advantages and shortcomings. The last section discusses aspects related to chemical interfacing in the design of MIP-based chemosensors. Reviews from 2020 and 2021 already described various characteristics related to MIP synthesis and the readout mode of MIP-based potentiometric sensors for the detection of organic and biological species [18], the advantages of nanomaterial-based MIPs for pesticides sensing [19], and the strength/weakness ratio for potentiometric sensors in general [20], which are not tackled in this work.

2. Electrochemical MIP Sensors

Electrochemical sensors represent one of the most successfully applied MIP-based sensors [21,22,23,24,25]. Electrochemical sensors are defined as devices wherein a sensing layer is coupled to an electrochemical transducer [26]. Depending on the electrical phenomenon used for transducing the binding event, different families of electrochemical sensors can be distinguished: potentiometric (sensing a change in the membrane potential), conductometric (conductance variation), impedimetric (impedance fluctuation), and voltammetric or amperometric (overall current variation induced either by an electrochemical reaction upon a voltage switch or a time-dependent evolution over a constant potential, respectively) [27].
In the early 1990s, Mosbach and coworkers reported the first use of MIPs for the capacitive [28] or amperometric [21] detection of L-phenylalanine and morphine. Already in these early works, it became clear that the different transduction methods dictated the requirements for the suitable interfacing of the MIP. A major drawback of the most commonly used (meth)acrylate-based MIPs was their nonconductive nature; therefore, they were combined with electrically conductive polymers that remarkably improved the transduction [22]. Many valuable reviews have covered the wide range of applications of electrochemical MIP sensors [27,29,30,31], and they are therefore not discussed in detail here.
Electrochemical devices are classified depending on the reaction under study (amperometric, potentiometric and conductometric sensors) or depending on the detection technique (impedimetric or field-effect sensors) [32]. As a result, the reaction generates different types of signals: (i) a measurable current for amperometric sensors, (ii) a measurable potential or charge accumulation for potentiometric sensors, and (iii) a measurable alteration of the conductive properties for conductometric sensors. Impedimetric sensors measure the impedance based on both resistance and reactance effects [33], whereas field-effect devices quantify the current induced by a potentiometric effect at a gate electrode in a transistor [26].

2.1. Potentiometric Sensors

Among the different chemical sensors, potentiometric sensors are the most popular due to their low cost and easy handling. This type of sensor works in the near-zero current flow, measuring the difference in potential between a working electrode (WE) and a reference electrode (RE), which generates an analytical signal. Ion selective electrodes (ISEs), which use a permselective membrane able to produce a potential in contact with solutions of a given analyte, are a prominent example of this class of transducers. The most known examples are glass electrodes for pH measurements. The membrane, which consists of a lipophilic-complexing agent that selectively binds the analyte of interest, is the key component.
When moving to MIP-based systems, potentiometric sensors represent a well-established class. For these sensors, low conductivity, hydrophobicity, and high selectivity are all requirements that (meth)acrylate-MIPs fit perfectly. Two different kinds of potentiometric sensors can be distinguished. The first comprises faradaic coupled devices (with a conventional inner-reference ISE; see Figure 1a) and capacitive coupled devices (with solid inner contacts, coated wire ISE; see Figure 1b), and the second comprises an ion-sensitive field-effect transistors (ISFETs).
The classical setup is a faradaic coupled device in which the permselective membrane separates two compartments with solutions of different activity for a given ion (the sample and the internal electrolyte solution). Approaches similar to those of conventional ISEs are used to incorporate MIPs into the membranes as selective ionophores by embedding imprinted particles into a polymer matrix, typically polyvinylchloride (PVC). These have been referred to as “imprinted polymer inclusion membranes” [34]. Such membranes have been reported for the detection of dysprosium (III) and other lanthanides [35], as well as for the pesticide atrazine [36] and melamine in milk [22]. Their response greatly depends on how the membrane is tailored, e.g., the presence of ionic additives and the type and amount of the added plasticizer and MIP.
In addition to faradaic potentiometric sensors, capacitive sensors are also well-established. In contrast to the former, capacitive sensors do not use an inner solution, as the ion-selective membrane is directly in contact with a solid phase and the sample. The solid contact consists of conductors, semi-conductors, or insulators. This type of sensor can be further split into two subgroups, with either the membrane parallel to the coated wire electrodes or with a field-effect transistor device. For the development of solid-contact potentiometric sensors, conductive polymers are a clear advantage. A polymer coating is usually achieved by either the electropolymerization of MIPs (e.g., polypyrrole) or by the drop-casting of pre-synthesized acrylic MIPs embedded in plasticized PVC matrixes (as described before) on noble metals (such as Pt and Au) or carbon material (such as glassy carbon and graphite) for coated wire electrodes. The capacitive readout is based on the ionic charge-transfer occurring on the membrane in the presence of an analyte. Such coated electrodes have been used for sensing various compounds: nitrates [37], pesticides [38], antibiotics [39], and β-blockers [40]. Table 1 summarizes the type of MIP, the analyte, the limit of detection (LOD), and, when available, the response time and stability of the sensors for the detection of these analytes. Another important way to obtain a selective electrode is by mixing a MIP-based membrane with carbon paste (e.g., graphite powder) [41] or relying on self-assembled monolayers (SAMs) [42]. For the second subgroup, ion-sensitive field-effect transistors are the most common examples. In this case, the ion-selective membrane is deposited onto the input dielectric of the field-effect transistor. Examples of target analytes for these are chloroaromatic acids [43], nucleotides and various acids [44,45], thiophenols [45], and NAD(P)+/NAD(P)H cofactors [46] (see Table 1). The development of such potentiometric sensors led to the fabrication of a platform consisting of the sensor and the readout circuit in one device called a microelectromechanical system (MEMS) [47], which is particularly interesting for the miniaturization and, thus, for mass-production of commercial sensing devices. An emerging field in the development of MIP-based potentiometric sensors is the replacement of expensive gold or glassy carbon electrode substrates by commercially-available, low-cost chromatography paper [48]. The paper sensor selective for bisphenol A showed a comparable analytical performance to a classical glassy carbon-based sensor. The detection limit was 0.15 µM (see Table 1), with good selectivity over other phenols.

2.2. Conductometric and Impedimetric Sensors

Conductometric and impedimetric sensors were also adapted to include MIPs as a recognition layer, which also ensures the selectivity. Conductometric sensors are based on a time-dependent change in conductivity triggered by the binding event and are less popular than potentiometric ones. In their design, two main setups can be distinguished. The first approach was reported by Mosbach et al. [65]. In their work, a membrane selective for benzyltriphenylphosphonium ions was pressing the bare polymer particles onto a polished surface connected to two Pt-wires and fixed on a filter paper. An alternative approach was proposed by Piletsky et al. [54], where a MIP membrane was placed between two Pt-electrodes in a conventional electrochemical cell with separated compartments. Since conductometric devices are in general poorly selective, especially in buffers due to the high ionic strength, reference NIP (non-imprinted polymers)-based sensors are always needed. This type of device can be upgraded by using interdigitated electrodes, which allow for a more reliable comparison between MIPs and NIPs [55].
Impedimetric sensors are based on the measurement of an alternated current generated by the binding interaction towards the selective membrane compared to the applied alternating current on the system. The measurement relies on the change of the total electrical resistance and reactance to the flow of the applied current through the given medium. Depending on the sensing principle, impedimetric sensors can be classified into two major subclasses: resistive and capacitive [66]. Capacitive sensors are nowadays widely used, especially those that provide a near-ideal capacitor behavior, with a phase angle close to 90°. To fulfill this condition, the imprinted polymer layer has to be electrically insulated and the binding event has to take place very close to the transducer. The insulation condition can be easily achieved with (meth)acrylic MIPs. For the second condition, thin films are preferred because they provide better performance than thick films. Indeed, thin films concentrate all the available binding sites close to the transducer and thus improve the sensitivity. It has also been reported that electropolymerized thin layers (around 10–50 nm) do not usually provide a convenient insulation because of the presence of local defects in the polymer matrix. Hence, special treatments with “blocking agents” such as alkanethiols for gold transducers have been shown to conveniently enhance insulation, thus improving sensor performance [33]. A wide variety of molecules have been detected using impedimetric sensors: phenylalanine [33], nicotine [25], glucose [49], theophylline [50], melamine [62], resorcinol [51], imidacloprid [52], and amphetamine [53] (see Table 1 for the characteristics of these sensors).
MIP interfacing with a transducer can be made either with SAMs [67], as previously mentioned, or by grafting photopolymerization [68]. The trend of miniaturization and mass production led to the development of interdigitated capacitance sensors, e.g., for amino acids [69] and protein allergens [70].

2.3. Voltametric and Amperometric Sensors

The last type of electrochemical sensors that we describe in this tutorial review is represented by voltammetric and amperometric sensors, which are currently extensively used. The measured signal corresponds to the current flow as primary transduction phenomenon, so these sensors are considered to be faradaic coupled devices. A potential is applied between the sensor and a reference electrode in a three-electrode setup. The flow through the counter electrode and the sensor is continuously measured to produce an analytical signal. Electroactive targets are required for both types of sensors. Non-electroactive analytes can nevertheless be detected, but an electroactive probe such as ferro-ferricyanide is required in that case. The detection requires the analyte to diffuse close enough to the transducer in order to undergo an electron transfer. Since there is no physical contact between the analyte and the transducer, the electron transfer has to be mediated by the sensing element, and conductive MIPs are particularly suited for such sensors.
The correct integration of MIPs into an electrode is crucial, and various strategies, such as embedding nanoparticles into polymer matrixes, deposition by sol–gel chemistry, and mixing with graphite as a paste to form electrodes, have been explored. Electropolymerized films have been used to embed particles into electrodes. The direct grafting or electropolymerization onto an electrode also represents a convenient approach. To increase conductivity and obtain a better signal, graphite powder [33] and nanoparticles [71,72,73] have been included in these sensors. Morphine [21,56], ephedrine [57], paracetamol [58], dopamine [59,71], homovanillic acid [74], atrazine [60], creatinine [61], cholestanol [64], triacetone triperoxide [24], 2,4,6-trinitrotoluene, and 1,3,5-trinitroperhydro-1,3,5-triazine explosives [63] (see Table 1 for the characteristics of these sensors) are representative analytes. The analytic results obtained for the detection of creatinine using a MIP-based sensor showed comparable precision and accuracy with results obtained by HPLC [61]. We should note that voltammetry is the most selective electrochemical technique because it can specifically detect the analyte thanks to its intrinsic properties such as specific oxidation and reduction peaks. Kröger et al. developed one of the first imprinted polymer-based sensor using screen-printed electrodes and differential pulse voltammetry [75]. Several types of voltammetric sensors can be distinguished based on the shape of their applied potential function. The most commonly used are linear sweep voltammetry and cyclic voltammetry sensors. The applied potential shape varies either linearly with time (for linear sweep voltammetry and cyclic voltametry) or as constant increments on a linear ramp (for differential pulse voltammetry) or as square wave function (for square wave voltammetry), respectively. These techniques generally improve the signal-to-noise ratio and therefore the sensitivity.

3. Mass-Sensitive Sensors

All sensors that generate their signal thanks to a mass change leading to a measurable, reliable, and analytical frequency response are considered mass-sensitive sensors. The piezoelectric effect, discovered in 1880 by Pierre and Jacques Curie brothers [76], is the basis of all mass-sensitive devices. Examples of such sensors for MIPs include, as mentioned above, MEMS alone [47] or MEMS combined with cantilevers [77], as well as extensively used piezoelectric sensors such as quartz crystal microbalance (QCM) or surface acoustic wave (SAW) sensors, which are described in the following subsections.

3.1. QCM Sensors

One of the most used mass-sensitive sensors in the MIP community are QCM sensors. Their signal is generated by a decrease of the oscillation frequency of a piezoelectric crystal upon the recognition of the template by the MIP. The change in frequency is herein proportional to the square of the fundamental resonance frequency mode and can be used for quantitative readouts according to the Sauerbrey equation. A scheme of a QCM chip and the corresponding sensogram are shown in Scheme 2a. QCM sensors have been widely used for the detection of steroid hormones such as nandrolone [78] and neurotransmitters such as catecholamines [79], as well as for other analytes like the β-blocking drug (S)-propranolol [80], caffeine [81], trichlorfon [82], α-amanitin [83], N-hexanoyl-L-homoserine lactone [84], and L-tryptophan [85]. The experimental characteristics of the sensors detecting these analytes are summarized in Table 2. Molecularly imprinted films on top of a QCM can be made using the drop-casting by embedding the preformed MIP nanoparticles (NPs) into a polymer matrix [78,79], covalent immobilizing via coupling reactions [84], in situ polymerizing [80], or imprinting onto preformed polymers [81,82].

3.2. SAW Sensors

SAW sensors represent another example of mass-sensitive readouts (see Scheme 2b). They are made of one or more comb-like interdigitated electrodes and rely on the propagation of mechanical vibrations on a piezoelectric surface material. In practice, like for Rayleigh waves, the effect of the surface acoustic waves is produced by an electric signal at resonance frequency [92]. Quantitative measurements are obtained by adding a sensitive layer on top, which produces an alternating voltage. These sensors are used for the detection of various analytes ranging from proteins [88] to small molecules [87]. Recent applications include the detection of biomarkers for early stage diagnosis and/or therapy monitoring (notably in neurodegenerative diseases) [91], antibiotics [89], and herbicides [90] (see Table 2 for the MIPs used and the experimental characteristics of the sensors). The simplicity of handling, real-time detection, and good sensitivity are the main advantages of SAW sensors. Despite their complicated electronics circuits, which remain a primary limitation, their relatively low cost has rendered the SAW sensors more and more compatible with an industrial-scale production [93].

4. Optical Sensors

Optical sensors are extensively used in various fields such as biotechnology, environmental monitoring, pharmaceuticals, and clinical analysis. In luminescent optical sensors, the detection method relies on the conversion of a binding event into a measurable light thanks to fluorescence, chemiluminescence, or colorimetric changes; these light signal changes lead to highly sensitive, flexible, and inexpensive sensors. The signal transduction can occur in three different ways:
(a)
The inherent optical activity of the target.
(b)
The incorporation of a fluorophore or a chromophore into the polymer matrix, which can result either in the quenching or in the enhancement of fluorescence.
(c)
A signal generated upon a catalytic reaction, leading to spectroscopically active species.
The following subsections describe the different types of readouts used for optical MIP sensors: UV/Vis absorption, fluorescence, surface plasmon resonance (SPR), localized SPR (LSPR), surface-enhanced Raman scattering (SERS), surface-enhanced Raman resonance scattering (SERRS), reflectometric interference, and colorimetric.

4.1. UV/Vis and Fluorescence Readout

UV/Vis absorption is one of the simplest readouts based on a change in the absorption spectrum of the sensing element induced by the analyte [94]. The response is quick and provides a quantitative information on the binding itself, but the technique suffers from low sensitivity. Nevertheless, if the analyte shows a specific absorption peak in the monitored region, this technique provides a further level of accuracy and could overall enhance the selectivity of the sensor. Examples include the chemical grafting of MIPs onto the surface of polystyrene microplates for rapid binding assays [95] or in combination with solid-phase extraction, as one of the most common uses, for example for the detection of propranolol in biological fluids [96].
Sensitivity can be increased by combining the imprinted polymers with different nanostructures like quantum dots, which modify their luminescent properties upon a physical or chemical interaction (i.e., binding event) occurring close enough to their surface [97,98]. High sensitivity, selectivity, and low detection limits can be achieved when fluorescence readouts are used for optical MIP sensors [99,100]. A fluorescent readout can be easily coupled with optical waveguides [101] and is compatible with a variety of fluorescent probes like quantum dots [97,102], upconverting particles (UCP) [103], and fluorescent derivatives [104] (see Table 3 for the detected analytes and the experimental characteristics of the sensors). In the case of clenbuterol analyte, the accuracy of fluorescence detection was validated by comparative analysis with other methods [103]. When non-fluorescent analytes are targeted, fluorescence quenching or enhancement can be achieved upon the addition of fluorescent materials or dyes such as fluorescent functional monomers [105,106] into the polymer matrix. Several types of analytes have been detected by optical MIP sensors with fluorescent readouts: small or organic molecules (caffeine [107], cocaine [108]), proteins [109], and inorganic ions(Al (III) [110] or Ag (I) [105]).

4.2. SPR Readout

Transducers based on SPR use the change in thickness and the refractive index of thin films coupled to metal surfaces to generate an analytical signal upon binding. The metal surfaces supporting surface plasmons are typically gold and silver, but copper, titanium, and chromium are suitable alternatives. Surface plasmons represent an optical excitation effect based on the theory of attenuated total reflection originally developed by Kretschmann and Raether [123] and Otto [124] that is widely used in sensors. Polarized light is hereby applied onto a prism covered with a thin layer of metal, such as gold, which generates a surface plasmon. After interfacing the MIP with the transducer, the analyte binding to the MIP leads to an incidence angle shift that is concentration-dependent (see Scheme 3a) because the analyte binding changes the refractive index of the MIP layer. Surface integration is achieved upon the coupling of presynthesized MIP using thiols [113], by the in situ polymerization of thin films [114,115] (see Table 3 for the detected analytes and the experimental characteristics of the sensors), or by electropolymerization.
Since conductive compounds propagate the plasmonic wave and increase sensitivity [126,127,128], metallic nanoparticles such as Au-NPs and Au-nanostars are often embedded into MIP matrices. For more information on these devices, one can refer to the minireview of Lépinay et al. covering the years 2010–2011 [129] or the recent review by Malik et al. [130]. SPR sensors have been successfully used for the detection of a wide range of molecules from proteins to small molecules like explosives; therefore, sensing techniques based on SPR sensors are relatively common. Recently, fiber optic SPR techniques using molecularly imprinted polymers for the detection of perfluorinated compounds in water have also been reported [112].

4.3. LSPR Readout

LSPR is an optical phenomenon produced by the collective oscillation of valence electrons and the following absorption of the incident photons in the UV/Vis band (conduction band) of a noble metal nanostructure (see Scheme 3b). The technique was extensively reviewed by Hammond and coworkers, who illustrated its applications in material science and biosensing [125]. Possible metal surfaces are palladium (Pd), platinum (Pt), gold (Au), and silver (Ag). The sensing signal is based on the refractive index change near their surface. The readout can be based on UV–Vis spectroscopy by monitoring a wavelength-shift of the collective oscillation due to changes of the refractive index during the binding event. For example, it has been shown [131] that the intense color of an aqueous gold nanoparticles solution is an expression of the LSPR phenomenon. Matsui et al. [116] proposed the colorimetric detection of adrenaline by a MIP using acrylic acid as a functional monomer. Gold nanoparticles were embedded into the polymer matrix. The plasmon absorption band at 522 nm in water was shifted down to 511 nm in the presence of 1 mM adrenaline due to the increased average distance between NPs following the template uptake. The blue shift was shown to be concentration dependent and allowed for the measurement of concentrations as low as 5 µM. “Supra-particles” consisting of MIP nanoparticles (MIP-NPs) and template-functionalized gold nanoparticles (template-Au-NPs) were instead used by Takeuchi’s group to measure bisphenol A (BPA) in ethyl acetate [117] (see Table 3 for the detected analytes and the experimental characteristics of the LSPR sensors). In their elegant approach, MIP-NPs and BPA-surface coated Au-NPs were allowed to spontaneously assemble thanks to the MIP–BPA affinity. Incubation with increasing concentrations of free BPA resulted in the progressive disassembly of supra-particles due to the competitive binding with MIP-NPs. Such disassembly could be easily tracked by measuring the changes in the plasmon peak.

4.4. SERS and SERRS Readouts

Another readout method is the observation of enhanced electromagnetic fields generated by a nanostructured surface, such as those of SERS and SERRS, and monitoring the changes in these enhanced fields during binding events [125]. SERS and SERRS readouts can be used in two ways: in conjunction with LSPR, as mentioned above, or by using the specific vibrational spectrum of Raman active molecules. SERS/SERRS is one of the latest integrated transduction methods into MIP-based sensors. SERS is a surface-sensitive technique based on the enhancement of Raman scattering during the binding event promoted by the coupling between the incident laser and localized surface plasmons on rough metal structures or nanostructures. The mechanism is not yet fully understood, so two options have been discussed in the literature: an electromagnetic theory related to the LSPR phenomenon around the NPs and a charge-transfer complex due to a chemical bond formation between the analyte and the metal structure that would increase its polarizability [118]. The SERRS phenomenon appears when the laser is close to a metal NP’s surface, resulting in hotspots on the surface and consequently the production of a clear signal that varies with the laser position relative to the nanoparticle [132]. Our group successfully detected the drug propranolol by micro-Raman spectroscopy on single MIP microspheres [133]. Rather low limits of detection have been reached on single MIP particles (100 × 10−6 M) and single MIP microspheres (1 × 10−6 M). The limit of detection was improved by three orders of magnitude when SERS measurements were performed on single Au-MIP composites particles, where the analyte could even be detected in diluted equine serum [118]. Compared to fluorescence-based sensors, SPR and SERS sensors show limits of detection in the femtomolar range [111,119], which is around five orders of magnitude lower than fluorescence. Additionally, Raman spectroscopy allows for the measurement of the specific vibrational spectrum of a molecule (i.e., its fingerprint), thus contributing to its identification. SERS sensors can be enhanced by using composite particles with gold colloids, which behave as nano-antennae forming hot spots [118,128].

4.5. Reflectometric Interference Readout

Reflectometric interference spectroscopic sensors are used in fiber optical or planar waveguide setups by recording the interference occurring between two beams propagating through different optical paths in a single or two different fibers/waveguides (beam split and beam combining) [120,134]. In such devices, molecularly imprinted polymers have been used as a recognition layer and were either embedded as nanoparticles in films or directly synthesized as a film on the surface. The transducer system is based on a multi-layer design consisting of a silica (glass) layer followed by a high-refractive Ta2O5 layer and an additional silica layer that can be chemically modified. Belmont et al. [120] used this type of sensor for the detection of atrazine pesticide in toluene (see Table 3 for the experimental characteristics of the sensor). The MIP layer was created by spin-coating of the precursors followed by in situ polymerization, as well as by the auto-assembly of MIP nanoparticles using an associative linear polymer as the matrix.

4.6. Colorimetric Readout

In addition to classical optical sensors, there are devices based on structural colored materials such as holograms and photonic crystals. In 2012, Liu et al. [121] proposed a molecularly imprinted photonic crystal against the degradation products of nerve agents (organophosphorus compounds). They used polymethyl methacrylate colloid particles for the preparation of a packed colloidal crystal array embedded in an imprinted hydrogel. The analyte was detected by diffraction. Silver-halide reflection holograms represent another example of structural-based optical transducers. The optochemical sensor was fabricated by inscribing a hologram inside a molecularly imprinted polymer film made of acrylates [122]. Upon testosterone binding, a wavelength shift of the reflection peak was measured and translated into an analytical signal. Regarding the MIP-based transmission holographic sensors, the response time upon template binding is rather long, since 8 h of incubation are necessary to well-discriminate the imprinted from the non-imprinted-based sensor. Similar results were obtained for template (S)-propranolol.

5. Interfacing

The interfacing of a MIP onto a transducer is one of the most crucial steps for sensor preparation. As mentioned before, this depends on the sensor surface and the chosen readout. MIPs are normally interfaced based on two different physical forms: (1) thin films and (2) pre-synthesized microparticles/nanoparticles. Micro or nanoparticles can be interfaced in several ways: embedded into polymer matrices [34] with core-shell designs and covalent linkage to the surface [135] or drop-casting [136], spin-coating [137], and spray-coating directly onto the surface [138].
For electrochemical sensors, particles are often embedded into membranes or polymer matrices. As mentioned before, a commonly used polymer matrix is polyvinyl chloride (PVC), especially for ISEs [34] as membranes, but it is also possible to spin-coat a thin non-conductive layer of PVC onto a transducer [78]. Gels are an alternative to embed powders into polymer matrixes, such as with herbicides [75] or morphine [139]. Another possibility is to add MIP particles into a prepolymerization mixture of electropolymerizable monomers and then carry out the polymerization directly on the sensor surface [56]. Electropolymerizable monomers include dopamine, pyrrole, thiophene, and 4-aminthiophenol. For the embedding into a polymer matrix, an adhesive layer can also be deposed by spin-coating onto the transducer surface, and the particles can be entrapped by stamping using a polydimethylsiloxane (PDMS) stamp. Subsequently, heat is applied, and the particles sink into the adhesive layer [140]. If necessary, the polymer layer can be tailored to be conductive to enhance the signal. For electrochemical sensors, mixing with graphene powder or carbon paste was shown to be a suitable way to increase the conductivity of (meth)acrylic MIP powders [41]. The particles are mixed with a conducting material (e.g., carbon nanotubes, graphene, graphite, or carbon black) and a binder (e.g., paraffin or PVC) to yield a paste, and then they are formed into electrodes for use. Alternatively to the above physical means, a covalent coupling to the sensor surface can also be carried out. This method is often used on gold surfaces due to their easy reaction with thiols [141] or on silica after silanization [135,142] that provides amino, epoxy, or even carboxy groups on the chips depending on the chosen silane. These groups can easily be coupled with nanoparticles carrying either amino- or carboxy-groups on their surface, which are obtained by including specific functional monomers directly into the polymerization medium or by creating a functionalized shell around presynthesized MIP particles. However, the main drawback of this technique is the often incomplete surface coverage. Thus, deactivation and blocking steps are necessary to avoid any unspecific reading from the uncoated spots, which makes this approach less convenient than the direct deposition of continuous thin films. In addition, reproducibility is limited because the number of particles per chip and, hence, the overall sensitivity can vary.
As previously stated, thin films can be obtained by free radical polymerization [129] or electropolymerization of monomers deposited by drop-casting, spin-coating, or through self-assembled monolayers (SAMs) [67]. In 2013, a review about signal enhancement on thin films using different interfacing techniques was published by Kutner’s group [143], who presented the advantages of interfacing homogeneous layers rather than discrete particles.
The most applied MIPs are based on poly(meth)acrylates, which can be grafted onto the surface in order to create thin films by either thermal- or photo-initiated polymerization, the last being the most commonly used and easiest to handle. In both cases, a covalent immobilization of the initiator (surface initiation) or of a monomer [144] is necessary. In some cases, the thickness of the layer can be tuned by just varying the polymerization time if controlled polymerization techniques are used (i.e., reversible-deactivation radical polymerizations). Another way to use photo-polymerization, the top–down approach, is to spread a pre-polymerization mixture containing a photo-initiator via spin-coating [137] or drop-casting without rotation [136] onto a transducer. Spin-coating and drop-casting also apply to imprinted films via sol–gel chemistry. As such, dip-coating and spray-coating can be found in the literature for the formation of MIP films on electrodes and optical fibers. As mentioned above, SAMs [42] can be used for transducer modification.
The last interfacing method is the direct polymerization on electrochemical transducers via electropolymerization in the presence of a template. The resulting polymers can be either conductive or non-conductive. The morphology and thickness can be easily tuned by the selection of suitable solvents, electrolytes, and the number of deposition cycles (in general, cyclic voltammetry is used for the deposition). The only limitation of the technique comes from the restricted panel of electropolymerizable monomers (e.g., 3-aminophenylboronic acid, thiophenes, aniline, phenol, 1,2-phenylenediamine, 2-aminothiophenol/4-aminothiophenol, pyrrole, and dopamine [25,58,145,146,147]) and therefore the number of functional groups capable to stabilize the template.

6. Conclusions and Future Prospects

Over the past few decades, MIPs have gained a prominent role as sensing components in the design of chemosensors, notably to obtain an improved selectivity. The ability to design chemosensors capable of detecting various analytes explains their wide range of applications, which include medical diagnosis, environmental and industrial monitoring, toxicological analysis, and the detection of explosives and chemical warfare agents. In the future, the requirements imposed by the use of MIP-based chemosensors in medical or industrial applications will become even more stringent in terms of selectivity, sensitivity, miniaturization, and simplicity of use. Such applications are expected to continuously stimulate the development of MIP-based (chemo)sensors.
In this review, we provided an overview of the various chemosensing devices based on the use of MIPs together with interfacing approaches and applications. Despite the significant progress already achieved in this field, further innovations are expected to come from the development of new transduction elements or the improvement of current ones, especially in terms of sensitivity. Similarly, improvements are also expected on the MIP side, not only with the introduction of new interfacing strategies but also with MIPs capable of responding to external stimuli like pH, light, or temperature and new MIP design methods able to precisely control their thickness and their organization into predefined patterns (i.e., micro- and nano-structuring of MIPs). This particular approach is regarded as a way of simultaneously turning a MIP into a sensing element and a transducer. Therefore, similarly to optical chemosensors based on imprinted photonic crystals, the polymer structure will be in charge of both target recognition and signal generation.
All these improvements are expected to lead to the detection of an even broader range of analytes, as well as to the development of more compact, more stable chemosensors and perhaps at much lower costs, in order to render them accessible to underdeveloped countries, notably for their use in environmental and healthcare monitoring applications. Paper-based sensors are an example of such economic MIP-based chemosensors.

Author Contributions

Writing—original draft preparation, N.L., L.D., and C.G.; writing—review and editing, L.D., C.G. and K.H.; visualization, N.L. and L.D.; supervision, L.D. and C.G.; project administration and funding acquisition, K.H. All authors have read and agreed to the published version of the manuscript.

Funding

This work was financially supported by the European Commission (project NOSY for New Operational Sensing systems, Grant agreement ID 653839, H2020-EU.3.7).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Acknowledgments

CNRS and University of Technology of Compiègne are acknowledged for administrative and technical support.

Conflicts of Interest

The authors declare no conflict of interest.

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Scheme 1. Scheme of a chemical sensor consisting of a recognition layer, an interface, a transducer, and a signal detection element.
Scheme 1. Scheme of a chemical sensor consisting of a recognition layer, an interface, a transducer, and a signal detection element.
Chemosensors 09 00123 sch001
Figure 1. Typical setup for potentiometric measurements: with either an inner-reference ion-selective electrode (ISE) (a) or coated wire ISE (b) and a reference electrode (RE). Reprinted with permission from [27].
Figure 1. Typical setup for potentiometric measurements: with either an inner-reference ion-selective electrode (ISE) (a) or coated wire ISE (b) and a reference electrode (RE). Reprinted with permission from [27].
Chemosensors 09 00123 g001
Scheme 2. (a) Scheme of a quartz crystal microbalance (QCM) chip coated with a MIP film (left) and a typical QCM response (right) for a MIP thin film (red), as well as the non-imprinted polymer (yellow) at different vapor concentrations of formaldehyde (in blue on the top of the graph). The difference between the red and yellow curves is attributed to the mass effects induced by the incorporation of the analyte into the recognition sites of the polymer film. The time-phase evolution corresponds to the change in formaldehyde concentration. Response graph taken with permission from [86]. (b) Scheme of a surface acoustic wave (SAW) sensor.
Scheme 2. (a) Scheme of a quartz crystal microbalance (QCM) chip coated with a MIP film (left) and a typical QCM response (right) for a MIP thin film (red), as well as the non-imprinted polymer (yellow) at different vapor concentrations of formaldehyde (in blue on the top of the graph). The difference between the red and yellow curves is attributed to the mass effects induced by the incorporation of the analyte into the recognition sites of the polymer film. The time-phase evolution corresponds to the change in formaldehyde concentration. Response graph taken with permission from [86]. (b) Scheme of a surface acoustic wave (SAW) sensor.
Chemosensors 09 00123 sch002
Scheme 3. (a) Scheme of a surface plasmon resonance sensor setup (left). Polarized light is applied onto a prism covered with a thin layer of metal, such as gold, which generates a surface plasmon. Analyte binding events induce changes on the surface and consequently a resonance angle shift (right, top) that can be transformed into a sensogram either directly or by the intensity change at a fixed angle (right, bottom graph). (b) Scheme of localized surface plasmon resonance (LSPR), where the free conduction electrons of the metal nanoparticle oscillate due to their strong coupling with the incident light. Adapted with permission from [125]. The electromagnetic field decay length in LSPR is around 6 nm compared to 200 nm in SPR.
Scheme 3. (a) Scheme of a surface plasmon resonance sensor setup (left). Polarized light is applied onto a prism covered with a thin layer of metal, such as gold, which generates a surface plasmon. Analyte binding events induce changes on the surface and consequently a resonance angle shift (right, top) that can be transformed into a sensogram either directly or by the intensity change at a fixed angle (right, bottom graph). (b) Scheme of localized surface plasmon resonance (LSPR), where the free conduction electrons of the metal nanoparticle oscillate due to their strong coupling with the incident light. Adapted with permission from [125]. The electromagnetic field decay length in LSPR is around 6 nm compared to 200 nm in SPR.
Chemosensors 09 00123 sch003
Table 1. MIP-based electrochemical sensors.
Table 1. MIP-based electrochemical sensors.
TransducerReceptorAnalyteLOD (mol/L)Response Time (s)Stability (Weeks)Ref
PotentiometricMIPsNitrates0.2 × 10−624-[37]
MIPs into membranesDy(III)2 × 10−610-[35]
Atrazine0.5 × 10−6120-[36]
Melamine5 × 10−616-[22]
NAD(P)+/NAD(P)H2 × 10−7604[46]
Thiophenols2 × 10−6452[45]
MIP-covered electrodeAmoxicillin0.3 × 10−620-[39]
Metoprolol1.3 × 10−714-[40]
MIP TiO2 thin filmsAcids5 × 10−4300-[43]
5 × 10−5300-[44]
AMP 1
GMP
CMP
1.5 × 10−5
1.5 × 10−5
8 × 10−7
60-[44]
ImpedimetricMIP layer on Au electrodePhenylalanine3 × 10−3900-[33]
Glucose50 × 10−6-<1[49]
MIP filmNicotine0.5 × 10−660012[25]
MIP filmTheophylline1 × 10−6600-[50]
MIP on Au electrodeResorcinol0.1 × 10−6-5[51]
MIP particles on Au electrodeImidacloprid4.61 × 10−6--[52]
Multiplex MIP on gold electrodesAMP 2
NFA 3
BMK 4
50 × 10−6
20 × 10−6
20 × 10−6
--[53]
ConductometricMIPs into membranesAtrazine0.5 × 10−6180016[54]
MIPsHaloacetic acids3 × 10−93012[55]
VoltametricMIP NPsMorphine0.3 × 10−3--[56]
MIP filmsEphedrine0.5 × 10−3--[57]
MIPParacetamol7.9 × 10−7--[58]
MIPDopamine1.98 × 10−941[59]
MIPAtrazine1 × 10−6600-[60]
MIP
Sol–gel film
Creatinine1.23 × 10−3120<1[61]
MIP-based electrodeMelamine0.83 × 10−9-4[62]
TATP 527 × 10−6--[24]
MIp(DA) 6 filmsTNT 7
RDX 8
0.1 × 10−9
10 × 10−9
--[63]
MIP-covered electrodeCholestanol1 × 10−12-7[64]
1 AMP: adenosine monophosphate; GMP: guanosine monophosphate; CMP: cytidine monophosphate; 2 AMP: amphetamine; 3 NFA: N-formyl amphetamine; 4 BMK: benzyl methyl ketone; 5 TATP: triacetone triperoxide; 6 MIp(DA): molecularly imprinted polydopamine; 7 TNT: 2,4,6-trinitrotoluene; 8 RDX: Research Department eXplosive or 1,3,5-trinitroperhydro-1,3,5-triazine.
Table 2. MIP-based mass-sensitive sensors.
Table 2. MIP-based mass-sensitive sensors.
TransducerReceptorAnalyteLOD (mol/L)Response Time (s)Stability (Weeks)Ref
QCMMIP film(S)-propranolol50 × 10−6--[80]
MIP membranesCaffeine1 × 10−6720-[81]
Two formats 1Catecholamines-150-[79]
MIP filmTrichlorfon4.63 × 10−6-3[82]
MIP filmFormaldehyde1 × 10−610-[86]
MIP NPsN-hexanoyl-L-homoserine lactone1 × 10−61800-[84]
MIP film onto QCM crystalα-Amanitin0.052 × 10−121200poor[83]
L-tryptophan0.73 × 10−65-[85]
SAWMIP particles 2Phenacetin5 × 10−9900-[87]
MIP filmIgG0.4 × 10−91020-[88]
MIP film onto SAW chipSulfamethizole1.7 × 10−91000-[89]
MIP film onto Au electrodeGlyphosate1 × 10−121800-[90]
MIP filmCDNF protein4.2 × 10−61980-[91]
1 Crushed and sieved particles and film; 2 Crushed and sieved particles embedded in a PVC matrix.
Table 3. MIP-based optical sensors.
Table 3. MIP-based optical sensors.
TransducerReceptorAnalyteLOD (mol/L)Response Time (s)Stability (Weeks)Ref
UV/Vis and fluorescence3-Aminophenyl boronic acid filmEpinephrine9.2 × 10−61200-[95]
Crushed and sieved MIP particlesPropranolol0.32 × 10−3--[96]
Crushed and sieved MIP particlesAl3+3.62 × 10−640-[110]
Core shell composite particles4-nitrophenol76 × 10−9--[98]
QDs 1 embedded in MIP films/NPsAmylase,
lipase,
lysozyme
0.1 × 10−3,
0.1 × 10−3,
0.013 × 10−3
300-[109]
MIP particles embedded in a PVC 2 matrixDeltamethrin0.018 × 10−31803[97]
MIP tip on an optical fiberCocaine2 × 10−6~10004[108]
MIP tip on an optical fiber2,4-D 30.25 × 10−9600-[106]
Crushed and sieved MIP particlesCaffeine1.22 × 10−34800-[107]
MIP ionic liquid CdSe/ZnS QDsMycotoxin zearalenone3.12 × 10−6--[111]
MIP NPs embedded in a PVA 4 film, on an optical fiber2,4-D 3,
Citrinin
1 × 10−9,
1 × 10−6
600-[101]
Core-shell composite MIP particlesClenbuterol0.12 × 10−6300-[103]
MIP NPsTrypsin50 × 10−127200-[104]
SPRMIP film spin-coated on the SPR chipAmmonium perfluorooctanoate0.13 × 10−6600-[112]
MIP NPs coupled on a SPR chipβ-lactoglobulin211 × 10−12--[113]
MIP film on a SPR chipAflatoxin B11.04 × 10−930012[114]
MIP film spin-coated on the SPR chipOchratoxin A0.028 × 10−6600-[115]
LSPRAu NPs embedded in an MIP gelAdrenaline5 × 10−6long-[116]
Supra-particles between MIP-NPs and BPA-Au-NPsBisphenol A (BPA)<10−9 1200-[117]
SERS/SERRSCore-shell Au@MIP particles(S)-propranolol1 × 10−71-[118]
Mercaptobenzoic acid1 × 10−15--[119]
ReflectometricMIP filmsAtrazine8 × 10−62000-[120]
ColorimetricMIPC 5Methyl phosphonic acid1 × 10−6480-[121]
Silver-halide holograms into MIPs filmsTestosterone1 × 10−6long-[122]
1 QDs: quantum dots; 2 PVC: polyvinyl chloride; 3 2,4-D: 2,4-dichlorophenoxyacetic acid; 4 PVA: polyvinyl alcohol; 5 MIPC: molecularly imprinted photonic crystals.
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Leibl, N.; Haupt, K.; Gonzato, C.; Duma, L. Molecularly Imprinted Polymers for Chemical Sensing: A Tutorial Review. Chemosensors 2021, 9, 123. https://doi.org/10.3390/chemosensors9060123

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Leibl N, Haupt K, Gonzato C, Duma L. Molecularly Imprinted Polymers for Chemical Sensing: A Tutorial Review. Chemosensors. 2021; 9(6):123. https://doi.org/10.3390/chemosensors9060123

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Leibl, Nadja, Karsten Haupt, Carlo Gonzato, and Luminita Duma. 2021. "Molecularly Imprinted Polymers for Chemical Sensing: A Tutorial Review" Chemosensors 9, no. 6: 123. https://doi.org/10.3390/chemosensors9060123

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