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Review

Electrochemical Perovskite-Based Sensors for the Detection of Relevant Biomarkers for Human Kidney Health

by
Claudia Ivone Piñón-Balderrama
1,*,
César Leyva-Porras
1,
Alain Salvador Conejo-Dávila
2,
Anayansi Estrada-Monje
2,
María Cristina Maldonado-Orozco
3,
Simón Yobanny Reyes-López
4 and
Erasto Armando Zaragoza-Contreras
1,*
1
Centro de Investigación en Materiales Avanzados, S.C., Miguel de Cervantes No. 120, Complejo Industrial Chihuahua, Chihuahua C.P. 31136, Chihuahua, Mexico
2
Centro de Innovación Aplicada en Tecnologías Competitivas, Omega No. 201 Col. Industrial Delta, León C.P. 37545, Guanajuato, Mexico
3
Faculty of Engineering, Universidad Autónoma de Chihuahua, Circuito Número I s/n, Nuevo Campus Universitario, Nte. 2, Chihuahua C.P. 31125, Chihuahua, Mexico
4
Institute of Biomedical Sciences, Universidad Autónoma de Ciudad Juárez, Envolvente del PRONAF and Estocolmo s/n, Ciudad Juárez C.P. 32310, Chihuahua, Mexico
*
Authors to whom correspondence should be addressed.
Chemosensors 2023, 11(9), 507; https://doi.org/10.3390/chemosensors11090507
Submission received: 1 August 2023 / Revised: 11 September 2023 / Accepted: 15 September 2023 / Published: 17 September 2023
(This article belongs to the Special Issue Current Development on Electrochemical Glucose Biosensors)

Abstract

:
The importance of biomarker quantification in technology cannot be overstated. It has numerous applications in medical diagnostics, drug delivery, and the timely implementation of prevention and control strategies for highly prevalent diseases worldwide. However, the discovery of new tools for detection has become increasingly necessary. One promising avenue is the use of perovskite-based materials, which exhibit excellent catalytic activity and redox properties. These make them ideal candidates for the development of electrochemical sensors. In this review, the advances of purely non-enzymatic electrochemical detection of bio-analytes, with ABO3 perovskite form, are presented. The work allows the visualization of some of the modifications in the composition and crystal lattice of the perovskites and some variations in the assembly of the electrodes, which can result in systems with a better response to the detection of analytes of interest. These findings have significant implications for improving the accuracy and speed of biomarker detection, ultimately benefiting patients and healthcare professionals alike.

Graphical Abstract

1. Introduction

Non-protein nitrogenous compounds (NPNC) such as urea, uric acid, creatine, and creatinine are commonly used as biomarkers of human kidney health. Worldwide acute kidney injury (AKI) in critically ill patients is a risk factor for morbidity and mortality, with a prevalence of 17.2% in the short and long term, representing important economic impacts in terms of public health costs with an estimated USD 10 billion [1]. In 2005, the American Society of Nephrology Renal Research Report (ASNRRR) assigned the highest research priority for the discovery, detection, and standardization of novel AKI biomarkers [2]. Hydrogen peroxide and glucose are also recognized as critical biomarkers of renal function in patients with chronic kidney disease, which can lead to progressive loss of organ function and eventually to end-stage renal disease [3,4]. A biomarker is defined as a molecular marker that indicates a biological state. Biomarkers are substances in the blood, tissues, and other biological fluids, such as urine or saliva, the presence and level of which indicate a normal or abnormal condition or disease. Currently, there is great scientific and commercial interest in the discovery of new biomarkers and the development of novel techniques for their detection and quantification. As known, once a biomarker is associated with a disease, the chances and efficacy of the treatments are more successful, while the corresponding commercial opportunities for biotechnology and pharmaceutical companies are triggered. A biomarker can be a gene, a protein, a metabolite, or a substance that can be studied qualitatively and quantitatively by analytical methods such as colorimetric [5], spectrophotometric [6], and chromatographic [7] methods. Although these methods have the advantage of being highly sensitive and selective for many biomarkers, their detection is slow and expensive, and samples require pretreatment and use highly specialized material and equipment, which makes diagnosis a late and expensive event. Commonly, these types of methods are found in hospitals and specialized clinics. The emergence of new tools for the quantification of health biomarkers can potentially improve this situation, allowing the early use of multiple treatment strategies for the preservation of human health and promoting the commercial availability of at-home detection devices. Currently, some sensor systems and biosensors are emerging as promising alternatives, overcoming the drawbacks. Such devices combine biological recognition elements through a transducer responsible for giving a signal response to the presence of the biomarker and converting the observed change into a measurable signal. Diverse elements of biological recognition have been explored in numerous studies, such as biocatalysts (enzymes, microorganisms, material tissue) and bioligands (antibodies, nucleic acids, and lipid layers) [8,9]. The usefulness of these systems is impressive; however, their complexity and dependence on multiple components present the disadvantages of low storage stability, probability of enzyme inactivation, high cost, and complexity of operation. In addition, variations in sensor activity may be introduced by factors such as pH, the presence of inhibitory agents, and enzyme immobilization [10,11,12].
In recent decades, novel sensors have been developed for the detection of various biomarkers, primarily for those with a response that can be detected by colorimetric [5,13], fluorescent [14], or electrochemical [15] methods. This type of sensor has attracted attention due to its relative ease in the development of commercial devices, and at the same time, it has the advantage of not being invasive; i.e., the patient is spared the trauma of taking a blood sample since it is acquired from other bodily fluids such as saliva, sweat, urine, or tears [16,17,18,19]. These non-invasive sensors are based on electrodes, where the electrocatalytic oxidation of analytes is carried out on the surface. Therefore, the selection of the electrode and its surface characteristics, like morphology, porosity, rugosity, composition, and electron transport, significantly impact the final performance of the sensor [20].
Perovskite-based electrodes were first reported by Shimizu et al. in 1996 [21]. Since then, perovskites have shown great potential for easy-to-use detection device development with outstanding performance in detecting a variety of chemical and biological species. Either in the solid state or in solution, perovskites exhibit high selectivity and sensitivity, while providing stability to sensors. The performance of the perovskite-based sensors is due to the tunable redox properties, high oxygen mobility, electronic and ionic conduction, thermal and chemical stability, oxygen sorption capacity, and active electrical structure; all these features make this material an attractive support for the efficient detection of important biomarkers [22,23,24].
In this review, we report the recent advances in non-enzymatic electrochemical perovskite-based sensors focused on three types of biomarkers related to relevant aspects of human health for renal health indicators: glucose, hydrogen peroxide, and NPNC such as urea. This review also includes the use of perovskites with different cations, partial substitution, and different dopants, aiming to identify those that have demonstrated a better performance for the detection of the biomarkers of interest in electrochemical sensors.

2. Perovskite’s Overview

Perovskites are materials with a chemical formula of the form ABO3 (oxide-based form) or ABX3 (halogen-based form), ordered in a specific arrangement of atoms in a crystal lattice. It consists of a cubic unit cell in which an atom or ion is located at the center, surrounded by a larger octahedral cage of different atoms or ions. In the structure, A and B represent cations of different sizes (Figure 1A). In the crystalline structure of perovskites, cations in position A are usually the larger cations corresponding to alkali, alkaline earth, or lanthanide elements. These cations form a cubic lattice, which occupies the body center, 12-coordinate position. Cations B are mostly medium-sized transition metals with a preference for octahedral coordination with oxygen atoms [25,26]. Adsorption and porosity have been identified as key parameters for the sensing ability of perovskite electrochemical sensors. Thus, many works have been dedicated to evaluating the relationship between synthesis processes and morphology [27,28,29,30]. The overall conclusion is that to improve the sensing performance, the surface area must be increased, the grain size reduced, and a porous structure created. For example, Wang et al. [31] prepared LaNiO3 perovskites by electrospinning, decreasing the diameter from 400 to 140 nm by removing the binding agent (polyvinyl pyrrolidone) through calcination. With this, the surface of the fibers became rough, increasing the specific surface area and the number of active sites for the electrochemical reaction. The variation of dopants A and B and the partial substitution of B positions with cations of similar redox behavior (B′) is another strategy employed to improve the redox efficiency of perovskites. LaMnO3 perovskites and their corresponding B partial substitution La1−xAxMn1−yMyO3 (where M is a transition metal like Fe, Co, or Ni) showed possibilities to improve the sensing capacity of the hydrogen peroxide due to different oxidation states of the metal, Mn(II), Mn(III), and Mn(IV), and a flexible oxygen stoichiometry [32]. Other studies have focused on how the modification of cations induces distortion of the original form of the ABO3 formula and its effects on the perovskite catalytic properties [33,34,35,36]. The modification of the general formula induces changes in the symmetry of the crystalline structure and hence distortions in the original monoclinic, orthogonal, tetragonal, or cubic phases [37]. Although the literature mainly attributes the electrocatalytic properties to cation B, which participates in the redox process of several analytes, the ultra-high catalytic activity of perovskites seems to be due to a synergistic effect of A and B dopants since cation A also promotes the electrocatalytic activity by inducing a high concentration of non-stoichiometric oxygen (oxygen vacancies), a high diffusion rate of oxygen ions, an increase in the charge transfer process, and a stabilization of different oxidation states of B cations [38,39,40,41].
The detection mechanism in non-enzymatic electrochemical detection of bioanalytes with ABO3 perovskites is based on the chemical reaction of B cations with OH groups in an alkaline medium, forming oxides, hydrated oxides, or hydroxide species (Figure 1B). He et al. [42] reviewed the advances in non-enzymatic electrochemical sensing using oxidized perovskites. In this review, the model of the incipient hydrated oxide adatom mediator (IHOAM) was introduced, which is the model that better describes the mechanism of electrochemical sensing. According to this model, the metals oxidize at a low potential and produce hydrated oxides (BOOH) that mediate oxidation and reduction processes [43]. A particular emphasis was placed on the effect of the electrocatalytic mechanism of lattice oxygen intermediates (LOM) with adsorbed -OO and lattice O vacancies [44], which endow these perovskites with ultra-high catalytic activity. Several other review papers have been focused on the perovskites’ sensory applications based on their ferroelectric, ferromagnetic, optical, and electrical properties [45,46,47,48].

3. Application of Perovskites in the Sensing of NPNC Biomarkers

3.1. Sensing of Glucose

Glucose, as the major energy supply substance of organisms and an intermediate product of metabolism, plays a vital role in the physiology and biochemistry of living organisms. Glucose promotes the body’s ability to remember, stimulates calcium absorption, and increases cellular communication [49]. However, the overexpression of serum glucose triggers adverse effects in the body, leading to chronic damage and dysfunction of various tissues, especially diabetic retinopathy, diabetic cataracts, and peripheral neuropathy. Hence, there is value in detecting and quantifying the glucose content in the human body. Traditional home blood glucose monitoring (HBGM) methods are invasive, involving blood analysis through a blood drop from one fingertip, the reaction of the glucose in the blood with the indicator band, and the final reading content on the glucometer screen. This type of biosensor is based on a thin layer of glucose oxidase (GOx) on an oxygen electrode. Thus, the readout is the amount of oxygen consumed by GOx during the enzymatic reaction with the substrate glucose [50]. In the test strip, a GOx enzyme reacts with glucose to create gluconic acid. The gluconic acid reacts with ferricyanide, which then combines to create ferrocyanide. The amount of ferrocyanide produced is related to the glucose concentration in the blood sample by an electronic current passing through the testing strip. The glucose concentration is indicated by the number displayed on the screen of the glucose testing meter. A compressive review of electrochemical glucose biosensors was reported by Wang [51]. According to this review, glucose biosensors can be categorized into three groups: (i) first-generation biosensors that require the use of a natural oxygen co-substrate, the generation and detection of hydrogen peroxide (H2O2), and the application of a relatively high potential on the electrode; (ii) second-generation biosensors that involve replacing the oxygen co-substrate with a synthetic electron acceptor capable of transporting electrons from the enzyme to the surface of the electrode; and (iii) third-generation biosensors that are based on the elimination of the electron-transfer mediator and the application of a relatively low operating potential.
Recently, the development of non-enzymatic glucose biosensors has been directed toward the obtention of non-invasive detection mechanisms, which avoids the hassle of taking a blood sample through determinations in other body biological fluids such as saliva, sweat, urine, and tears. The study of non-enzymatic sensors also has given rise to detection systems with reduced costs, avoiding the use of expensive and unstable enzymes. The use of enzymes presents the disadvantage of low stability, in addition to variations in sensory activity due to factors such as pH, the presence of inhibitory agents, and enzyme immobilization [12,52,53]. These non-invasive sensors are based on electrodes where the electrocatalytic oxidation of analytes is carried out on the surface. Therefore, the selection of the material for modifying the electrode surface, the electroactive area, morphology, porosity, and rugosity can significantly impact the final performance of the sensor [20]. NiFe2O4 (NFO) nanoparticles were used to immobilize GOx on a carbon paste electrode (CPE) coated with LaNi0.5Ti0.5O3 (LNT) perovskite particles, finding that at a ratio of 20:1 LNT-NFO, the enzymes were effectively immobilized, obtaining a glucose sensor with a linear range of 0.5–10 mM and a detection limit of 0.04 mM [54]. In this sense, perovskites are materials able to retain a three-dimensional network microstructure while keeping large amounts of oxygen vacancies and accommodating different metallic elements within the lattice structure [55]. A recent review established that the mechanism for glucose electro-oxidation in perovskites is complex and similar to the mechanism of H2O2 electro-oxidation [56]. This mechanism is known as the lattice-oxygen-mediated oxygen evolution reaction (LOM-OER), which involves the partial substitution of the cations of the A sites by divalent cations from group IIA of the periodic table, which can oxidize the cations of the B sites. The increase in these substitutions causes a reduction in the formation energy of oxygen vacancies, which transfer oxygen from the lattice to the adsorbed species, generating highly oxidative oxygen species known as superoxide ions.
The first published article where perovskites were employed as a sensor on a carbon electrode in electrochemical tests was published by Shimizu et al. in 1996 [21]. They found that La0.6Ca0.4Ni0.7Fe0.3O3 perovskite presented a relatively high specific surface area and good response in the sensing of H2O2 in the range of 0.01–1 mM. In the A2BO4+δ type perovskite containing Pr1.92Ba0.08Ni0.95Zn0.05O4+δ, the presence of Pr2O3 promotes the formation of defects in the crystal lattice of the A sites, as the partial substitution of Pr by Ba causes the disproportionation (oxidation-reduction reaction) of the B sites from NiIII to NiII and NiIV [56]. The perovskite material was deposited on a gold electrode employed as a working electrode, and the performance of the glucose sensor showed a dynamic range of 1.5–7000 μM, detection limit of 0.5 μM, and no interference for glucose detection in human serum.
The properties of the perovskites are mainly determined by the element, substitution, and occupation of the B sites [57]. In this sense, perovskites doped with noble metals (AB1−yMyO3) may present improved stability and catalytic activity. To verify this, the SrPd1−yMyO3 perovskites were studied, where M represents the noble metals tested (Ni2+, Cu2+, Au3+, and Pt2+) [58]. From these cations, Au3+ at low concentrations, i.e., 0 < y < 0.7, presented the best characteristics for glucose sensing since the anodic peak current increased, reaching a maximum value at y = 0.3. The dopant promoted the electronic properties of the perovskite and increased the charge transfer rate while stabilizing the orthorhombic structure. The glucose sensing in human serum showed a wide concentration range of 0.2–1000 µM, high sensitivity of 1.44 × 104 µA/mM cm2, low detection limit of 2.11 nM, and no interference from other molecules. Silver nanoparticles have been extensively studied as catalysts in various reactions due to their excellent electrical conductivity. Hence, by adding Ag NPs to a La-Ti perovskite (LaTiO3-Ag0.2), it has been possible to decrease the detection limit to 0.21 µM, increase the sensitivity to 784.14 µA/mM cm2, and broaden the range of linear response of 2.5 µM to 4 mM [59].
Perovskites containing Ni at the B sites, known as nickelates (ANiO3, where A = La, Nd, Eu, Gd, Dy, or Sm), have also attracted the attention of glucose sensing due to their specific conductivity, specific surface area, and electroactivity. The contribution of some of these rare earths in the A position of the perovskite, as in the case of Nd, is to provide a high specific conductivity to the electrode. For example, NdNiO3 perovskite synthesized by the hydrothermal method and deposited on a carbon electrode showed excellent electrocatalytic behavior for the oxidation of glucose in human serum [60]. The electrochemical results showed a wide linear range from 0.5 µM to 4.6 mM, a sensitivity of 1105.1 µA/mM cm2, and a detection limit of 0.3 µM. The non-enzymatic glucose oxidation mechanism in this type of perovskite involves the oxidation of nickel (Ni2+ ↔ Ni3+ + ē) and the subsequent oxidation of glucose (Ni3+ + glucose → Ni2+ + glucolactone). LaNi0.5Ti0.5O3 (LNT) deposited on a carbon paste electrode (CPE) showed a sensitivity to glucose of 1630.53 µA/mM cm2, limit of detection of 0.07 µM, and linear range of 0.2 to 20 µM [61]. In electrodes modified with perovskites of La0.6Sr0.4FeO3−δ and La0.6Sr0.4Co0.2Fe0.8O3−δ (LSF and LSCF, respectively), the partial substitution of Fe by Co atoms increased the sensitivity towards the detection of H2O2 and glucose [62]. The partially occupied d orbitals allow these transition metals to assume different oxidation states through the loss or acquisition of electrons, which promote the formation of a surface layer of adsorbed OH species. Glucose detection results for the LSCF perovskite obtained at a potential of 0.5 V were a linear range of 0–200 µM, detection limit of 7 µM, and sensitivity of 285 µA/mM cm2.
The formation of oxygen vacancies has also been identified as a key parameter to increase the glucose sensing capacity through surface area modification. He et al. studied the increase of oxygen vacancies by replacing trivalent cations such as La3+ with divalent cations such as Sr2+ or Ca2+. Additionally, the presence of these cations promotes a growth in surface area and structural stability. The doping of the SrPO3 perovskite with Ca, in the concentration range of 0–0.7, allowed setting the formulation Sr1.7Ca0.3PdO3 with optimal results in glucose sensing [63]. This performance was mainly attributed to the structural modification of the crystalline lattice, where the increase in the free volume allows a greater mobility of the surface lattice oxygen. The sensing results showed a linear range of 5 µM to 1.4 mM, a sensitivity of 306.9 µA/mM cm2, and a detection limit of 0.0845 µM. Determining glucose in urine samples showed relative standard deviations lower than 4.17%. In the case of the perovskite La0.6Sr0.4CoO3−δ (LSC), its behavior as a glucose sensor was enhanced by depositing on a reduced graphite oxide (RGO) electrode, presenting a detection range of 2–3350 µM, sensitivity of 330 µA/mM cm2, and detection limit of 0.063 µM [64].
Surface area and grain size modification and the creation of porous structures represent an alternative strategy to improve the sensing performance of perovskite-based materials. For example, LaNiO3 perovskites, prepared by electrospinning, showed a decrease in the diameter of the fibers after the removal of polyvinyl pyrrolidone by calcination, which worked as the binding agent. The reduction of the fibers decreased from 400 to 140 nm, giving rise to a rougher surface and increasing the specific surface area and the number of active sites for the electrochemical reaction. The Ni ions are the active sites with partially occupied d orbitals that produce two different oxidation states for the metal (NiII/NiIII). The detection limit for glucose was 0.32 μM and a linear detection range of up to 1 mM. Electrospun and calcined La0.88Sr0.12MnO3 perovskites deposited on a CPE presented a linear range of 0.05–100 μM, a sensitivity of 1111 μA/mM cm2, and a detection limit of 32 nM [31]. The morphological characterization showed rough surface fibers with diameters of 200–300 nm and lengths of several micrometers. ABO3-type perovskite structures were employed for modifying a carbon electrode with the electrospinning of porous La–Sr–Co–Ni–O (LSCNO) nanofibers [65]. According to these authors, when metallic elements such as Ni, Co, and Fe are placed in perovskite B sites, they promote a high activity in glucose sensing. Then, after testing the perovskite’s performance in glucose detection, they found an optimal composition of the form La0.75Sr0.25Co0.5-Ni0.5O3, showing a linear response in the range of 0.1–1.0 mM with a calibration sensitivity of 924 ± 28 µA/mM, a low detection limit of 0.083 mM, and 0.59 ± 0.03 mM of glucose in urine fluid sample.
Because of its high electrocatalytic activity, perovskite-carbon nitride composite is an attractive potential candidate for interference-free sensing of glucose [66]. A perovskite-type cerium-aluminum oxide (CeAlO3, molar ratio Ce: Al of 1:1), in the form of polycrystalline powder, was ultrasonically mixed with carbon nitride (CN). The formed CeAlO3@CN composite was deposited on a glassy carbon electrode, represented in Figure 2. Then, it was tested as the working electrode in a conventional electrochemical three-electrode cell configuration. The voltammetry detection of glucose showed a linear concentration range of 0.01–1034.5 μM and a detection limit of 0.86 nM. The amperometric determinations of glucose in human blood, saliva, and sweat were compared against those determined in a commercial glucometer, finding similar results with less than five percent error. A photoelectrochemical biosensor based on different semiconductor heterojunctions was constructed to reduce electron–hole pair recombination while retaining the oxidation potential of the composite material [67]. For this purpose, strontium titanate (SrTiO3) perovskite was synthesized by hydrothermal method and employed as a working electrode in tandem with titanium oxide (TiO2), polydopamine (PDA), and GOx. PDA was deposited on the final surface of the modified electrode and employed as the binder to increase the affinity between GOx and the perovskite. The TiO2-SrTiO3-PDA-GOx system presented an extended linear range of 0–32 mM, a high sensitivity of 5.37 μA/mM cm2, a detection limit of 25.68 μM, and accurate detection of glucose in human serum in the range of 0–20 mM. The proposed mechanism describes hydrogen peroxide production from the surface reaction of glucose and GOx and its subsequent oxidation by photogenerated holes at the SrTiO3-TiO2 interface to generate a photocurrent. The SrPdO3 perovskite coated with gold nanoparticles presented a synergistic effect with a higher current response for the electro-detection of glucose with a linear concentration range of 100 μM/L to 6 mM/L, detection limit of 10 μM/L, and no interferences detection [63]. This system allowed the glucose oxidation mechanism explanation based on the oxidation potentials: (i) the dehydrogenation of the adsorbed glucose molecules (−0.55 V), (ii) oxidation of dehydrogenated glucose (+0.056 V) to gluconolactone, and (iii) conversion of gluconolactone to gluconate by reacting with hydroxyl ions in solution.
Other glucose sensing techniques not based on electrochemical measurements include colorimetry, fluorometry, and chemiluminescence. The hydrolysis reaction of glucose by GOx produces water, oxygen, and many protons, lowering the pH and harshening the environment of the sensing probe. Thus, cesium-lead-bromide perovskite quantum dots were coated with SiO2 (CsPbBr3@SiO2 PQDs) to avoid environmental deterioration and the loss of optical properties such as light emission. This system showed excellent fluorescence properties with an absorption of UV radiation at a wavelength of 365 nm, an emission of green light at 525 nm, a notable selectivity to pH, and a detection limit of 18.5 µM [68]. The development of fluorescence measurements by eliminating multiple background interferences has led to a noticeable improvement in detection sensitivity and accuracy. This has been achieved by exciting a material at one wavelength and obtaining emission at two wavelengths. Metal halide perovskite nanocrystals present unique optical properties for this purpose. CsPbBr3 hydride perovskite nanocrystals (PNCs) complexed with Cu NCs emit at two wavelengths: PNCs at 645 nm and NCs at 517 nm [69]. Upon the glucose sensing, the system presented a linear response range of 2.0–170.0 μM, a detection limit of 0.8 μM, and satisfactory results when tested with human serum. Electrochemiluminescence (ECL) sensors are based on the synergistic effect of electrochemical oxidation or reduction of a chemical compound that emits light. With LaTiO3-Ag0.1 deposited on a working electrode and luminol as a chemiluminescent agent, a promising glucose sensor was reported [70]. Properties as glucose sensors in human blood serum samples have a linear range of 0.01 μM–0.10 mM, a detection limit of 2.50 nM, and a sensitivity of 7.80 × 102 μA/mM cm2. These properties are explained in terms of the increase of the active surface area of the working electrode caused by the perovskite composite oxide, while doping with Ag promotes the interfacial electron-transfer rate, and the luminol oxidation generates the ECL effect.

3.2. Sensing of Urea

According to the definition of the British encyclopedia [71], urea is a nitrogenous product of the metabolic breakdown of proteins in all mammal species, present in the urine, blood, bile, milk, and all mammal species perspiration. While the proteins break down, amino groups are removed from the amino acids, which could convert later to ammonia, which is toxic to the body and converted into urea by the liver. The urea then passes to the kidneys and is excreted in the urine. If this process is disturbed, ammonia levels begin to rise. High urea levels in blood and urine cause kidney failure, urinary tract obstruction, gastrointestinal bleeding, dehydration, burns, and shock, while lower levels of urea result in hepatic failure, nephritic syndrome, and cachexia [72,73,74]. The electrochemical oxidation of urea from perovskite-based sensors is catalyzed by cation B. In an alkaline medium, the adsorption of OH groups takes place on the electrode surface. Then, these groups react with the B metal to form the M2+(OH)2 species. These molecules are oxidated to produce M3+OOH, corresponding to the reactive species that carry out urea electrooxidation. M3+OOH reacts with CO(NH2)2 and water molecules to produce M2+(OH)2, N2 and CO2. For example, Tran reported the synthesis of a nanocomposite based on CeO2-modified LaNi0.6Fe0.4O3 perovskite and MWCNT [75]. Niquel cations were responsible for the catalytic activity, while the CeO2 and multiwall carbon nanotubes imparted stability and increased the surface area, respectively. The authors report that the mechanism of electrochemical oxidation of urea is carried out in two steps, following the next reaction mechanism:
6Ni2+(OH) (s) + 6 OH → 6Ni 3+OOH (s) + 6H O + 6e   Step 1
6Ni3+ OOH (s) + CO(NH) (aq) + H2O → 6Ni2+ (OH) (s) + N2 (g) + CO2   Step 2
The urea detection level is of prime importance in clinical diagnosis and as a biomarker of the kidneys and liver functions. The most common methods for this important biomarker detection are UV-vis and infrared spectroscopy, ion and liquid chromatography-mass spectrometry, and fluorimetry [75,76,77,78] Previously, the drawbacks of the enzymatic sensing of glucose, which are also applicable to urea, were mentioned. The typical amperometric urea biosensors are based upon the detection of ammonium ions resulting from the hydrolysis of urea in the presence of the enzyme urease viz. Due to the formation of ionic species by the reaction with the enzyme (NH4+ and HCO3) in the presence of water, the electrochemical techniques become the suitable methodology for both the identification and quantification of urea. Thus, perovskite-based non-enzymatic detection systems for sensing analytes related to human kidney health were recently reported. Most of the studies have been focused on the improvement of (i) the surface area, (ii) imparting chemical stability, (iii) increasing the sensing performance, and (iv) reducing the cost of the fabrication of the sensor. For example, Tran et al. [75] used the perovskite of LaNi0.6Fe0.4O3 in a composite with CeO2 to improve the electro-oxidant activity towards urea. In addition, multi-wall carbon nanotubes (MWCNT) were included in the modified indium tin oxide (ITO) electrode, which improved the active electrochemical surface area. In the presence of urea, electrochemical oxidation is carried out by the reaction mechanism for the Ni2+ (OH)2/Ni3+ OOH pathway. Kumar et al. [79] reported the electrochemical detection of uric acid with a GP electrode modified with perovskite-type XFeO3 (with X = La, Ce, Pr, Sm, Gd, Tb, and Dy). In every case, the perovskites were obtained in nanometric size with mainly cubic morphology in the 30 to 50 nm range. They found that the best charge transfer, using a standard [Fe(CN)6]−4/[Fe(CN)6]−3 redox system, occurred when X = La with phosphate buffer saline (PBS) electrolyte at a pH of five. The modified electrode was tested with human serum and urine samples, finding high precision in its application in clinical diagnosis. Another study for the detection of uric acid employed a graphite paste electrode modified with a neodymium ortho-ferrite perovskite (NdFeO3) to investigate the electrochemical behavior of the modified electrode. A standard [Fe(CN)6]−4/[Fe(CN)6]−3 redox system was used and compared against the unmodified electrode (blank). The modified electrode showed an oxidation current almost three times higher than the blank, evidencing its greater efficiency in charge transport. This was verified in the determination of uric acid at a pH of five, employing cyclic voltammetry. The sensor showed high stability after 30 days and high reproducibility [80]. Nanocubes of ZnSnO3 perovskite, in its orthorhombic phase, were used for uric acid detection [81] by cyclic voltammetry and differential pulse voltammetry. Before analyte detection, a study to determine the optimal electrochemical surface-active area produced by the ZnSnO3 charge was carried out. It was determined that with 6 μL of 0.5 wt% dispersion, an effective surface area of 0.1041 cm2 was obtained, which favors the increment of the number of electrocatalytic active sites for redox reactions [81]. The detection of uric acid was attributed to the Sn2+/Sn4+ oxidation states of tin, which favored the high electrochemical stability and sensor selectivity. Soundharraj et al. [82] reported urea sensing using a graphite electrode modified with zinc titanate (ZnTiO3) nanoparticles prepared by the sol-gel method. The modified electrode showed a peak current increase in the presence of urea compared to graphite alone. This was related to the transfer of electrons from the amine groups to the ZnTiO3 conduction band. The subsequent reduction in current with the increase in urea content was attributed to a delay in electrical conductivity due to an oxidation augment induced by the TiO2. Chakraborty et al. [83] employed a mixture of cerium copper oxide (CeCuOx) and nickel oxide (NiO) nanoparticles, CeCuOx/NiO, for the detection of Lipocalin 2 (LCN2). LCN2 higher than standard levels may indicate various human health conditions, including kidney damage. Before the assembly of the silicon-based electrodes, a heat treatment was performed on the CeCuOx, which was corroborated by cyclic voltammetry, showing that annealing at 800 °C produced the best electrochemical behavior. Subsequently, when adding the NiO nanoparticles, an improvement in the electrochemical activity was observed, which was explained first as an electronic transfer reaction from CeCuOx to NiO, followed by a redox exchange reaction between Fe, Fe3+/2+ in LCN2, and Ni3+/2+ of the NiO nanoparticles. The sensor showed high stability for 14 days and high selectivity in the presence of common interferents in human serum. In addition, high sensing precision was found when compared with human serum samples spiked with LCN2.
Perovskite-type transition metal oxides have high catalytic activities due to high electronic conductivities. Manna et al. modified a glassy carbon electrode with the composite rhenium oxide (ReO3)/reduced graphene oxide (rGO) for uric acid detection. The high electrochemical response of the composite was attributed to the plasmonic behavior at the edges of the ReO3 nanostructure, which favors electron transfer. It was found that the presence of interfering species, such as glucose and some metal ions, does not significantly alter the detection of uric acid. This study also indicated that the modified electrode has good repeatability, so it can be applied to real samples. Analyses of synthetic human serum spiked with uric acid showed an acceptable recovery, in the order of 10%.
It should be noted that other works dedicated to electrochemical non-enzymatic sensing with perovskites have reported the detection of some of the analytes of interest in this section. However, in these studies, these compounds were only used as interferents [84,85]; therefore, they were not considered in this review.

3.3. Sensing of Hydrogen Peroxide (H2O2)

Hydrogen peroxide (H2O2) is a reactive oxidant species (ROS) in all aerobic organisms [86,87]. It is a byproduct of aerobic metabolism and physiological processes such as immune activation [88], apoptosis [89], and cell growth [90]. Cells must remove this molecule due to oxidized biological targets, causing different diseases and pathologies [88] like cancer [91], cell damage [92], and inflammatory diseases [93].
H2O2 is not only a metabolic byproduct but also an oxidant reactive employed in food [94], pharmaceutical [95], cosmetics [96], and chemical industries [97]. Due to the relevance that H2O2 represents, its quantification and detection become necessary. In the last decades, hydrogen peroxide sensors have been developed, mainly based on colorimetric [6], fluorescent [14], and electrochemical [98] methodologies. This last kind of sensor has attracted much attention due to its relative facility for developing commercial sensor devices. The reported electrochemical hydrogen peroxide sensor could be also enzymatic [99] or non-enzymatic [100]. The non-enzymatic sensor generally requires metal compounds that make the redox reaction for hydrogen peroxide detection. Perovskite-based materials are bimetallic compounds that show excellent electrochemical and redox properties. Conventionally, these materials were employed to explore the redox properties of perovskites to develop electrochemical sensors. The most applied conventional formula of perovskites to sense hydrogen peroxide is also the ABO3 form. The most employed elements are from the lanthanide group or alkaline earth metals, where La, Sr, and Ca are the most important. Cations in B positions are usually transition metals from the fourth group of the periodic table, in which Ni, Co, Fe, and Mn are more frequently reported [101]. These cations (B) are responsible for interacting with hydrogen peroxide through the redox reaction B(M)+/B(M+1)+, producing molecular oxygen, water, and electrons as the responses of the electronic signal, which makes these substances electrochemically detectable and measurable. Due to lattice oxygen transfer, a redox mechanism occurs [64]. In contrast, the role of A cation is to stabilize the diverse B cation oxidation states in redox reactions. It has been reported that the general performance and redox behavior could be improved by partial substitution of A cations with the same element but with different oxidation states (A′) [101]. The partial substitution of B with other cations with similar redox behaviors, B′, is a strategy to improve redox efficiency [32].
The development of materials as non-enzymatic H2O2 sensors has gone through several stages. The first studies focused on exploring different A cations and observing the electrocatalytic performance of these cations on H2O2 decomposition. For example, the enthalpy of the formation of various perovskite copper oxides (ACuO3) with other A cations (A = La, Sr, Ba, Na, or K) and doped La1−XCuO3 perovskite (where X = Ca, Sr, or Ba) requires higher exothermic oxidation energies than lanthanum nickelates and cobalt [102]. The research on the effect of cation A and possible dopant agents was complemented by varying the ratio of each cation and observing their effects. In perovskite oxides of La1−XCaXMnO3 (X = 0.0, 0.2, 0.4, and 0.6) using the citrate gel method, the concentration of calcium in perovskites affects the catalytic activity. This behavior is attributed to the non-stoichiometry δ-oxygen and the average valence states of Mn responsible for the catalytic activity in the decomposition of hydrogen peroxide in an alkaline solution [101].
The methodology of perovskite oxide synthesis for H2O2 detection has also been explored, where aspects such as the temperature of calcination and the effect on their crystalline structure (Figure 3) have been addressed by different research groups. For example, the catalytic redox activity of La1−XAXMnO3 perovskite synthesized through denitrification using MW heating metal nitrate aqueous solutions doped with Ca and Pr and calcinated at 800 °C showed a crystal size larger than 48 nm. In contrast, the perovskites doped only with Ca exhibited a smaller crystal size but a surface area of 16 m2 g−1. Nevertheless, the perovskite doped with Sr showed the most sensing sensitivity of H2O2 [32]. The synthesis of La1−XSrXMnO3 perovskites by sol-gel methodology and calcinated between 550 and 750 °C for 5 h displayed considerable catalytic activity in an alkaline medium by reducing the analyte concentrations [103].
The morphology of perovskites also plays a fundamental role in sensor development since this strategy impacts the superficial area of the electrode and, therefore, the active sites available for detection and sensing of the interest analytes. In this sense, the synthesis methodology is the most significant variable in the resulting morphology. Perovskite nanostructures have been synthesized by hydrothermal, solvothermal, and electrospinning routes, evidencing significant changes in their morphology and physicochemical properties. Thus, the same CaTiO3 system has been synthesized by several authors, evidencing a wide variety of morphologies ranging from butterfly-like dendrites [104], cubic particles [105], hollow micro-cubes [106], nanolamellate [107], and pyramides [82]. Also, a calcination procedure impacts the final morphology. For instance, electrospinning and sequential calcination of perovskite oxide LaNiO3 nanofibers reduced the fiber’s diameter from 400 to 140 nm. The corresponding amperometry sensor of H2O2 and glucose developed with LaNiO3 nanofibers showed a fast response and long-term stability [31]. Likewise, La0.7Sr0.3Mn0.75Co0.25O3 nanofiber for sensing H2O2 in alkaline buffer, synthesized through electrospinning and calcination, was produced as fibers with a diameter in the 250 to 300 nm range [108]. Other morphologies reported are nano brushes of KNbO3 synthesis by hydrothermal [109] and nano-structured perovskite oxide LaNiTiO [110]. Figure 4 displays a variety of morphologies reported in literature where different synthesis strategies were employed, intending to tailor the morphology of the obtained nanomaterial.
Interest in the investigation to develop new perovskite structures, combining different cations (A and B), doped or pure, to improve some properties of the sensor, such as the limit of detection, the linear range of detection, the sensitivity, and the selectivity, increased after 2009. I.e., two B cations and their ratios have been studied to improve the sensing properties of LaCaBO perovskites. They described the behavior of carbon electrodes loaded with La0.6Ca0.4BO3 (B = Cr, Mn, Fe, Co, and Ni) perovskites oxides prepared by the amorphous malate precursor method, which provides a specific surface area in the range of 8–30 m2/g. These values are considerably larger than those obtained by the conventional acetate decomposition method [21]. The potentiometric response of these perovskites was tested in the presence of H2O2, showing that material doped with Fe presented the best characteristics to develop a potentiometric sensor. Also, perovskite oxide LaXSr1−XCoYFe1-YO3−δ was synthesized by the citrate method, and a comparison of its sensing properties showed that cobalt added to the ferrite structure enhanced the sensitivity, the linear range, and the detection limit [62]. Also, SrFeO3 perovskite doped with Ce showed that the presence of both cations improved the sensor performance [109]. A 3D macroporous SmCoO3 perovskite hydrogen peroxide sensor presented the lowest detection limit of 0.004 µM and a linear detection in the 0.1 to 10,000 µM range, while the presence of glucose, ascorbic acid, dopamine, and uric acid did not show interference activity [110]. The properties of this sensor may be related to the hexagonally ordered microporous crystalline structure. Rare earth cuprate perovskites (Ln2CuO4 where Ln = Sm or La) were employed for sensing H2O2 and presented broad detection ranges [111]. The perovskite with Sm exhibited a detection range of 1.24–35,440 µM, while La showed a value of 0.50–23,350 µM but a lower LOD. Additionally, the highest sensitivity sensor toward H2O2 with a value of 1667.9 µA mM−1 cm−2 was reported for a La0.9Sr0.1NiO3 nanofiber perovskite; this structure provides excellent ion transport channels and contact sites for the H2O2 sensing [112].
Amperometric and potentiometric (cyclic voltammetry, CV) approaches are the most employed characterization techniques to evaluate the sensing capacity and electrocatalytic activity of perovskites. The way these electrochemical probes work is different. A potentiometric test measures the potential (voltage) between a working and reference electrode in a system with no significant current flow. The working electrode surface is modified so that changes in potential can be correlated with the changes in the analyte concentrations. The reference electrode remains constant, performing as a reference or comparison to the working electrode. Amperometric sensors rely on the principle that changes in current are related to changes in analyte concentration. In a typical CV experiment (Figure 5A), the determination and quantification of the analyte may be observed as a change in the anodic or cathodic peak current, which changes proportionally with the increase of the analyte concentration. On the other hand, amperometric recordings are performed by successive additions of the analyte and plotting the observed sensitivity to the analyte concentrations (Figure 5C). Consequently, it is possible to employ this technique as a parameter for sensing a variety of biomarkers.
Electrochemical impedance spectroscopy is another methodology for evaluating the electrocatalytic properties of perovskite-based materials. This technique is employed for analyzing interfacial events occurring at the electrode surface. The results are presented as a Nyquist plot (Figure 5B), where a semicircle reflecting the changes in the electron transfer resistance is displayed at high frequency. The charge transfer resistance (Rct) at the electrode interface is measured by the diameter of the semicircle, while the straight line at the low frequency corresponds to the dispersion process. An equivalent circuit is employed for fitting the impedance Nyquist plot. On the other hand, amperometric detection is carried out by fixing the potential at its oxidation or reduction peak potential value (previously determined from CV measurement) and monitoring its current response.
X-ray diffraction (XRD) is commonly employed to elucidate the perovskite crystalline structure. Ideally, perovskites of the form ABX3 are arranged into a cubic cell, where the atoms are just touching each other, and the B–X distance is equal to a/2 and the A–X distance is 2a/2, where a is the cube unit cell length and the relationship between radii of ions holds RA + Rx = 2RB + Rx [113,114,115]. However, distorted structures with tetragonal, rhombohedral, or orthorhombic symmetry have been found, mainly arising from smaller A ions that induce a tilting of the BX6 octahedra to optimize A–X bonding. ABO3 perovskites, where cation A is typically larger than cation B, are known to exhibit cubic, hexagonal, or even polytypism consisting of mixed cubic and hexagonal stacking of AO3 layers.
X-ray photoelectron spectroscopy (XPS) is also performed to probe the surface oxidation states and compositions, the binding energies, and the relative amounts of different metal and oxygen species on the surface available for the catalyst of the analyte. The characterization technique is also helpful in identifying the lattice oxygen species (O2), highly oxidative oxygen species (O22−/O−), hydroxyl groups or the surface adsorbed oxygen (HO/O2), and adsorbed molecular water (H2O).
Figure 5. (A) Cyclic voltammogram measurements of BaTi0.7Fe0.3O3-NiFe2O4 nanocomposites conducted in a solution of standard redox probe of ferricyanide with the 5 mM in KCl as the suppor- ting electrolyte for detection of H2O2. (B) Electrochemical impedance IS Nyquist spectra characterization of modified electrodes with the nanomaterials. Inset represents the modeled circuit that is used for curve fitting. “Reprinted (Adapted) from Construction and characterization of nanooval BaTi0.7Fe0.3O3@NiFe2O4 nanocomposites as an effective platform for the determination of H2O2Hammad, A.B.A., Magar, H.S., Mansour, A.M. et al. Copyright © 2023 [114]. (C) current-time responses of LSC + RGO/GCE upon addition of different concentrations of H2O2 and (D) glucose in a 0.1 M NaOH electrolyte; insets show the linear range for H2O2 and glucose detections. Reprinted from High-performance non-enzymatic perovskite sensor for hydrogen peroxide and glucose electrochemical detection, 244, He, J., Sunarso, J., Zhu, Y., Zhong, Y., Miao, J., Zhou, W., & Shao, Z., Copyright (2017), with permission from Elsevier [64].
Figure 5. (A) Cyclic voltammogram measurements of BaTi0.7Fe0.3O3-NiFe2O4 nanocomposites conducted in a solution of standard redox probe of ferricyanide with the 5 mM in KCl as the suppor- ting electrolyte for detection of H2O2. (B) Electrochemical impedance IS Nyquist spectra characterization of modified electrodes with the nanomaterials. Inset represents the modeled circuit that is used for curve fitting. “Reprinted (Adapted) from Construction and characterization of nanooval BaTi0.7Fe0.3O3@NiFe2O4 nanocomposites as an effective platform for the determination of H2O2Hammad, A.B.A., Magar, H.S., Mansour, A.M. et al. Copyright © 2023 [114]. (C) current-time responses of LSC + RGO/GCE upon addition of different concentrations of H2O2 and (D) glucose in a 0.1 M NaOH electrolyte; insets show the linear range for H2O2 and glucose detections. Reprinted from High-performance non-enzymatic perovskite sensor for hydrogen peroxide and glucose electrochemical detection, 244, He, J., Sunarso, J., Zhu, Y., Zhong, Y., Miao, J., Zhou, W., & Shao, Z., Copyright (2017), with permission from Elsevier [64].
Chemosensors 11 00507 g005

4. Perspectives and Current Challenges

Although the use of perovskites as electrochemical sensors began in 1994, the challenge in recent years has undoubtedly been focused on improving the detection parameters of this type of sensor by electrocatalytic material modification. However, there are still areas of opportunity to obtain even lower detection limits or wider detection ranges, either through the development of new types of perovskites, composite materials, or variations in the sensor assembly. As can be inferred, the scientific interest in biomarker sensing through the development of perovskite-based sensors is notable, resulting in many reported perovskite systems. This review allowed a visualization of the effect of the modifications in the composition and crystal lattice of perovskites and the variations in the electrode assembly, which may result in systems with a better response to the sensing of analytes of interest. Table 1 summarizes some of the most critical parameters of electrochemical sensors, including the limit of detection (LOD), linear range of detection (LROD), and stability for the most frequently reported biomarkers, such as H2O2, uric acid, urea, and glucose. As observed from Table 1, the LOD for urea is close to 1 μM, and the LROD is 25 to 650 μM. For uric acid, these values are relatively smaller, with LOD in the range of 200–550 nM and LROD from 0.5 to 120 μM. Regarding sensor stability, high stabilities are reported in the 15 to 45-day range.
The monitoring of biomarkers is an essential tool for the prevention and control of patients with renal dysfunction or critical kidney disease. In this sense, the development of accurate devices for the detection of biomarkers is of high interest. Perovskite-based material is a versatile and promising candidate with desirable features for biomedical applications such as high selectivity and sensitivity, while providing stability to sensors. Additionally, these materials have tunable redox properties, high oxygen mobility, electronic and ionic conduction, and thermal and chemical stability. However, some significant challenges need to be addressed before these nanomaterials can be converted into real devices for patients who require a daily care control. Firstly, most of the sensors have been studied from the point of view of material science research, instead of meeting real specifications of this field that involve the treatment of biological fluid samples. For example, blood glucose concentrations in healthy people have been established to be 5.6 mM; however, for diabetic patients, values up to 7 mM can be expected. Although most of the investigation works presented an adequate LOD, most of them require extending their working range to fit the needs of correct blood glucose evaluation. Another key challenge is the fact that an alkaline electrolyte is required for the oxidation of several biomarkers, which does not correspond with the pH of the biological fluids.
Some areas of opportunity were detected, such as extending research related to other important biomarkers for renal health care, such as creatine and creatinine, which to our knowledge have not been explored yet for the perovskite-based materials. In this sense, as mentioned above, work on the development of non-enzymatic sensors for the detection of biomarkers of kidney health is still in its infancy; consequently, a trend in the type of metals used has not yet been observed in the general ABO3 structure, which is the most favorable for this purpose, although Fe seems to be the most used. However, we would have to wait a longer time to have more data to give a more objective conclusion.

5. Conclusions

Glucose, hydrogen peroxide, and non-protein nitrogenous compounds (NPNC), such as urea and uric acid, are important biomarkers of human kidney health. Acute kidney injury (AKI) in critically ill patients represents a risk factor for morbidity and mortality worldwide. Non-enzymatic detection tools have emerged as promising alternatives to prevent and control critical diseases as they are quick to read, easy to use, and low-cost. In this work, relevant literature related to the non-enzymatic sensing of perovskite-based materials has been reviewed. Although the development of perovskite-based sensors is broad, as evidenced by the significant number of papers published, the works analyzed in the present review allow visualizing modifications implemented as strategies to increase the sensing performance. This results in better responses to the detection and quantification of different analytes. In general, in perovskite-based materials, catalytic activity and, therefore, sensing capacity largely depends on three relevant parameters: (i) the creation of a high surface area, small grain size, or a porous surface; (ii) the formation of oxygen vacancies; and (iii) the corresponding stoichiometry of A and B cations in the ABO3 chemical structure. Finally, it should be highlighted that the effect of modifications in perovskite composition and lattice and variations in electrode assembly became apparent. This allowed the progress of systems with a better response to detecting analytes of interest. However, the road to detection systems with higher efficiencies still has a long way to go. Among the most evident topics for future improvements are the use and synthesis of new perovskites, composites with carbon-based porous conductive materials, and variations in the sensor assembly.

Author Contributions

Conceptualization, E.A.Z.-C., C.I.P.-B., A.S.C.-D., M.C.M.-O. and C.L.-P.; investigation, E.A.Z.-C., C.I.P.-B., A.S.C.-D. and C.L.-P.; resources, E.A.Z.-C.; writing—original draft preparation, E.A.Z.-C., C.I.P.-B., A.E.-M., S.Y.R.-L. and C.L.-P.; writing—review and editing, E.A.Z.-C., C.I.P.-B. and C.L.-P.; supervision, E.A.Z.-C.; project administration, E.A.Z.-C.; funding acquisition, E.A.Z.-C. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Centro de Investigación en Materiales Avanzados, S.C. (CIMAV).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

We wish to thank CONAHCYT for the assignment of a Researcher position of the “Investigadores por México Program” for the project “Desarrollo de plataformas de sensores químicos para detección de creatinina” awarded to Claudia Ivone Piñón-Balderrama (CVU 387600).

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. (A) Schematic representation of ABO3 perovskite structure. Redox mechanism of (B) glucose, (C) urea, and (D) hydrogen peroxide.
Figure 1. (A) Schematic representation of ABO3 perovskite structure. Redox mechanism of (B) glucose, (C) urea, and (D) hydrogen peroxide.
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Figure 2. Schematic representation of the electrochemical detection of glucose sensing. Reprinted from publication. Deep eutectic solvents synthesis of perovskite-type cerium aluminate embedded carbon nitride catalyst: High-sensitive amperometric platform for sensing of glucose in biological fluids. 102, 312–320. Rajaji et al. Copyright (2021) with permission from Elsevier [66].
Figure 2. Schematic representation of the electrochemical detection of glucose sensing. Reprinted from publication. Deep eutectic solvents synthesis of perovskite-type cerium aluminate embedded carbon nitride catalyst: High-sensitive amperometric platform for sensing of glucose in biological fluids. 102, 312–320. Rajaji et al. Copyright (2021) with permission from Elsevier [66].
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Figure 3. XRD of LaSrCrNiO representative patterns calcinated at 700, 800, 900, and 1000 °C. (A) TEM micrographs of perovskite fibers (magnified in the inset), (B) HRTEM lattice fringes, and (C) electron diffraction pattern. “Reprinted (Adapted) from reference [65]”.
Figure 3. XRD of LaSrCrNiO representative patterns calcinated at 700, 800, 900, and 1000 °C. (A) TEM micrographs of perovskite fibers (magnified in the inset), (B) HRTEM lattice fringes, and (C) electron diffraction pattern. “Reprinted (Adapted) from reference [65]”.
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Figure 4. Morphology of perovskite-based materials (A) pyramids [82], (B) nanolamellate “Adapted with permission from {In situ hydrothermal synthesis of nanolamellate CaTiO3 with controllable structures and wettability, 46(19), Wang, D., Guo, Z., Chen, Y., Hao, J., & Liu, W.}. Copyright {2007} American Chemical Society [107].”, (C) nanofibers before calcination, reproduced from [65] with permission from Royal Society of Chemistry, (D) nanofibers after calcination, reproduced from reference [65] with permission of Royal Society of Chemistry, (E) nanocubes perovskites, reproduced from reference [108], and (F) hollow microcubes, adapted with permission from {Formation mechanism of CaTiO3 hollow crystals with different microstructures, 132(40), 14279–14287. Yang, X., Fu, J., Jin, C., Chen, J., Liang, C., Wu, M., & Zhou, W.}. Copyright {2010} American Chemical Society [106].
Figure 4. Morphology of perovskite-based materials (A) pyramids [82], (B) nanolamellate “Adapted with permission from {In situ hydrothermal synthesis of nanolamellate CaTiO3 with controllable structures and wettability, 46(19), Wang, D., Guo, Z., Chen, Y., Hao, J., & Liu, W.}. Copyright {2007} American Chemical Society [107].”, (C) nanofibers before calcination, reproduced from [65] with permission from Royal Society of Chemistry, (D) nanofibers after calcination, reproduced from reference [65] with permission of Royal Society of Chemistry, (E) nanocubes perovskites, reproduced from reference [108], and (F) hollow microcubes, adapted with permission from {Formation mechanism of CaTiO3 hollow crystals with different microstructures, 132(40), 14279–14287. Yang, X., Fu, J., Jin, C., Chen, J., Liang, C., Wu, M., & Zhou, W.}. Copyright {2010} American Chemical Society [106].
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Table 1. Summary of the sensing parameters of perovskites employed as non-enzymatic sensors of various biomarkers.
Table 1. Summary of the sensing parameters of perovskites employed as non-enzymatic sensors of various biomarkers.
Perovskite StructureAnalyteLOD (µM)LROD (µM)InterferenceYearRef.
LaCuO3, LaSrCuO4, LaBaCuO4, NaCuO2,
KCuO2.
H2O2---1994[22]
La0.6Ca0.4Ni0.7Fe0.3O3H2O20.50.1–1-1996[28]
La0.66Sr0.33MnO3H2O2---2009[21]
La1−xSrxMnO3H2O2---2010[23]
La1−xCaxCoO3H2O2---2012[19]
LaNiTiO3H2O20.010.05–1000AA, DA, and UA2013[27]
LaNiO3H2O20.320.05–1000AA, DA, and UA2013[24]
KNbO3H2O212--2014[26]
La0.6Sr0.4Co0.2Fe0.8O3−δH2O250–3000AA, DA, and UA2015[29]
La0.7Sr0.3Mn0.75Co0.25O3H2O20.170.5–1000AA, DA, and UA2015[25]
Ce doped SrFeO3H2O2100–500Glu, CA, Na, NO2, Ca, N, Cu, Fe.2016[30]
LaNi0.6Co0.4O3H2O20.050.2–3350AA, DA, and UA2017[20]
SmCoO3H2O20.0040.1–10,000Glu, AA, DA, and UA2018[31]
LaNiO3H2O20.0350.2–50, 50–3240Suc, Glu, Fru, Ara, Urea, CA, L-Cys, Arg, APAP, and His.2022[34]
PrBaCo2O6 (PBC), PrBaCo0.9Ni0.1O6−δ (PBCN)H2O2(0.17), (0.34)5–6950, 5–6380-2022[35]
La2CuO4
Sm2CuO4
H2O2(0.160),
(0.410)
0.50–15.87
15.87–23,350
1.24–37.20
37.20–35,440
Glu, AA, UA, L-Cys, and TrTrp2022[32]
La0.9Sr0.1NiO3H2O20.0181~7000-2023[33]
LaNi0.6Fe0.4O-CeO2Urea125 to 670 Creatinine, AA, Glu, Na+, Mg+, SO4−22018[75]
XFeO3 X=La, Ni, Fe, CeUric acidFor La = 0.20.5 to 120 -2018[79]
NdFeO3Uric acid0.351 to 120 -2019[80]
ZnSnO3Uric acid0.5501 to 5 Ca2+, Cl, Na+, K+, Glu, and AA2020[81]
CaTiO3Urea1.650 to 450 AA, H2O2, UA, catechol, resorcinol, phenol, DA, and Glu2020[82]
ZnTiO3Urea76.1630 to 150 -2021[83]
NiO/CeCuOxLipocalin4.23 ng mL−125 to 400 ng mL−1Crt, AA, human serum albumin (HSA), and hemoglobin (Hb)2021[115]
ReO3Uric acid0.061–10.5 Glu, Fe3+, Cys, Pb2+, Cd2+, and Cu2+2022[116]
La0.6Sr0.4CoO3Glucose0.052–3350DA, UA, and AA2017[64]
LaSrCoNiOGlucose83100–1000Glu, Fru, Lac, Gal, Man, DA, and AA2022[65]
CsPbBr3Glucose0.82.0 to 170.0Glu, Gly, Val, Glut, Cys, Mal, Lac,Man, Fru, and Suc2022[69]
CeAlO3Glucose0.000860.01–1034.5NO3, NO2, H2O2, FA, UA, AA, PA, DA, Epi, CPF, and NFA2021[66]
LaCoO3Glucose0.00160.01–407.2-2021[117]
SrTiO3Glucose-0–32,000NaCl, DA, UA, AA, Suc2021[67]
Pr1.92Ba0.08Ni0.95Zn0.05O4+δGlucose0.51.5 μM–7000-2020[118]
Sr2PdO3Glucose0.00210.2–100UA, AA, and DA2019[58]
NdNiO3Glucose0.30.5 to 4600AA, DA, UA, Chol, Lac, Fru, Suc, NaCl, KCl, NO2, and Na2SO42017[60]
CaTiO3Glucose2.30.7 to 1490UA and AA2017[69]
Sr1.7Ca0.3PdO3Glucose0.08455 to 5600-2016
LaTiO3Glucose0.00000250.01 to 1000Gly, Fruc, Mal, UU, AA, DP, Cu2+, Na+, Fe3+, Mn2+, and SO42−2015[70]
SrPdO3Glucose10.1100–6000UA, AA, DA, and PA2015[119]
La0.88Sr0.12MnO3Glucose-0.05–100AA, UA, and DA2015[120]
LaxSr1−xCoyFe1−yO3−δGlucose50–200AA, UA, and DA2014[62]
LiNbO3Glucose10300 to 3300UA and AA2014[11]
LaNb2O7Glucose2025 to 2830-2014[10]
LaTiO3Glucose0.212.5 to 4000AA, UA, and DA2013[59]
AA = Ascorbic acid, UA = Uric acid, DA = Dopamine, PA = Paracetamol, L-cys = L-cysteine, Arg = Arginine, TrTrp = Tryptophan, CA = Citric acid, Chol = Cholesterol, Lac = Lactose, Fruc = Fructose, Mal = Maltose, Man = Mannose, Val = Valine, Glut = Glutamate, Gal = Galactose, Suc = Sucrose, CPF = Ciprofloxacin, NFA = Norfloxacin, Epi = Epinephrine, Gly = Glycine, Crt = Creatinine, HAS = Human serum albumin, Hb = Hemoglobin.
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Piñón-Balderrama, C.I.; Leyva-Porras, C.; Conejo-Dávila, A.S.; Estrada-Monje, A.; Maldonado-Orozco, M.C.; Reyes-López, S.Y.; Zaragoza-Contreras, E.A. Electrochemical Perovskite-Based Sensors for the Detection of Relevant Biomarkers for Human Kidney Health. Chemosensors 2023, 11, 507. https://doi.org/10.3390/chemosensors11090507

AMA Style

Piñón-Balderrama CI, Leyva-Porras C, Conejo-Dávila AS, Estrada-Monje A, Maldonado-Orozco MC, Reyes-López SY, Zaragoza-Contreras EA. Electrochemical Perovskite-Based Sensors for the Detection of Relevant Biomarkers for Human Kidney Health. Chemosensors. 2023; 11(9):507. https://doi.org/10.3390/chemosensors11090507

Chicago/Turabian Style

Piñón-Balderrama, Claudia Ivone, César Leyva-Porras, Alain Salvador Conejo-Dávila, Anayansi Estrada-Monje, María Cristina Maldonado-Orozco, Simón Yobanny Reyes-López, and Erasto Armando Zaragoza-Contreras. 2023. "Electrochemical Perovskite-Based Sensors for the Detection of Relevant Biomarkers for Human Kidney Health" Chemosensors 11, no. 9: 507. https://doi.org/10.3390/chemosensors11090507

APA Style

Piñón-Balderrama, C. I., Leyva-Porras, C., Conejo-Dávila, A. S., Estrada-Monje, A., Maldonado-Orozco, M. C., Reyes-López, S. Y., & Zaragoza-Contreras, E. A. (2023). Electrochemical Perovskite-Based Sensors for the Detection of Relevant Biomarkers for Human Kidney Health. Chemosensors, 11(9), 507. https://doi.org/10.3390/chemosensors11090507

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