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Electronic tongue

An electronic tongue is a multisensor system designed to mimic the human gustatory system, comprising an array of non-specific, low-selectivity chemical sensors that detect and analyze the chemical composition of liquid samples through cross-reactivity and pattern recognition algorithms. Introduced in 1995, it serves as an objective analytical tool for taste evaluation, primarily in liquid media, by generating electrical signals from sensor interactions with analytes and processing them via multivariate data analysis to classify tastes or product qualities. Unlike human tasters, it provides rapid, reproducible results without subjective bias, making it valuable for quality control and research. The concept of electronic tongues builds on early work in biomimetic sensors, with foundational developments in the 1990s by researchers such as Iiyama, Toko, Vlasov, and Legin, who pioneered potentiometric arrays inspired by neural principles dating back to 1943. Key components include a (typically 4 to 40 units made from materials like /polymer membranes, chalcogenide glasses, or noble metals), an interface for signal acquisition, and software employing techniques such as or artificial neural networks for data interpretation. Sensor types encompass electrochemical variants (potentiometric, voltammetric, impedimetric), optical, and bio-inspired designs, often enhanced with like or carbon nanotubes for improved sensitivity. Electronic tongues find broad applications across industries, including food and beverage analysis for detecting adulteration, freshness, or flavor profiles in products like wine, , and ; pharmaceutical development for assessing drug taste-masking and formulation stability; and for identifying pollutants such as or pesticides in water. In sensory science, they correlate highly with panels (e.g., coefficients often exceeding 0.95 for attributes like astringency), enabling non-destructive, while reducing reliance on subjects. Advancements as of 2025 include integration of and hybrid systems (e.g., combined with electronic noses) to expand capabilities in diagnostics and , as well as graphene-based sensors achieving near- taste discrimination and applications in flavor simulation.

History

Origins and Early Development

The conceptual foundations of electronic tongue technology emerged in the 1980s, rooted in biomimicry of human and advancements in electrochemical detection of ions and compounds. Researchers drew inspiration from the biological gustatory system, where cells respond to multiple stimuli with global selectivity rather than high specificity, leading to early investigations into membranes as transducers for taste substances. These efforts built on electrochemical principles to mimic the interaction between taste compounds and cell membranes, focusing on potentiometric measurements to quantify basic qualities. Parallel developments occurred in , with contributions from Shigeru Iiyama and collaborators on / membrane , and in , where Yuri Vlasov and Andrei Legin initiated work around 1994 on potentiometric for liquid analysis, later popularizing the term "electronic tongue." The first prototype of an electronic tongue was developed by Kiyoshi Toko at in , with a filed in 1989 for a multichannel using / membrane electrodes. This system employed potentiometric coated with / membranes to detect the five basic tastes—sour, sweet, bitter, salty, and —by generating electrical responses proportional to substance concentrations. The prototype featured an of several electrodes, each with distinct membrane compositions to provide differential signals for of profiles. Early experiments in the early centered on these potentiometric sensors, which emulated cells through changes in induced by ions and molecules. Initial studies demonstrated the system's ability to discriminate simple solutions, such as varying concentrations of (NaCl) and (), by analyzing response patterns from the sensor array. Key publications from 1992 to 1994 highlighted these capabilities, including a 1992 study mapping profiles of samples using the multichannel to differentiate bitterness and other attributes, and a 1993 experiment successfully classifying based on their qualities like and bitterness. These works established the feasibility of electronic tongues for qualitative assessment through statistical pattern . By the mid-1990s, the development of electronic tongues benefited from cross-pollination with technologies, particularly in adopting designs and multivariate data processing for handling non-specific responses. This influence enhanced the robustness of discrimination in complex mixtures, paving the way for broader applications while maintaining the core biomimetic focus.

Key Milestones and Commercialization

In the , electronic tongues progressed significantly through the integration of multisensor arrays with chemometric software for , facilitating the shift from prototypes to commercial viability. A notable example is the Alpha MOS ASTREE system, developed and marketed around 2000, which employs seven potentiometric ChemFET sensors to evaluate liquid samples for taste attributes like saltiness, acidity, and . This decade also saw applications in EU-funded initiatives, including the project (2004–2007), which advanced multisensor arrays for real-time assessment, such as detecting contaminants in beverages and products. A pivotal milestone came in 2005 with the IUPAC technical report, which formalized an electronic tongue as a multisensor system comprising low-selectivity s coupled with advanced mathematical tools for signal acquisition, processing, and analysis, prioritizing global over individual sensor specificity. During the , innovations expanded modalities to include voltammetric and impedimetric techniques, enhancing to diverse analytes such as redox-active compounds in complex matrices. was propelled by collaborations between academic institutions and industry partners, exemplified by research at the University of into scalable technologies in the late 2000s, as well as the Insent SA402B sensing system—derived from Toko's efforts—for precise pharmaceutical profiling and optimization. By the mid-2010s, electronic tongues had transitioned from specialized instruments to routine tools in , evidenced by a surge in scientific output exceeding 100 annually by , underscoring their adoption in industrial settings for consistent product evaluation.

Principles and Components

Sensor Technologies

Electronic tongues rely on diverse technologies to mimic taste by detecting ions, redox-active compounds, and other taste-related analytes in samples through electrochemical and optical mechanisms. These form the core of the system, generating signals based on interactions with tastants such as acids, salts, and bitter substances, enabling the of basic tastes like sour, salty, bitter, sweet, and . The choice of sensors draws from established electrochemical principles, with adaptations for cross-sensitivity to handle complex mixtures without high specificity to individual compounds. Potentiometric sensors, the most common in electronic tongues, utilize ion-selective electrodes (ISEs) featuring or membranes that respond to specific ions by measuring potential differences across the membrane. These electrodes are particularly effective for detecting cations like Na⁺ (associated with saltiness) and H⁺ (linked to sourness), where the potential change is governed by the : E = E_0 + \frac{RT}{zF} \ln a Here, E is the measured potential, E_0 is the standard potential, R is the , T is the absolute temperature, z is the charge number of the ion, F is the , and a is the ion activity. This non-specific cross-response allows arrays of such ISEs to profile overall profiles in solutions. Early developments in the 1990s established potentiometric arrays as foundational for electronic tongues, with -based membranes enhancing selectivity for taste ions. Voltammetric sensors operate by applying a varying potential to working electrodes, typically or , and measuring resulting current transients to characterize redox-active tastants. , a prevalent technique, produces current-voltage curves where oxidation or reduction peaks reveal the presence of bitter compounds like through distinct peak currents and potentials. These sensors provide dynamic information on kinetics, complementing static potentiometric measurements for broader discrimination. Seminal work in the early 2000s demonstrated their utility in electronic tongues for food analysis, highlighting advantages in sensitivity to organic tastants. Impedimetric sensors quantify taste by monitoring changes in electrical impedance at sensor-solution interfaces, often using interdigitated electrodes to detect variations in charge transfer resistance or induced by tastants. Conductometric detection, a low-frequency subset, measures solution conductivity shifts for umami-related glutamates or astringent polyphenols. Optical sensors, employing fluorometry or , capture taste-induced changes in light emission or transmission, such as for astringency in infusions or for umami compounds. These methods extend detection to non-electroactive tastants, with impedimetric arrays showing robustness in complex matrices since the . Hybrid approaches integrate bioinspired elements into traditional sensors to improve selectivity and sensitivity, such as enzyme-immobilized s for specific tastant recognition or nanomaterial modifications like on surfaces since the 2010s. As of 2025, soft and flexible hydrogel-based sensors, inspired by saliva-like chemiresistive materials, have been developed to detect in foods by mimicking protein binding mechanisms. hybrids enhance and surface area, enabling detection of low-concentration analytes mimicking biological receptors. These bioelectronic designs, often combining voltammetric or potentiometric bases with biomolecules, have advanced electronic tongues toward greater mimicry of human gustation. Sensor arrays in electronic tongues typically comprise 5-20 diverse , selected for overlapping sensitivities to generate multidimensional response patterns that capture the collective profile of mixtures. This design principle, rooted in cross-reactive sensing, allows pattern-based identification rather than isolated detection, with array configurations optimized for specific applications through empirical validation. of these arrays into portable systems facilitates real-time analysis.

System Architecture

The system architecture of an electronic tongue integrates a multisensor with supporting and software to enable collective sensing of chemical profiles in liquid samples. The core components typically include a housed within a , consisting of multiple electrochemical sensors (such as potentiometric or voltammetric types) that generate electrical signals in response to analytes. These arrays are paired with reference electrodes, often Ag/AgCl types, to provide a stable potential reference during measurements. Additionally, a pretreatment chamber is incorporated for sample conditioning, involving processes like or dilution to reduce interferences and enhance sensor reliability. The unit forms the backbone, featuring analog-to-digital converters (ADCs) and multiplexers that simultaneously process signals from the , converting analog outputs into for . Sampling rates vary by system and type; for example, 1 Hz (one sample per second) is used in potentiometric measurements to capture steady-state responses. This setup ensures synchronized handling of multi-channel inputs, minimizing and enabling logging. Interface layers facilitate sample-sensor interaction, primarily through flow cells for controlled liquid delivery or setups where the probe is directly submerged in the sample. These are often equipped with automated stirring or pumping mechanisms to promote uniform distribution and reproducible contact, critical for consistent signal generation across sensors. The software backbone relies on embedded microcontrollers to manage signal preconditioning, including amplification to boost weak sensor outputs and noise filtering to eliminate artifacts from environmental factors. This preprocessing occurs prior to data transmission for higher-level pattern recognition, ensuring clean inputs for subsequent analysis stages. Portability trends in electronic tongue designs have evolved significantly, shifting from bulky benchtop systems prevalent in the 1990s—often requiring laboratory power and manual operation—to compact, battery-powered configurations by the 2020s that support field deployment. These modern iterations, such as simplified potentiometric arrays integrated with data loggers, maintain analytical performance while enhancing mobility for on-site applications like water quality monitoring.

Operation and Data Analysis

Measurement Process

The measurement process of an electronic tongue involves a standardized sequence of steps to ensure reliable capture of taste-related signals from samples, typically using a multisensor array immersed in controlled conditions. samples, such as beverages or pharmaceutical solutions, are prepared by dilution in aqueous media to volumes of 10-100 mL, often with co-solvents like to enhance while maintaining physiological relevance, and filtered if necessary to remove . This preparation occurs in a contamination-free , such as a sealed chamber, to prevent external influences on responses. Sensors within the array, consisting of /polymer membranes or electrochemical probes as described in the system architecture, are then immersed in the prepared sample either sequentially or simultaneously. Exposure duration ranges from 30 to 120 seconds, during which transient and steady-state signals—such as potentiometric potentials or voltammetric currents—are recorded to capture the dynamic interaction between the sample and surfaces. Multiple acquisitions (e.g., 3-10 measurements per sample) are often performed, discarding initial readings to stabilize the signal and focus on reproducible steady-state data. Prior to each measurement series, a routine baselines the sensors using standard taste solutions, such as quinine hydrochloride for bitterness or , to verify response within specified ranges (e.g., relative standard deviation <4%) and compensate for potential drift via reference electrode potentials aligned with the Nernst equation. Following sample exposure, an automated cleaning cycle rinses the sensors with deionized water, ethanol-based solutions (e.g., 30% ethanol with HCl or KCl), or reference buffers for 10-60 seconds to eliminate residue and prevent carryover between analyses, with longer washes (up to 330 seconds) for thorough decontamination. The process culminates in the generation of raw output as multidimensional datasets, comprising voltage or current profiles (e.g., relative values calculated as sample potential minus reference potential, in mV) that represent the collective sensor responses for subsequent pattern analysis. These profiles, often including aftertaste metrics from post-cleaning reference measurements, provide a comprehensive snapshot of the sample's taste attributes without further processing at this stage.

Pattern Recognition Methods

Pattern recognition methods transform the multidimensional sensor responses from electronic tongues into interpretable taste profiles, enabling discrimination, classification, and quantification of samples. These computational techniques handle the inherent complexity and noise in data from sensor arrays, often comprising potentiometric, voltammetric, or impedimetric signals, to mimic human taste perception through statistical and machine learning approaches. Unsupervised and supervised algorithms are predominantly applied, with preprocessing ensuring data quality for reliable analysis. Data preprocessing is fundamental to mitigate variability, noise, and baseline drifts in raw sensor signals. Normalization via z-score standardization subtracts the mean and divides by the standard deviation for each feature, yielding data with zero mean and unit variance to facilitate comparison across sensors and samples. Feature extraction from transient signals, such as extracting maximum response, slope, or integral values from dynamic curves, further reduces dimensionality while preserving taste-relevant information. These steps enhance subsequent pattern recognition by addressing sensor drift and environmental influences. Unsupervised methods like Principal Component Analysis (PCA) perform dimensionality reduction and clustering without labeled data, revealing inherent structures in e-tongue datasets. PCA achieves this by projecting data onto principal axes that capture maximum variance, via eigenvalue decomposition of the covariance matrix \Sigma: \Sigma = U \Lambda U^T Here, \Lambda is the diagonal matrix of eigenvalues representing variances along each principal component, and the columns of U are the corresponding eigenvectors serving as the projection directions. This technique visualizes sample groupings, such as distinguishing beverage types, by retaining the first few components that explain most variance (often >90%). Supervised methods leverage labeled training for targeted predictions. Partial Least Squares (PLS) models quantitative attributes, such as bitterness or sweetness levels, by constructing latent variables that maximize covariance between sensor inputs and responses, outperforming simple linear models in handling collinear from e-tongue arrays. Artificial Neural Networks (ANN), including multilayer perceptrons, excel in classifying mixtures through non-linear mappings, achieving high rates for multi-component samples like wines or teas. For example, ANN models have demonstrated up to 99.14% accuracy in quality grading tasks. Linear Discriminant Analysis (LDA) serves as another supervised technique for taste discrimination, optimizing feature projections to maximize between-class separation while minimizing within-class variance. Cross-validation, such as leave-one-out, assesses model robustness by iteratively training on all but one sample, with e-tongue implementations frequently exceeding 90% accuracy; notable examples include 98.83% classification rates for wastewater samples using LDA. Validation of these models relies on metrics that quantify performance in blind tests. Confusion matrices tabulate true positives, false positives, and errors across classes, providing , , and overall accuracy for multi-class taste identification. (ROC) curves plot true positive rate against , with the area under the curve () indicating discriminative power, often approaching 1.0 in optimized e-tongue systems. These tools ensure generalizability beyond training data.

Applications

Food and Beverage Industry

In the food and beverage industry, tongues (e-tongues) play a crucial role in by enabling rapid detection of spoilage and ensuring product consistency. For instance, AI-enhanced e-tongues have been developed to assess dilution levels and freshness in fruit juices, identifying spoilage through chemical changes with over 80% accuracy across various liquid samples. A 2025 study utilizing graphene-based sensors further demonstrated the ability to detect early spoilage in juices by analyzing volatile compounds and shifts, allowing for non-invasive monitoring during storage. Similarly, in brewing, e-tongues based on potentiometric ion-selective electrodes have classified different commercial beer types and predicted alcoholic strength since the early , to maintain batch uniformity. E-tongues facilitate flavor profiling in by providing non-destructive measurements of key attributes like , acidity, and ripeness. In analysis, voltammetric e-tongues assess phenolic content to determine optimal times, correlating responses with sensory panel evaluations for classification. This approach minimizes destructive sampling, enabling real-time adjustments in production to enhance wine quality and reduce variability across vintages. For shelf-life monitoring, voltammetric e-tongues track oxidation processes in oils and products, predicting expiration dates with high predictive accuracy. In applications, these systems analyze fresh samples over storage periods, detecting microbial growth and oxidation to forecast . For edible oils, e-tongues detect adulteration and assess content non-invasively. Adulteration detection represents another key application, where e-tongues identify or diluted beverages through deviations in patterns. Potentiometric e-tongues have quantified additives in soft drinks, distinguishing authentic formulations from diluted versions by analyzing ionic profiles and levels with semi-quantitative precision. In fruit juices, these devices detect water or sugar syrup adulteration by , offering a faster alternative to chromatographic methods for . In , e-tongues integrated with electronic noses monitor for and detect nutrient levels in extracts, supporting sustainable farming practices and crop health assessment. Integration of e-tongues into large-scale production lines supports batch uniformity by automating sensory assessments, significantly reducing reliance on costly human taste panels. In beverage manufacturing, portable e-tongue systems enable inline monitoring of flavor consistency across production runs, correlating outputs with traditional quality metrics to streamline operations and lower evaluation expenses. This adoption has been particularly impactful in breweries and juice processors, where real-time data fusion enhances and without compromising product standards.

Pharmaceutical and Medical Uses

Electronic tongues have been instrumental in pharmaceutical development since the early for taste masking in oral formulations, particularly to reduce bitterness in pediatric medications and improve patient compliance. These systems assess bitterness intensity by correlating sensor responses to standard references like equivalents, enabling the evaluation of masking agents such as sweeteners, flavors, or coatings in drugs like antibiotics and antihistamines. For instance, electronic tongue analysis has demonstrated up to 80% reduction in perceived bitterness for sublingual tablets containing bitter active pharmaceutical ingredients through the addition of non-medicinal ingredients like and . In formulation optimization, electronic tongues predict drug release profiles by simulating dissolution in saliva mimics, providing rapid in vitro data that correlates strongly with human sensory panels. Correlation coefficients exceeding 0.9 (e.g., R² = 0.910) have been reported between electronic tongue outputs and human taste assessments for bitter compounds such as H1-receptor antagonists, allowing developers to refine excipient compositions for controlled release and palatability. This approach facilitates the design of oral dosage forms, such as orodispersible tablets, where taste-masking efficiency is quantified without extensive human testing. Beyond , electronic tongues support medical diagnostics by analyzing biofluids like and for markers, including alterations in taste profiles indicative of conditions such as cancer. In samples, voltammetric electronic tongues combined with have discriminated oral cavity cancer patients from healthy individuals with high accuracy (up to 95% ), detecting subtle electrochemical changes linked to biomarkers. Similarly, for analysis, potentiometric and spectroscopic electronic tongues have achieved over 96% accuracy in identifying bladder and cancers non-invasively, leveraging to profile volatile and ionic metabolites altered by . Electronic tongues contribute to in pharmaceutical testing, particularly for equivalence, by providing objective data on taste profiles that align with results, thereby reducing the reliance on costly and ethically challenging or trials. Their validated methods support demonstrations under frameworks like those from the FDA, where sensor arrays confirm formulation similarity in bitterness and release behavior for orally disintegrating generics. A notable recent advancement is the 2024 Penn State University electronic tongue, which integrates ion-sensitive sensors with for high-accuracy identification of liquid compositions, enabling rapid screening of medication consistency and potential adulteration in oral liquids. This AI-enhanced system achieves over 80% accuracy in distinguishing subtle differences in samples, offering a scalable tool for pharmaceutical .

Environmental Monitoring

Electronic tongues have been deployed for water quality assessment in natural bodies such as rivers and lakes, utilizing multisensor arrays to detect like (Cd(II)), (Cu(II)), lead (Pb(II)), and zinc (Zn(II)), as well as pesticides including and , and organic pollutants such as compounds. These systems employ potentiometric, voltammetric, and amperometric sensors to generate toxicity profiles through , enabling the discrimination of contaminant mixtures at levels. For instance, a potentiometric electronic tongue with ion-selective electrodes achieved detection of like Cd(II) at levels in water samples. Similarly, an amperometric bioelectronic tongue incorporating enzymatic biosensors quantified pesticides in water with high accuracy using artificial neural networks. A voltammetric bioelectronic tongue monitored pollutants in , demonstrating real-time tracking of degradation processes. Portable electronic tongues facilitate on-site pollution tracking in industrial effluents, allowing discrimination of shifts, ionic imbalances, and concentrations without laboratory intervention. These devices, often equipped with radio modems for data transmission up to 15 miles, monitor effluents in , with sensitivities reaching 5.2 × 10⁻⁸ M for Cu²⁺ and Pb²⁺ in waste streams near industrial sites. Potentiometric arrays have quantified , sodium, and ions in polluted at concentrations from 7.3 × 10⁻⁶ M to 1.5 × 10⁻² M, achieving coefficients exceeding 0.9. Such portability supports rapid field assessments, outperforming traditional methods in deployment speed while maintaining low power consumption around 500 mW. Bibliometric analyses reveal over 50 studies on electronic tongues for environmental aqueous samples since 2010, reflecting a surge in applications for monitoring with sensitivities down to parts-per-billion (ppb) levels for various contaminants. This growth underscores the shift toward , low-cost alternatives to conventional techniques, with key contributions from voltammetric and potentiometric systems in profiling complex matrices. Integration with (IoT) enables wireless electronic tongues for continuous data logging in remote areas, providing alerts for anomalies such as algal blooms via toxin detection like microcystins. Autonomous systems, such as those deployed on unmanned vessels, facilitate long-term and monitoring with frameworks for data transmission and analysis. Recent examples from 2023 include electronic tongues using screen-printed electrodes to detect at 0.02 ppm in compliance with limits (e.g., 0.0001 mg/L per pesticide), offering over 90% accuracy and faster results than . These advancements support regulatory adherence under directives like 2006/118/EC, enhancing ecological surveillance.

Mimicry of Human Taste and Limitations

Relation to Biological Taste Perception

The human gustatory system detects five basic tastes—sweet, sour, salty, bitter, and —via specialized receptors located in clustered within papillae on the and oral cavity. Sweet taste is mediated by the heterodimeric G-protein-coupled receptors T1R2 and T1R3, which bind sugars and artificial sweeteners to initiate signaling cascades involving phospholipase Cβ2 and M5 (TRPM5). Umami perception occurs through T1R1/T1R3 receptors responsive to like glutamate, while sour taste is transduced by PKD2L1 (a polycystin channel) and OTOP1 proton channels that detect acidity via influx. Salty taste relies on epithelial sodium channels (ENaC), and bitter taste is sensed by approximately 25 T2R family receptors tuned to diverse aversive compounds. These receptors convert chemical stimuli into electrical signals through ion channels and second messengers, generating patterned neural activity relayed to the and for taste interpretation. Electronic tongues approximate this receptor diversity not through specific molecular bindings but via arrays of cross-selective, low-specificity sensors that produce collective, multidimensional response profiles akin to holistic "taste maps." Each sensor interacts broadly with multiple analytes, mimicking the overlapping sensitivities of ensembles rather than isolated receptor-ligand interactions, and the resulting patterns are analyzed using multivariate methods to classify or quantify tastes. This global selectivity enables e-tongues to emulate the integrative output of biological taste cells without replicating their biochemical specificity. As defined by the International Union of Pure and Applied Chemistry (IUPAC), an electronic tongue comprises a nonspecific coupled with or multivariate calibration to process cross-sensitive signals from complex solutions. Key differences arise in perceptual integration: human taste perception fuses gustatory signals with olfactory, tactile, and thermal inputs via multisensory regions, yielding a rich experience shaped by and experience, whereas e-tongues isolate chemical signatures from dissolved tastants for objective profiling. Despite these limitations, e-tongues often correlate strongly with human sensory judgments; for instance, in wine analysis, potentiometric e-tongue responses aligned closely with expert panel ratings for attributes like bitterness and astringency, demonstrating reliable in blind assessments. This artificial prioritizes global selectivity for broad detection, in contrast to the evolutionary fine-tuning of human receptors for specific survival cues, such as energy-rich nutrients or toxins. E-tongue architectures are evolutionarily inspired by the spatial organization of into clustered papillae, where distributed receptor responses converge on neural pathways for centralized decoding, though electronic systems forgo the biological adaptability, such as receptor and learning-mediated refinement seen in humans.

Challenges and Future Directions

tongues face several technical challenges that limit their widespread adoption. Sensor drift, caused by environmental factors or material degradation, necessitates frequent recalibration to maintain accuracy, posing ongoing burdens. Limited capability for detecting volatile compounds, which is better addressed by electronic noses, can necessitate hybrid systems for comprehensive analysis in complex matrices. Additionally, high initial costs for commercial systems restrict accessibility, particularly for small-scale users. remains problematic due to variability in sensor designs and outputs across vendors, complicating comparability and regulatory approval. Recent advancements address some of these issues by enhancing portability and analytical capabilities. In 2025, hydrogel-based in-tape electronic tongues emerged as a low-cost, disposable solution for rapid beverage classification, enabling sequential analysis of liquids like juices and coffees with high accuracy through ion-selective hydrogel pores. AI-enhanced models integrated with electronic tongues have also progressed, providing insights into the AI's decision-making processes—often termed "inner thoughts"—to improve flavor discrimination and early spoilage detection in products such as milk and wine. These developments, including a 2024 study reported in 2025, achieve high accuracy (>95%) in taste differentiation for subtle variations. Further 2025 advancements include voltammetric e-tongues for shelf-life evaluation and AI integration for pharmaceutical taste masking. Looking ahead, future directions emphasize hybrid systems and ethical integration. Combining electronic tongues with electronic noses could create comprehensive sensory arrays for multimodal analysis in and . Biohybrid approaches incorporating living cells promise greater adaptability to dynamic samples, though they require overcoming challenges. In pharmaceuticals, electronic tongues support reducing by simulating taste profiles in drug formulation, aligning with ethical shifts toward non-invasive methods. However, AI-driven applications in raise data privacy concerns, necessitating robust safeguards to protect sensitive ecological datasets.

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