Control Of Behavior Research Articles

Sensor for a Solid–Liquid Tribological System

Solid–liquid lubrication systems have been widely used to enhance tribological behaviors. Alongside offering exceptional lubrication and wear-resistance performance, the active control of the tribological behavior of lubrication systems in accordance with service conditions is equally critical. To achieve this goal, accurately monitoring the condition of the lubrication system is fundamental. This review article aims to provide a fundamental understanding of different sensors for monitoring the condition of lubricants, as well as the friction and wear properties. Specifically, the sensors suitable for engineering applications are detailed introduced. Through this review, we wish to provide researchers in mechanical engineering with a clear technical overview, which can guide the design of intelligent lubrication systems with suitable sensors.

Phenanthrene Treatment for O‐xylene‐Processed PM6:Y6‐Based Organic Solar Cells Enables Over 19% Efficiency

AbstractAchieving excellent charge transport properties in high‐performance organic solar cells (OSCs) generally requires photovoltaic materials to have strong crystallinity. Meanwhile, non‐halogenated solvent processing is very important for future application of the OSCs. However, highly crystalline materials will pose challenges for the control of molecular aggregation behavior in donor/acceptor blend films processed with high boiling point non‐halogenated solvents. Herein, a new approach to effectively regulate the aggregation of represented strong crystallinity material Y6 in high boiling point processing solvents is developed by employing phenanthrene (PAT) with unique crystallinity and relatively loose molecular stacking as volatile solid additive. It is elucidated that PAT treatment shows a significant effect in inhibiting the excessive self‐aggregation of Y6 in high boiling point solvent during the film formation process and reducing the crystallization rate of Y6 molecules under thermal annealing, resulting in highly ordered molecular packing and favorable phase‐separated morphology. As a result, the PM6:Y6‐based device processed with chlorobenzene, toluene, and o‐xylene achieve excellent power conversion efficiencies (PCEs) of 17.71%, 17.99%, and 19.04%, respectively. The efficiency of 19.04% represents the highest value so far for the PM6:Y6‐based binary OSCs processed with high boiling point non‐halogenated solvents.

Occlusal acuity and bite force in young adults.

Occlusal tactile acuity (OTA) and bite force are essential components of the sensorimotor control of oral behaviors. While these variables have been studied independently, it has not yet been revealed whether compressive force impacts the occlusal perception mediated by the mechanoreceptive afferents in the periodontal ligament. The present study examined the effect of repetition and maximum bite force on OTA by testing nine aluminum foils of different thicknesses together with a sham test with no foil, three times each, in randomized order in 36 healthy individuals. In addition, the 40 μm foil was tested three more times at the start of each session to evaluate possible short-term effects. This test session was repeated with and without an interspersed maximum bite force task in between. The results demonstrated that repeated measurements increased OTA significantly (p = 0.033); a change mainly driven by the 40 μm thickness, whereas maximum bite force tests did not affect OTA (p = 0.097). Collectively, the results suggest that the enhanced OTA may be attributed to repetition-mediated learning and neuroplasticity within the pathways related to OTA. Furthermore, the compressive bite force may have induced a short-term change that lasted seconds and was not detected by the subsequent OTA measurements or may have altogether inhibited the facilitatory effect of repeated OTA. This underscores the potential for future research to explore the implications of compressive force and pain on OTA in patient populations, which could provide valuable insights into the adaptive mechanisms of the sensorimotor system in pathological conditions.

Iono‐Optic Impedance Spectroscopy (I‐OIS): A Model‐Less Technique for In Situ Electrochemical Characterization of Mixed Ionic Electronic Conductors

AbstractFunctional properties of mixed ionic electronic conductors (MIECs) can be radically modified by (de)insertion of mobile charged defects. A complete control of this dynamic behavior has multiple applications in a myriad of fields including advanced computing, data processing, sensing or energy conversion. However, the effect of different MIEC's state‐of‐charge is not fully understood yet and there is a lack of strategies for fully controlling the defect content in a material. In this work we present a model‐less technique to characterize ionic defect concentration and ionic insertion kinetics in MIEC materials: Iono‐Optic Impedance Spectroscopy (I‐OIS). The proof of concept and advantages of I‐OIS are demonstrated by studying the oxygen (de)insertion in thin films of hole‐doped perovskite oxides. Ion migration into/out of the studied materials is achieved by the application of an electrochemical potential, achieving stable and reversible modification of its optical properties. By tracking the dynamic variation of optical properties depending on the gating conditions, I‐OIS enables to extract electrochemical parameters involved in the electrochromic process. The results demonstrate the capability of the technique to effectively characterize the kinetics of single‐ and even multi‐layer systems. The technique can be employed for studying underlying mechanisms of the response characteristics of MIEC‐based devices.

Resilience of Gen-Z people with disabilities against the dark joke phenomenon: Qualitative research

Humor or jokes have become an integral part of social life. The Gen-Z group's response to humor is strange, especially for those above 25 years old. It is often characterized by an absurd and dark sense of humor. This will certainly cause contradictions from many parties, especially for people with disabilities who feel themselves to be the butt of jokes. In responding to dark jokes, a person with a disability uses resilience to maintain their self-actualization in the community. The objectives of this study are (1) to analyze the resilience dynamics of Gen-Z people with physical disabilities towards the dark joke phenomenon. The method used in this research is qualitative research with phenomenological design. Data collection was conducted by in-depth interviews with 3 key informants and 3 supporting informants. The results of this study indicate that aspects of resilience that arise include (1) emotion regulation; (2) Reaching out; (3) Imput control of negative behavior; (4) use of dark jokes; (5) optimism and support from the surrounding environment; (6) self-adjustment; and (7) self-efficacy. People with disabilities also use coping mechanisms as a problem-solving strategy that includes emotion focused coping and problem focused coping. Through resilience and coping owned by people with disabilities, they are able to actualize themselves and accept their physical limitations.

Sub-second characterization of locomotor activities of mouse models of Parkinsonism.

The degeneration of midbrain dopamine (DA) neurons disrupts the neural control of natural behavior, such as walking, posture, and gait in Parkinson's disease. While some aspects of motor symptoms can be managed by dopamine replacement therapies, others respond poorly. Recent advancements in machine learning-based technologies offer opportunities for unbiased segmentation and quantification of natural behavior in both healthy and diseased states. In the present study, we applied the motion sequencing (MoSeq) platform to study the spontaneous locomotor activities of neurotoxin and genetic mouse models of Parkinsonism as the midbrain DA neurons progressively degenerate. We also evaluated the treatment efficacy of levodopa (L-DOPA) on behavioral modules at fine time scales. We revealed robust changes in the kinematics and usage of the behavioral modules that encode spontaneous locomotor activity. Further analysis demonstrates that fast behavioral modules with higher velocities were more vulnerable to loss of DA and preferentially affected at early stages of Parkinsonism. Last, L-DOPA effectively improved the velocity, but not the usage and transition probability, of behavioral modules of Parkinsonian animals. In conclusion, the hypokinetic phenotypes in Parkinsonism are mediated by the decreased velocities of behavioral modules and the disrupted temporal organization of sub-second modules into actions. Moreover, we showed that the therapeutic effect of L-DOPA is mainly mediated by its effect on the velocities of behavior modules at fine time scales. This work documents robust changes in the velocity, usage, and temporal organization of behavioral modules and their responsiveness to dopaminergic treatment under the Parkinsonian state.

Motor Control on the Move - from Insights in Insects to General Mechanisms.

This review discusses how the nervous system controls the complex body movements keeping animals up and running. In particular, we revisit how research in insects has shed light onto motor control principles that govern movements across the animal kingdom. Starting with the organization and evolution of the insect nervous system, we discuss insights into the neuronal control of behaviors varying in complexity, including escape, flight, crawling, walking, grooming, and courtship. These behaviors share specific control features. For instance, central pattern generating circuits (CPG), which reside in proximity to the motor neurons and muscles, support the generation of rhythmic motor activity. The number of CPGs involved depends on the complexity of the motor apparatus controlled, such as wing pairs for flight, or six pairs of multi-segmented legs for walking. The different control architectures are introduced with respect to their organization, topology, and operation. Sensory feedback plays a pivotal role in shaping CPG activity into a functional, well-coordinated motor output. The activity of motor circuits is orchestrated by descending neurons connecting the brain to the ventral nerve cord or spinal cord, which initiate, maintain, modulate, and terminate different actions. We therefore discuss the current understanding of descending control, and the contributions of individual, command-like descending neurons and population codes. To highlight how insights in insects help discover fundamental motor control principles, we cross-reference findings from other animals, particularly vertebrates. Additionally, we discuss methodological advances that enabled breakthroughs in motor control research, including neurogenetics and connectomics, and discuss key open questions.

Forceps minor control of social behaviour.

The PRISM project, funded by the EU's Innovative Medicines Initiative, has identified a transdiagnostic, pathophysiological relationship between the integrity of the default mode network (DMN) and social dysfunction. To explore the causal link between DMN integrity and social behaviour, we employed a preclinical back-translation approach, using focal demyelination of the forceps minor to disrupt DMN connectivity in mice. By applying advanced techniques such as functional ultrasound imaging and automated analysis of social behaviour, we demonstrated that reduced DMN connectivity leads to impaired social interactions and increased anxiety in mice. Notably, these effects were reversible, indicating that the forceps minor, a critical fibre tract connecting key DMN regions in the prefrontal cortex, plays a crucial role in social function. This study provides direct evidence for a causal relationship between DMN integrity and social dysfunction, with potential implications for developing targeted treatments in precision psychiatry.

From Chains to Arrays: Substrate-Mediated Self-Assembly of Diboron Molecules.

In this study, we explore the substrate-mediated control of self-assembly behavior in diboron molecules (C12H8B2O4, B2Cat2) using scanning tunneling microscopy (STM). The structural transformation of B2Cat2 molecules from one-dimensional (1D) molecular chains to two-dimensional (2D) molecular arrays was achieved by changing the substrate from Au(111) to bilayer graphene (BLG), highlighting the key role of substrate interactions in determining the assembly structure. Notably, the B-B bond in the molecular arrays on BLG is distinctly pronounced, reflecting a more refined molecular resolution with distinct electronic states than that on Au(111). Density functional theory (DFT) calculations confirm the weak interaction between B2Cat2 molecules and the BLG substrate, which facilitates the formation of 2D molecular arrays on BLG. This work demonstrates how controlling substrate properties enables the formation of 1D chains and 2D arrays, providing valuable insights for the design of next-generation molecular electronics and catalysis systems.

Prefrontal electrophysiological biomarkers and mechanism-based drug effects in a rat model of alcohol addiction

Patients with alcohol use disorder (AUD) who seek treatment show highly variable outcomes. A precision medicine approach with biomarkers responsive to new treatments is warranted to overcome this limitation. Promising biomarkers relate to prefrontal control mechanisms that are severely disturbed in AUD. This results in reduced inhibitory control of compulsive behavior and, eventually, relapse. We reasoned here that prefrontal dysfunction, which underlies vulnerability to relapse, is evidenced by altered neuroelectric signatures and should be restored by pharmacological interventions that specifically target prefrontal dysfunction. To test this, we applied our recently developed biocompatible neuroprosthesis to measure prefrontal neural function in a well-established rat model of alcohol addiction and relapse. We monitored neural oscillations and event-related potentials in awake alcohol-dependent rats during abstinence and following treatment with psilocybin or LY379268, agonists of the serotonin 2A receptor (5-HT2AR), and the metabotropic glutamate receptor 2 (mGluR2), that are known to reduce prefrontal dysfunction and relapse. Electrophysiological impairments in alcohol-dependent rats are reduced amplitudes of P1N1 and N1P2 components and attenuated event-related oscillatory activity. Psilocybin and LY379268 were able to restore these impairments. Furthermore, alcohol-dependent animals displayed a dominance in higher beta frequencies indicative of a state of hyperarousal that is prone to relapse, which particularly psilocybin was able to counteract. In summary, we provide prefrontal markers indicative of relapse and treatment response, especially for psychedelic drugs.

Precision Control of Cell Type-Specific Behavior via RNA Sensing and Editing.

In the realms of bioengineering and biopharmaceuticals, there exists a critical demand for advanced genetic tools that can interact with specific cell signaling pathways to accurately identify and target various cell types. This research introduces the innovative CRISPR-ADAReader system, which enables precise manipulation of cell activity through sensing target RNA. Featuring both positive and negative feedback loops, the system allows for tailored regulation across different cell types in response to various internal signals, showcasing exceptional programmability, specificity, and sensitivity. By choosing distinct RNAs as activation signals, the CRISPR-ADAReader efficiently monitors and alters targeted cell behaviors. In a case study focusing on retinoblastoma treatment, the system distinctively initiates positive feedback and self-silencing actions by detecting MCYN and Rb transcripts, thus safeguarding normal retinal pigment epithelial cells while promoting apoptosis in cancer cells. Moreover, the CRISPR-ADAReader demonstrates significant anti-tumor effectiveness in live models, markedly reducing retinoblastoma cell proliferation through the activation of several cancer-suppression pathways, outperforming the capabilities of the ADAR-sensor. Notably, the system also shows an excellent in vivo safety profile. In conclusion, the CRISPR-ADAReader system represents a groundbreaking method for the detection and editing of RNA, offering a potent instrument for the customized and precise governance of cell behavior.

Stimulus conditions that promote habitual control

Two experiments in rats examined how training where a stimulus signaled when to respond for reward, conditions that should favour S-R learning, might lead to habitual control of behaviour. Experiment 1 investigated how animals trained with a stimulus preceding lever insertion would impact learning relative to a group that was self-paced and could control lever insertion with a second, distinct response. Rats were then tested for sensitivity to outcome devaluation to distinguish between goal-directed and habitual control. We found that free-operant, self-paced conditions promoted goal-directed control while signaling trials with a stimulus promoted habitual control evidenced as insensitivity to outcome devaluation. Experiment 2 assessed whether the stimulus-outcome association is important for driving habitual responding when training occurs with a traditional discriminative stimulus. A comparison group was trained under free-operant conditions and experienced the same stimulus presented alongside the earned reward. Following devaluation, animals trained under discriminated-operant conditions had reduced goal-directed control, but only after extended training. The free-operant group remained goal-directed, even after extended training, and their performance was not altered by stimulus presentations, suggesting effects of a stimulus-outcome association were unlikely to account for the deficit in the discriminative stimulus group. These results extend understanding of how stimuli present during instrumental training promote the development of habitual control.

The microRNA-29ab1/Zfp36/AR Axis in the Hypothalamus Regulates Male-Typical Behaviors in Mice.

Male-typical behaviors such as aggression and mating, which reflect sexual libido in male mice, are regulated by the hypothalamus, a crucial part of the nervous system. Previous studies have demonstrated that microRNAs (miRNAs), especially miR-29, play a vital role in reproduction and the neural control of behaviors. However, it remains unclear whether miR-29 affects reproduction through the hypothalamus-mediated regulation of male-typical behaviors. Here, we constructed two mouse knockout models by ablating either the miR-29ab1 or miR-29b2c cluster. Compared to WT, the ablation of miR-29ab1 in male mice significantly reduced the incidence of aggression by 60% and the incidence of mating by 46.15%. Furthermore, the loss of miR-29ab1 in male mice led to the downregulation of androgen receptor (AR) in the ventromedial hypothalamus. Transcriptomic analysis of the hypothalamus of miR-29ab1-deficient mice revealed inflammatory activation and aberrant expression of genes associated with male-typical behaviors, including Ar, Pgr, Htr4, and Htr2c. Using bioinformatics analysis and dual-luciferase reporter assays, we identified zinc finger protein 36 (Zfp36) as a direct downstream target gene of miR-29ab1. We subsequently showed that ZFP36 colocalized with AR in GT1-7 cells. Furthermore, inhibition of Zfp36 or RelB in GT1-7 cells led to an increase in AR expression. Collectively, our results demonstrate that the miR-29ab1/Zfp36/AR axis in the hypothalamus plays a pivotal role in the regulation of aggression and mating in male mice, providing a potential therapeutic target for treating infertility caused by low libido.

The effect of early weaning on feeding behavior parameters in rodents: A systematic review.

Breastfeeding is essential for somatic development, especially neurodevelopment. The abrupt termination of the mother-child bond, early weaning, is a stressful event during the neonatal period. This has lifelong consequences. The impact on neural plasticity will be reflected in behavioral expression, including feeding behavior. This behavior is modulated by encephalic and peripheral structures, such as the serotonergic and dopaminergic neurotransmission systems, as well as hormonal signaling, leptin, and ghrelin. The central nervous system, particularly the hypothalamus, receives information from the gastrointestinal tract to regulate hunger and satiety. Early weaning alters these mechanisms that control feeding behavior. The alterations most commonly reported in the literature are hyperphagia, increased body mass, and molecular alterations related to the control of feeding behavior. Studies have attempted to identify the factors involved in the changes in feeding behavior control caused by early weaning. Furthermore, pharmacological interventions, herbal medicines, calcium supplementation, and physical activity have been investigated as potential means of reversing these changes. Consequently, the objective of this literature review was to analyze the effects of early weaning on the modulation of parameters that act to control feeding behavior.

Genetically-stable engineered optogenetic gene switches modulate spatial cell morphogenesis in two- and three-dimensional tissue cultures

Recent advances in tissue engineering have been remarkable, yet the precise control of cellular behavior in 2D and 3D cultures remains challenging. One approach to address this limitation is to genomically engineer optogenetic control of cellular processes into tissues using gene switches that can operate with only a few genomic copies. Here, we implement blue and red light-responsive gene switches to engineer genomically stable two- and three-dimensional mammalian tissue models. Notably, we achieve precise control of cell death and morphogen-directed patterning in 2D and 3D tissues by optogenetically regulating cell necroptosis and synthetic WNT3A signaling at high spatiotemporal resolution. This is accomplished using custom-built patterned LED systems, including digital mirrors and photomasks, as well as laser techniques. These advancements demonstrate the capability of precise spatiotemporal modulation in tissue engineering and open up new avenues for developing programmable 3D tissue and organ models, with significant implications for biomedical research and therapeutic applications.

Beyond Intention: Barriers to Undergoing a Blood Pressure Check in the South-West Shewa Zone, Ethiopia.

Hypertension is often asymptomatic, progresses slowly, and leads to multiple secondary diseases. Thus, a regular blood pressure check is recommended. The objective of this study is to assess the intention to undergo a blood pressure check and its associated factors among adults in Southwest Shewa Zone, Ethiopia. A healthcare-facility-based cross-sectional design was utilized. A standardized questionnaire, adapted from previous research, was administered by trained interviewers. Binary logistic regression analysis was used to determine the factors the intention to undergo blood pressure checks is associated with, utilizing SPSS version 27. Four hundred twenty-one participants provided a complete response, yielding a 99.7% response rate. Of these participants, 153 (36%) had had their blood pressure checked at some point. The vast majority of the study participants (387, 91.9%) did not know the normal blood pressure range. The median score for intention to undergo blood pressure check was 11 (interquartile range 10-13). Female participants were 59% less likely (adjusted odds ratio [AOR] 0.408, 95% confidence interval 0.208-0.801) to intend to undergo a blood pressure check than male participants. Participants in the poorest wealth quintile were 82% less likely (AOR 0.183, 95% CI = 0.063-0.533) to intend to undergo a blood pressure check than those in the richest quintile. Participants who intended to undergo a blood pressure check had a significantly favorable attitude (t = 10.801, p < 0.001) and lower perceived behavioral control (t = -2.865, p < 0.001) compared with those who had no intention of checking. A high intent to undergo a blood pressure check should prompt healthcare facilities to offer regular blood pressure check-up services. Behavioral change communication interventions should address the attitude and perceived behavioral controls of individuals associated with the intention to undergo a blood pressure check. In doing so, special attention should be given to female and economically disadvantaged populations.

Collaborative improvement of mechanical and electrical properties of Cu–Ni–Co–P alloys via regulation of nanophase precipitation behavior

Owing to their excellent strength and electrical conductivity, Cu–Ni–Co–P alloys present strong potential as next-generation materials for integrated circuits in electronic information systems. However, these outstanding properties are closely tied to the precise control of nanophase precipitation behavior within Cu-based alloy systems. Herein, the design of alloy composition was combined with aging treatment to regulate the nanoprecipitation process. Furthermore, the effects of P content and aging treatment conditions, including temperature and duration, on the microstructure and the mechanical, and electrical properties of Cu–Ni–Co–P alloys were systematically investigated. The findings reveal that Cu–0.3Ni–0.3Co–0.16P alloys, when aged at 500 °C for 4 h, primarily consist of a Cu-rich matrix interspersed with numerous nanoprecipitates. These nanoprecipitates were identified as the hexagonal CoNiP phase, precipitating in Guinier–Preston (GP) zones and maintaining a coherent relationship with the Cu matrix. The as-annealed Cu–0.3Ni–0.3Co–0.16P alloys demonstrated a tensile strength of 652.9 MPa, a yield strength of 631.2 MPa, a Vickers hardness of 203.2 HV, and an electrical conductivity of 66.4 %IACS. Aberration-corrected scanning transmission electron microscopy revealed that G.P. zones suppressed the coarsening of the CoNiP phase, thereby enhancing the mechanical strength of the Cu–Ni–Co–P alloys. The strength analysis calculations suggest that fine-grain and precipitation strengthening mechanisms are the predominant factors in improving the mechanical strength of these alloys. This study provides valuable insights into the development and manufacturing of high-performance Cu-based alloys for advanced applications in the electronics industry.

Brain endocannabinoid control of metabolic and non-metabolic feeding behaviors.

The central endocannabinoid (eCB) system in brain shows a crucial role in the regulation of feeding behaviors, influencing both metabolic and non-metabolic mechanisms of appetite control, which has been paid much attention. Although there are already many review articles discussing eCB modulation of feeding behaviors, our paper attempts to summarize the recent advancements through synapses, circuits, and network in brain. Our focus is on the dual role of eCB signalling in regulating metabolic energy balance and hedonic reward-related feeding. In the context of metabolic regulation of feeding behaviors, eCBs affect the hypothalamic circuits that balance hunger and satiety through signal integration related to energy status and nutrient availability. Dysregulation of this system can contribute to metabolic disorders such as obesity and anorexia. In non-metabolic feeding, the eCB system influences the hedonic aspects of eating by modulating reward pathways, including the mesolimbic system and the olfactory bulb, critical for motivating food intake and processing sensory cues. This review also explores therapeutic strategies targeting the eCB system, including cannabinoid receptor antagonists and eCB hydrolase enzyme inhibitors, which hold promise for treating conditions associated with appetite dysregulation and eating disorders. By synthesizing recent findings, we aim to highlight the intricate mechanisms through which the eCB system affects feeding behavior and to propose future directions for research and therapeutic intervention in the realm of appetite control and eating disorders.

Emotion regulation in self-injurious youth: A tale of two circuits.

Two emotion regulation (ER) networks, the amygdala and ventral striatum (VS) circuits underpin defensive and reward processes related to non-suicidal self-injury (NSSI). Youth who engaged in non-suicidal self-injury behavior (NSSIB) and healthy controls either watched images passively (passive condition) or increased their positive affect during positive/neutral images and decreased their negative affect during negative and self-harm images (regulate condition) in the scanner. NSSI youth showed higher amygdala to precuneus and inferior parietal lobe (IPL) connectivity while regulating emotions during self-harm images, a pattern which was associated with higher self-injury frequency. NSSI youth showed higher VS connectivity to the fusiform gyrus and parahippocampus while regulating emotions elicited by self-harm and positive images, which was in turn linked to higher self-harm frequency and relief after NSSI. Higher amygdala-precuneus and IPL connectivity in NSSI youth suggest greater self-identification with, or difficulty regulating negative affect elicited by, self-injury images. High VS-fusiform gyrus and parahippocampus connectivity during positive and self-harm images implies reward anomalies and/or greater effort to regulate positive affect. VS circuit's' links to relief and NSSIB frequency suggest VS reward-based learning as biomarker of NSSIB endurance. We discovered ER mechanisms in adolescents with NSSIB and promising targets for effective NSSIB treatment.

Development of a Multiple Temperature Sensors Device for the Characterization, Control and Monitoring of Microbiological Incubators.

An increasing number of projects require the precise knowledge and control of thermal conditions within the study system and their temporal evolution. This is particularly critical for equipment such as laboratory ovens and microbiological incubators, which are essential in various fields of chemistry and microbiology areas. These devices allow and facilitate the execution of experimental work in controlled environments, leading to reproducible experiments. This work presents a methodology for assembling and calibrating a highly accessible and low-cost data logger equipped with multiple temperature sensors. The final calibrated dispositive is straightforward to construct and allows the simultaneous and independent temperature measurement from multiple positions within the same system, which is then applied to the study, characterization, control, and monitoring of the internal thermal behavior of a laboratory oven dedicated to microbiological agents' cultivation. This approach ensures, through a robust methodology, a precise characterization by quantitative methods that allows objective decision making in the management and control of the temperature inside the system. Additionally, the device is suitable for extension and application in diverse research environments by modifying the sensor calibration to achieve a desired temperature range or number of measurement units, representing a potential work tool for laboratory systems.