Phase Preference Research Articles

Molecular Structural Control of the Amorphous-Crystalline Balance in Solids: Structure-Phase Correlation in DADQs with Enhanced/Switchable Fluorescence.

The amorphous/crystalline (A/C) assembly in molecular solids has a direct bearing on their attributes and applications, including mechanical, pharmaceutical, electronic and photophysical. A systematic analysis of the molecular features and interactions that determine the predilection towards the A, C or bi-stable A-C states is critical. This fundamental problem is addressed through an exhaustive investigation of a large family of alkoxyalkyl diaminodicyanoquinodimethanes (ROR'-DADQs); enhancement of their fluorescence from the solution, to the A, to the C state serves as an excellent signature of the phase preference and temporal stability. Their thermal characteristics and single crystal structure investigations coupled with Hirshfeld surface analysis of the intermolecular interactions, not only confirm the spectroscopic observations, but also reveal the significant impact of the molecular structural features, key interactions like H-bonds, and molecular orientations in the lattice, on the phase stability. These explorations lead to a basic structure-phase correlation; its predictive power is demonstrated by identifying the borderline systems as functional phase change materials, and the subsequent verification through the reversible cycles of fluorescence switching between the A/C states. The factors promoting the A or C forms of molecular solids can guide the design of novel materials exploiting such supramolecular structures and their interconversions.

Cytotoxic Ruthenium(II)-Diphosphine Complexes Affect the Mitochondrial Respiration of Lung Cancer Cells.

In this work, we studied six Ruthenium(II)-diphosphine compounds containing different mercapto ligands (N-S), with general formula [Ru(N-S)(dppm)2]Cl (dppm=1,1-bis(diphenylphosphino)methane). These compounds were characterized by several techniques (NMR [1H, 31P(1H), and 13C], HRMS, IR, UV-Vis and XRD) and their purity confirmed by elemental analysis. DLS experiments revealed low diameters and polydispersity indexes, and positive log P values in n-octanol/PBS indicated their preference for the organic phase. In general, these compounds are stable in different media over 48 h. Cytotoxicity experiments revealed promising IC50 values on A549 breast cancer cells, 0.48 μM and 0.80 μM for [Ru(mtz)(dppm)2]Cl (1) and [Ru(mmi)(dppm)2]Cl (2), respectively (mtz and mmi are 2-mercapto-2-thiazoline and mercapto-1-methylimidazole in their deprotonated form, respectively). Clonogenic and migration experiments indicated their antiproliferative and anti-migratory capacity. ICP-MS results indicated their cellular accumulation in the nucleus, with little amounts in mitochondria. No covalent DNA binding was observed by ICP-MS. JC-1 and cell Mito Stress test confirmed mitochondrial dysfunction, which was verified by mitochondrial membrane potential uncoupling and drastic alterations in the oxygen consumption rate. Taken together, our results provide crucial insights regarding the anticancer potential of ruthenium(II)-phosphine compounds.

Improving quantum synchronization by manipulating auxiliary qubits in a dissipative model

Abstract Quantum phase synchronization is studied in a dissipative model via an analytic approach. It is found that a robust phase preference using the Husimi Q-function against decoherence for both the Markovian and non-Markovian regimes can be obtained by manipulating auxiliary qubits in a reservoir. Specifically, we show that quantum phase synchronization can be significantly improved by adding a number of auxiliary qubits for both the Markovian and non-Markovian regimes. We also find that a steady quantum phase synchronization can be obtained in the long-time limit, which is only dependent on the number of auxiliary qubits regardless of the Markovian or non-Markovian regimes. We give some intuitive interpretations of the obtained results. Overall, our results are of theoretical interest in the enhancement of quantum phase synchronization in noisy environments, and may have potential applications in quantum information science.

Frequency-dependent phase entrainment of cortical cell types during tACS: computational modeling evidence.

Transcranial alternating current stimulation (tACS) enables non-invasive modulation of brain activity, holding promise for clinical and research applications. Yet, it remains unclear how the stimulation frequency differentially impacts various neuron types.
Here, we aimed to quantify the frequency-dependent behavior of key neocortical cell types. We used both detailed (anatomical multicompartments) and simplified (three compartments) single-cell modeling approaches based on the Hodgkin--Huxley formalism to study neocortical excitatory and inhibitory cells under various-amplitude tACS frequencies within the 5-50 Hz range at rest and during basal 10 Hz activity. L5 pyramidal cells exhibited the highest polarizability at DC, ranging from 0.21 to 0.25 mm and decaying exponentially with frequency. Inhibitory neurons displayed membrane resonance in the 5-15 Hz range with lower polarizability, although bipolar cells had higher polarizability. Layer 5 PC demonstrated the highest entrainment close to 10 Hz, which decayed with frequency. In contrast, inhibitory neurons entrainment increased with frequency, reaching levels akin to PC. Results from simplified models could replicate phase preferences, while amplitudes tended to follow opposite trends in PC. tACS-induced membrane polarization is frequency-dependent, revealing observable resonance behavior. Whilst optimal phase entrainment of sustained activity is achieved in PC when tACS frequency matches endogenous activity, inhibitory neurons tend to be entrained at higher frequencies. Consequently, our results highlight the potential for precise, cell-specific targeting for tACS.

Hydrogen‐Driven Phase Differentiation in BN Nucleation on Diamond

AbstractBoron nitride has attracted scientific interest in recent years due to its potential use in electronics, both as hexagonal (hBN) and cubic (cBN) phases. While both are successfully realized through chemical vapor deposition, the heteroepitaxial growth of cBN on another iconic semiconductor, diamond is plagued with mixed‐phase formation. Employing first‐principles computations and a nanoreactor approach, the BN phase preferences are explored on diamond (001) controlled—as it is discovered—by the hydrogen gas concentration. In a limited‐hydrogen environment, the initial BN‐island expands along the diamond surface, forming a 3D metastable cubic phase that grows in the direction normal to the basal plane through kinetically‐limited nucleation, thus overcoming the thermodynamic preference toward the hBN phase. Comparatively, the amorphous phase is favored in the absence of hydrogen, while the hexagonal phase dominates at its high levels, elucidating numerous experimental observations. A obtained kinetic phase diagram connects the phase with hydrogen chemical potential to facilitate targeted phase selection. The results suggest that gas‐mediated nucleation kinetics provide feasible control for the precise synthesis. It also offers valuable guidance for the controllable synthesis of desired BN phases and advances research toward potential BN electronics.

Characterization (XRD/TGA-DSC) and assessment of calf thymus DNA interaction with single-crystalline novel complexes from Schiff base ligands

The Schiff base complexes [Zn(H2L)2Cl2] 2/3(CH3OH) 2/3(H2O) (1) and [Cd(H2L)2(NO3)2(CH3OH)2] (2), where H2L is an N-Acylhydrazone ligand, have been investigated mainly using a combinatory approach of single-crystal X-ray diffractometry (XRD), thermogravimetric and differential thermal analysis (TGA-DSC). XRD analysis revealed that both complexes coordinate through the nitrogen atom of the ligand’s pyridine ring. In complex (1), the zinc(II) ion coordinates with two ligands and two chloride ions, forming a distorted tetrahedral geometry. In complex (2), the cadmium(II) ion coordinates with two ligands, two nitrate ions, and two methanol molecules, resulting in an octahedral geometry. The crystalline material’s high purity and precise stoichiometry were crucial for accurate thermoanalytical analysis. Additionally, characterizations were performed using infrared (IR), ultraviolet–visible (UV–vis), molar conductivity, elemental analysis (EA) and nuclear magnetic resonance (NMR) spectroscopy. Biological studies with calf thymus DNA (CT-DNA), using UV–vis spectroscopy, viscosity measurements and ethidium bromide displacement assays indicated intercalative binding of the complexes with DNA. The binding (Kb) and quenching (Ksv) constants (104 L/mol) suggest moderate interaction with CT-DNA. The positive partition coefficients (log P) values in water and 1-octanol suggest a significant preference for the lipid-like organic phase, implying that these complexes can efficiently penetrate biological membranes.

Advances in Machine Learning Applications in Material Science: From Non-2D to 2D Materials

This mini-review presents recent advancements in the application of machine learning to both non-2D and 2D materials. For non-2D materials, the main focus is on construction materials, energy and environmental materials, and advanced functional materials. In the case of 2D materials, the mini-review emphasizes the role of machine learning in predicting electronic and structural properties, as well as in identifying defects and phase preferences. The mini-review underscores the crucial role that machine learning plays in advancing materials science by enabling rapid screening of materials, predicting their properties, and significantly reducing the time required for such processes.

Water-in-water emulsions stabilized by konjac glucomannan/tragacanth gum hydrogels for riboflavin delivery

Water-in-water (W/W) emulsions as innovative transport for hydrophilic functional ingredients inherently lack stability due to the ultralow interfacial tension and thick interfacial layer. In this work, we first proposed a simple strategy to construct stable dextran (DEX)-in-poly (ethylene glycol) (PEG) W/W emulsions by utilizing the unique phase preference of konjac glucomannan/tragacanth gum (KT) hydrogels formed based on the cooling-induced intermolecular hydrogen bonds. KT hydrogels were demonstrated to present selective partition to PEG phase and could form physically crosslinking network, thus significantly improving the rheological behavior and stability of DEX-in-PEG (D/P) emulsions with no flocculation after 31 d of storage at 25 °C. Meanwhile, the average droplet size of emulsions decreased from 15.37 to 8.48 μm with TG concentration tuning from 0.2 % to 0.8 %. When encapsulating riboflavin (RIB) in D/P emulsions stabilized by KT-4 hydrogel, the storage and lighting stability of RIB were enhanced with retention rate of 60.94 % and 21.89 %, respectively. In addition, the release of RIB in the simulate gastrointestinal environment substantially reduced and the antioxidant activity of RIB was maximumly protected due to the unique pH-responsiveness of KT hydrogel network. This work provides a feasible strategy for designing stable W/W emulsions stabilized by natural polysaccharide hydrogels, and biocompatible carriers for hydrophilic functional ingredients.

Perception of treatments with self-ligating and conventional brackets in peruvian orthodontists.

Orthodontists' perception of bracket techniques plays a significant role in planning, allowing critical evaluation of the patient's facial aesthetics. To compare the perception of Peruvian orthodontists regarding treatments with self-ligating and conventional brackets. A questionnaire was applied to 168 orthodontic specialists (53% men, average professional experience 9 years) to evaluate preferences for treatment phases, benefits of patient consultation according to the type of bracket, experience with self-ligating brackets, and demographic and clinical characteristics (sex, years of experience, volume of care and length of experience). The Kruskal-Wallis Test and Chi-square test were used with P < 0.05. The total preference for self-ligating brackets (48.9%) was higher than conventional brackets (18.8%). Self-ligating brackets were preferred in most treatment phases (46.4%-63.7%) but not in completion and finishing, in which conventional brackets were preferred. Most orthodontists preferred self-ligating brackets (40.5%-60.7%) over conventional brackets (4.2%-14.3%) due to patient comfort, oral hygiene, and total treatment and appointment time control, but not the cost. The orthodontists reported SLB having mastered their technique in <10 cases (59.5%), the experience of <2 years (45.2%), applying control times of 4-9 weeks (78.6%), and feeling comfortable with their use (89.3%). Preferences were not associated with sex (P > 0.05) but rather with years of professional experience (P < 0.05). Peruvian orthodontists preferred self-ligating brackets over conventional brackets in most treatment phases associated with user comfort and oral hygiene management and treatment/control time, and professional experience. However, some factors, such as cost-effectiveness, counteracted this preference.

Thermal effects and ephaptic entrainment in Hodgkin–Huxley model

The brain is understood as an intricate biological system composed of numerous elements. It is susceptible to various physical and chemical influences, including temperature. The literature extensively explores the conditions that influence synapses in the context of cellular communication. However, the understanding of how the brain’s global physical conditions can modulate ephaptic communication remains limited due to the poorly understood nature of ephapticity. This study proposes an adaptation of the Hodgkin and Huxley (HH) model to investigate the effects of ephaptic entrainment in response to thermal changes (HH-E). The analysis focuses on two distinct neuronal regimes: subthreshold and suprathreshold. In the subthreshold regime, circular statistics are used to demonstrate the dependence of phase differences with temperature. In the suprathreshold regime, the Inter-Spike Interval are employed to estimate phase preferences and changes in the spiking pattern. Temperature influences the model’s ephaptic interactions and can modify its preferences for spiking frequency, with the direction of this change depending on specific model conditions and the temperature range under consideration. Furthermore, temperature enhance the anti-phase differences relationship between spikes and the external ephaptic signal. In the suprathreshold regime, ephaptic entrainment is also influenced by temperature, especially at low frequencies. This study reveals the susceptibility of ephaptic entrainment to temperature variations in both subthreshold and suprathreshold regimes and discusses the importance of ephaptic communication in the contexts where temperature may plays a significant role in neural physiology, such as inflammatory processes, fever, and epileptic seizures.

Heatwave Location Changes in Relation to Rossby Wave Phase Speed

AbstractSurface anticyclones connected to the ridge of an upper‐tropospheric Rossby wave are the main dynamical drivers of mid‐latitude summer heatwaves. It is, however, unclear to what extent an anomalously low zonal phase speed of the wave in the upper troposphere is necessary for persistent temperature extremes at the surface. Here, we use spectral decomposition to separate fast and slow synoptic‐scale waves. A composite analysis of ERA5 reanalysis data reveals that, while in some regions heatwaves become more frequent during episodes of weak or no phase propagation, temperature extremes in other regions are commonly associated with more rapidly eastward propagating Rossby waves. Reflected in the mean heatwave duration as well, this relationship is possibly linked to a longitudinal phase preference of slow and fast waves or a meridional storm track shift. These findings open up new questions about the influence of mid‐latitude dynamics on temperature extremes.

Behavioral Intervention that Extends Sleep Duration Leads to Greater Self-Control in School-Aged Children.

Short sleep and evening phase preference associate with impaired self-control, yet few studies have assessed the efficacy of sleep extension for improving this behavioral domain. Thus, this secondary analysis of a behavioral sleep intervention measured whether an intervention that enhanced children's sleep also affected self-control. Differences by chronotype were also explored. Sixty-seven children (8-11 yr), who reportedly slept <9.5 hr/d, were randomized to either a control or sleep intervention condition (i.e., 4-session behavioral intervention to enhance sleep by 1-1.5 hr/night). Chronotype was assessed using the Child Chronotype Questionnaire at baseline, and self-control was assessed using the Self-Control Rating Scale (SCRS, a caregiver report) at baseline and 8 weeks postrandomization. Total sleep time (TST) was measured using wrist actigraphy for 1 week at both baseline and 8 weeks postrandomization. Partial correlations and mixed-model ANOVAs were used for statistical analyses, with age as a covariate. At baseline, children with shorter TST (r = -0.29, p = 0.02) and an evening preference (r = 0.26, p = 0.049) were perceived as having lower self-control by their caregivers. Significant condition*time interaction effects were found for TST ( p < 0.001) and SCRS score ( p = 0.046): From baseline to follow-up, children randomized to the sleep intervention exhibited a significant increase in TST and were perceived as having greater self-control by their caregiver; children randomized to the control condition exhibited no change in TST or in SCRS score. The condition*chronotype*time interaction effect was not significant. A brief sleep intervention that enhanced TST also resulted in enhanced caregiver reported self-control in school-age children. Results add to the growing evidence for the importance of sleep health in children.

Later ("evening") circadian preference is associated with poorer executive, academic, and attentional functioning in adolescents with and without ADHD.

Adolescents vary considerably in their circadian phase preference; those with greater "eveningness" (also known as "night owls") have later bedtimes, wake times, and peak arousal compared to those with greater "morningness." Prior research suggests that (a) greater eveningness is associated with worse academic, executive, and attentional functioning; and (b) adolescents with attention-deficit/hyperactivity disorder (ADHD) tend to be high in eveningness and to have deficits in these school-related constructs. However, few studies have examined circadian preference alongside two potential confounds-sleep duration and sleep quality-as predictors of daytime functioning, or whether the strength of associations differs across adolescents with and without ADHD. Participants were 302 adolescents (Mage = 13.17 years; 44.7% female; 81.8% White); approximately half (52%) had ADHD. A multi-method, multi-informant design was used. Specifically, adolescents reported on their circadian preference, school night sleep duration, and sleep quality. Adolescents provided ratings of their academic motivation (intrinsic, extrinsic, and amotivation) and were administered standardized achievement tests in reading and math. Adolescents and parents completed ratings of daily life executive functioning (behavioral, emotion, and cognitive regulation), and they and teachers also provided ratings of ADHD inattentive symptoms. Above and beyond sleep duration, sleep quality, and covariates (sex, family income, pubertal development, medication use), greater eveningness was uniquely associated with poorer academic, executive, and attentional functioning across most measures. Sleep quality was uniquely associated with a handful of outcomes, and sleep duration was not significantly uniquely associated with any outcome in the regression analyses. ADHD status did not moderate effects. This study provides compelling evidence that poorer academic, executive, and attentional functioning are more closely associated with greater eveningness than with sleep duration or quality in adolescents. Findings suggest that targeting circadian preference may be important to reduce these problems in adolescents, especially in clinical samples such as ADHD for whom academic, executive, and attentional difficulties are exceptionally common.

Thermodynamic and structural characterization of high-entropy garnet electrolytes for all-solid-state battery

This study explores multi-component garnet-based materials as solid electrolytes for all-solid-state lithium batteries. Through a combination of computational and experimental approaches, we investigate the thermodynamic and structural properties of lithium lanthanum zirconium oxide garnets doped with various elements. Applying density functional theory, the influence of dopants on the thermodynamic stability of these garnets was studied. Probable atomic configurations and their impact on materials’ properties were investigated with the focus on understanding the influence of these configurations on structural stability, phase preference, and ionic conductivity. In addition to the computational study, series of cubic-phase garnet compounds were synthesized and their electrochemical performance was evaluated experimentally. Our findings reveal that the stability of cubic phase in doped Li-garnets is primarily governed by enthalpy, with configurational entropy playing a secondary role. Moreover, we establish that the increased number of doping elements significantly enhances the cubic phase’s stability. This in-depth understanding of materials’ properties at atomic level establishes the basis for optimizing high-entropy ceramics, contributing significantly to the advancement of solid-state lithium batteries and other applications requiring innovative material solutions.

Ferroelectric polycrystalline Bi2SiO5 thin films on Pt-covered Si substrates prepared by pulsed laser deposition combined with post-annealing

In this study, we report on the fabrication of polycrystalline thin film Bi2SiO5, a notable non-perovskite ferroelectric material. The thin films were deposited on Pt-covered Si substrates by pulsed laser deposition (PLD) at room temperature, followed by a post-annealing process in air. The as-deposited thin film was of an amorphous phase of Bi-Si-O, and turned to a polycrystalline phase of Bi2SiO5 by the post-annealing above 550°C. The influences of the post-annealing temperature on the phase preference, surface morphology, and dielectric properties of the thin films were investigated by Raman spectroscopy, X-ray diffraction (XRD), atomic force microscopy (AFM), and dielectric measurements. As a result, the optimal post-annealing temperature was determined to be 600°C, yielding a good ferroelectric polycrystalline Bi2SiO5 thin film with a relative dielectric constant of 143 and a remanent polarization (2Pr) of 7.2 μC cm−2.

Artificial neural network for deciphering the structural transformation of condensed ZnO by extended x-ray absorption fine structure spectroscopy

Pressure-induced structural phase transitions play a pivotal role in unlocking novel material functionalities and facilitating innovations in materials science. Nonetheless, unveiling the mechanisms of densification, which relies heavily on precise and comprehensive structural analysis, remains a challenge. Herein, we investigated the archetypal B4 → B1 phase transition pathway in ZnO by combining x-ray absorption fine structure (XAFS) spectroscopy with machine learning. Specifically, we developed an artificial neural network (NN) to decipher the extended-XAFS spectra by reconstructing the partial radial distribution functions of Zn–O/Zn pairs. This provided us with access to the evolution of the structural statistics for all the coordination shells in condensed ZnO, enabling us to accurately track the changes in the internal structural parameter u and the anharmonic effect. We observed a clear decrease in u and an increased anharmonicity near the onset of the B4 → B1 phase transition, indicating a preference for the iT phase as the intermediate state to initiate the phase transition that can arise from the softening of shear phonon modes. This study suggests that NN-based approach can facilitate a more comprehensive and efficient interpretation of XAFS under complex in-situ conditions, which paves the way for highly automated data processing pipelines for high-throughput and real-time characterizations in next-generation synchrotron photon sources.

Evaluation of the objective structured clinical examination by the nursing students

The objective structured clinical examination (OSCE) represents a pivotal innovation in the assessment of clinical proficiency within nursing education. This method is crucial as nurses are anticipated to exhibit competence across diverse healthcare settings, ensuring comprehensive, safe, and high-quality care throughout the patient's lifespan. A key challenge in evaluating clinical competence lies in the inherent subjectivity and complexity of the task. This demands educators to perpetually seek and refine tools apt for gauging nursing competence. Our study, a descriptive cross-sectional analysis encompassing 150 undergraduate nursing students, utilized a modified standardized survey questionnaire to appraise student perceptions of their OSCE experiences. Findings indicate a predominant classification of the OSCE as "good," with a notable preference for the planning phase over the implementation phase. Pre-test orientation was highly valued, whereas the provision of materials was critiqued. Gender and academic year were identified as significant variables influencing OSCE evaluations, particularly in the implementation phase and regarding examiner roles. This research offers foundational insights for future studies aiming to enhance OSCE methodology and substantiates the necessity of integrating OSCE into nursing curricula for robust clinical competence assessment.

Cardiorespiratory fitness and circadian rhythms in adolescents: a pilot study.

Although cardiorespiratory fitness (CRF), an important marker of youth health, is associated with earlier sleep/wake schedule, its relationship with circadian rhythms is unclear. This study examined the associations between CRF and rhythm variables in adolescents. Eighteen healthy adolescents (10 females and 8 males; Mage = 14.6 ± 2.3 yr) completed two study visits on weekdays bracketing an ambulatory assessment during summer vacation. Visit 1 included in-laboratory CRF assessment (peak V̇o2) using a ramp-type progressive cycle ergometry protocol and gas exchange measurement, which was followed by 7-14 days of actigraphy to assess sleep/wake patterns and 24-h activity rhythms. During Visit 2, chronotype, social jetlag (i.e., the difference in midsleep time between weekdays and weekends), and phase preference were assessed using a questionnaire, and hourly saliva samples were collected to determine the dim light melatonin onset (DLMO) phase. All analyses were adjusted for sex, pubertal status, and physical activity. Greater peak V̇o2 was associated with earlier sleep/wake times and circadian phase measures, including acrophase, UP time, DOWN time, last activity peak (LAP) time, and chronotype (all P < 0.05). Peak V̇o2 was negatively associated with social jetlag (P = 0.02). In addition, the mixed-model analysis revealed a significant interaction effect between peak V̇o2 and actigraphy-estimated hour-by-hour activity patterns (P < 0.001), with the strongest effects observed at around the time of waking (0600-1000). In healthy adolescents, better CRF was associated with an earlier circadian phase and increased activity levels notably during the morning. Future studies are needed to investigate the longitudinal effects of the interactions between CRF and advanced rhythms on health outcomes.NEW & NOTEWORTHY In healthy adolescents, better cardiorespiratory fitness, as assessed by the gold standard measure [laboratory-based assessment of peak oxygen consumption (V̇o2)], was associated with earlier circadian timing of sleep/wake patterns, rest-activity rhythms and chronotype, and less social jetlag. These findings highlight the close interrelationships between fitness and rhythms and raise the possibility that maintaining higher cardiorespiratory fitness levels alongside earlier sleep/wake schedule and activity rhythms may be important behavioral intervention targets to promote health in adolescents.

Detecting quantum phase localization using Arnold tongue

The dynamical phase localization of a single qubit in a dissipative bath is investigated. We show that phase preference persists in the long time limit only for a non-Markovian evolution with a finite detuning implying that non-Markovianity is required for phase localization. The maximum of the shifted phase distribution exhibits an Arnold tongue like feature where the phase localized and phase delocalized regions are distinctly separated. We show the formation of Arnold tongue using the relative entropy of coherence as well. From our work we propose that Arnold tongue can be used to detect dynamical phase localization even when there is no synchronization present in the system.

The Role of Wearable Sensors in the Future Primary Healthcare – Preferences of the Adult Swiss Population: A Mixed Methods Approach

Wearable sensors have the potential to increase continuity of care and reduce healthcare expenditure. The user concerns and preferences regarding wearable sensors are the least addressed topic in related literature. Therefore, this study aimed first, to examine the preferences of the adult Swiss population regarding the use of wearable sensors in primary healthcare. Second, the study aimed to explain and learn more about these preferences and why such wearable sensors would or would not be used. An explanatory sequential design was used to reach the two aims. In the initial quantitative phase preferences of a nationwide survey were analyzed descriptively and a multivariable ordered logistic regression was used to identify key characteristics, that influence the preferences. In the second phase, eight semi-structured interviews were conducted. The cleaned study sample of the survey included 687 participants, 46% of whom gave a positive rating regarding the use of wearable sensors. In contrast, 44% gave a negative rating and 10% were neutral. The interviews showed that sensors should be small, not flashy and be compatible with everyday activities. Individuals without a current health risk or existing chronic disease showed lower preferences for using wearable sensors, particularly because they fear losing control over their own body. In contrast, individuals with increased risk or with an existing chronic disease were more likely to use wearable sensors as they can increase the personal safety and provide real-time health information to physicians. Therefore, an important deciding factor for and against the use of wearable sensors seems to be the perceived personal susceptibility for potential health problems.