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1. Analytical Model for Thermoregulation of the Human Body in Contact with a Phase Change Material (PCM) Cooling Vest

Author

Kaspar M. B. Jansen and Lennart Teunissen

Subjects
radiation, heat source, melting, cooling power, analytical equations, Thermodynamics, QC310.15-319
Abstract

Cooling vests containing phase change materials (PCMs) are used to reduce heat stress in hot environments and maintain the body core temperature within a safe range. The performance of such cooling vests depends in a complicated way on the PCM material and mass, the insulation value of the clothing layers and heat loss to the environment. Conventionally, these performance parameters are evaluated experimentally or using a numerical model, both of which do need a certain amount of evaluation time. The objective of this paper is to develop a transient heat transfer model which includes metabolic heat production in the human body, as well as clothing and PCM layers and radiation to the environment but which is presented as a series of closed-form equations that can be evaluated without the need of a numerical solver. We present solutions for the body and PCM temperature as well as for the heat flux, cooling power and cooling duration. The model equations are validated by comparing them with experiments of ice PCM packs on a hotplate, as well as with published experimental and numerical data for the core temperature, heat flux and percentage of environmental heat loss using a Glauber salt type of PCM. Both the hotplate experiments and the model predictions show that the cooling power during PCM melting drops from about 70 to 32 W for increasing insulation layer thicknesses. In addition, the model is seen to compare well with experimental and simulation data in the literature. In a parametric study, we show how the equations can be used to evaluate the effects of PCM melting temperature and PCM thickness on cooling performance. The paper, therefore, can be considered as a practical means to help select the best cooling vest configuration for workers in a hot and humid environment.

Published
2022
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3. 4D printing of reconfigurable metamaterials and devices

Author

Teunis van Manen, Shahram Janbaz, Kaspar M. B. Jansen, and Amir A. Zadpoor

Subjects
Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Shape-shifting structures are important building blocks in the design of reconfigurable materials and devices with advanced functionalities. Here, versatile metamaterials with 3D-to-3D shape-shifting behavior upon thermal activation are fabricated by adapting a 3D printer to print on curved surfaces.

Published
2021
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6. Design of Wearable Finger Sensors for Rehabilitation Applications

Author

Beyza Bozali, Sepideh Ghodrat, and Kaspar M. B. Jansen

Subjects
knitted strain sensor, rehabilitation applications, smart textiles, wearable textiles, Mechanical engineering and machinery, TJ1-1570
Abstract

As an emerging technology, smart textiles have attracted attention for rehabilitation purposes or to monitor heart rate, blood pressure, breathing rate, body posture, as well as limb movements. Traditional rigid sensors do not always provide the desired level of comfort, flexibility, and adaptability. To improve this, recent research focuses on the development of textile-based sensors. In this study, knitted strain sensors that are linear up to 40% strain with a sensitivity of 1.19 and a low hysteresis characteristic were integrated into different versions of wearable finger sensors for rehabilitation purposes. The results showed that the different finger sensor versions have accurate responses to different angles of the index finger at relaxation, 45° and 90°. Additionally, the effect of spacer layer thickness between the finger and sensor was investigated.

Published
2023
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7. Development of a Knitted Strain Sensor for Health Monitoring Applications

Author

Beyza Bozali, Sepideh Ghodrat, and Kaspar M. B. Jansen

Subjects
knitted strain sensor, health monitoring applications, smart textiles, wearable textiles, Engineering machinery, tools, and implements, TA213-215
Abstract

As an emerging technology, smart textiles have attracted attention for rehabilitation purposes to monitor heart rate, blood pressure, breathing rate, body posture and limb movements. Compared with traditional sensors, knitted sensors constructed from conductive yarns are breathable, stretchable and washable, and therefore, provide more comfort to the body and can be used in everyday life. In this study, knitted strain sensors were produced that are linear with up to 40% strain, sensitivity of 1.19 and hysteresis of 1.2% in absolute values, and hysteresis of 0.03 when scaled to the working range of 40%. The developed sensor was integrated into a wearable wrist-glove system for finger and wrist monitoring. The results show that the wearable was able to detect different finger angles and positions of the wrist.

Published
2023
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9. Development of Low Hysteresis, Linear Weft-Knitted Strain Sensors for Smart Textile Applications

Author

Beyza Bozali, Sepideh Ghodrat, Linda Plaude, Joris J. F. van Dam, and Kaspar M. B. Jansen

Subjects
smart textiles, knitted strain sensors, hysteresis-free sensors, conductive yarns, Chemical technology, TP1-1185
Abstract

In recent years, knitted strain sensors have been developed that aim to achieve reliable sensing and high wearability, but they are associated with difficulties due to high hysteresis and low gauge factor (GF) values. This study investigated the electromechanical performance of the weft-knitted strain sensors with a systematic approach to achieve reliable knitted sensors. For two elastic yarn types, six conductive yarns with different resistivities, the knitting density as well as the number of conductive courses were considered as variables in the study. We focused on the 1 × 1 rib structure and in the sensing areas co-knit the conductive and elastic yarns and observed that positioning the conductive yarns at the inside was crucial for obtaining sensors with low hysteresis values. We show that using this technique and varying the knitting density, linear sensors with a working range up to 40% with low hysteresis can be obtained. In addition, using this technique and varying the knitting density, linear sensors with a working range up to 40% strain, hysteresis values as low as 0.03, and GFs varying between 0 and 1.19 can be achieved.

Published
2022
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10. Periprocedural Hydrogen Sulfide Therapy Improves Vascular Remodeling and Attenuates Vein Graft Disease

Author

Peter Kip, Ming Tao, Kaspar M. Trocha, Michael R. MacArthur, Hendrika A. B. Peters, Sarah J. Mitchell, Charlotte G. Mann, Thijs J. Sluiter, Jonathan Jung, Suzannah Patterson, Paul H. A. Quax, Margreet R. de Vries, James R. Mitchell, and C. Keith Ozaki

Subjects
hydrogen sulfide, vascular remodeling, vein graft disease, Diseases of the circulatory (Cardiovascular) system, RC666-701
Abstract

Background Failure rates after revascularization surgery remain high, both in vein grafts (VG) and arterial interventions. One promising approach to improve outcomes is endogenous upregulation of the gaseous transmitter‐molecule hydrogen sulfide, via short‐term dietary restriction. However, strict patient compliance stands as a potential translational barrier in the vascular surgery patient population. Here we present a new therapeutic approach, via a locally applicable gel containing the hydrogen sulfide releasing prodrug (GYY), to both mitigate graft failure and improve arterial remodeling. Methods and Results All experiments were performed on C57BL/6 (male, 12 weeks old) mice. VG surgery was performed by grafting a donor‐mouse cava vein into the right common carotid artery of a recipient via an end‐to‐end anastomosis. In separate experiments arterial intimal hyperplasia was assayed via a right common carotid artery focal stenosis model. All mice were harvested at postoperative day 28 and artery/graft was processed for histology. Efficacy of hydrogen sulfide was first tested via GYY supplementation of drinking water either 1 week before VG surgery (pre‐GYY) or starting immediately postoperatively (post‐GYY). Pre‐GYY mice had a 36.5% decrease in intimal/media+adventitia area ratio compared with controls. GYY in a 40% Pluronic gel (or vehicle) locally applied to the graft/artery had decreased intimal/media area ratios (right common carotid artery) and improved vessel diameters. GYY‐geltreated VG had larger diameters at both postoperative days 14 and 28, and a 56.7% reduction in intimal/media+adventitia area ratios. Intimal vascular smooth muscle cell migration was decreased 30.6% after GYY gel treatment, which was reproduced in vitro. Conclusions Local gel‐based treatment with the hydrogen sulfide‐donor GYY stands as a translatable therapy to improve VG durability and arterial remodeling after injury.

Published
2020
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11. An End-to-End Deep Learning Pipeline for Football Activity Recognition Based on Wearable Acceleration Sensors

Author

Rafael Cuperman, Kaspar M. B. Jansen, and Michał G. Ciszewski

Subjects
artificial neural networks, convolutional neural networks, deep learning, football, HAR, human activity recognition, Chemical technology, TP1-1185
Abstract

Action statistics in sports, such as the number of sprints and jumps, along with the details of the corresponding locomotor actions, are of high interest to coaches and players, as well as medical staff. Current video-based systems have the disadvantage that they are costly and not easily transportable to new locations. In this study, we investigated the possibility to extract these statistics from acceleration sensor data generated by a previously developed sensor garment. We used deep learning-based models to recognize five football-related activities (jogging, sprinting, passing, shooting and jumping) in an accurate, robust, and fast manner. A combination of convolutional (CNN) layers followed by recurrent (bidirectional) LSTM layers achieved up to 98.3% of accuracy. Our results showed that deep learning models performed better in evaluation time and prediction accuracy than traditional machine learning algorithms. In addition to an increase in accuracy, the proposed deep learning architecture showed to be 2.7 to 3.4 times faster in evaluation time than traditional machine learning methods. This demonstrated that deep learning models are accurate as well as time-efficient and are thus highly suitable for cost-effective, fast, and accurate human activity recognition tasks.

Published
2022
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13. First Observational Results from ALFA with Natural and Laser Guide Stars

Author

Davies, R. I., Hackenberg, W., Ott, T., Eckart, A., Rabien, S., Anders, S., Hippler, S., and Kaspar, M.

Subjects
Astrophysics
Abstract

The sodium laser guide star adaptive optics system ALFA, which is installed at the Calar Alto 3.5-m telescope, has been undergoing an intensive optimisation phase. Observations using natural guide stars that are presented in this paper, show that for bright stars (V~<8) it is now possible to reach K-band Strehl ratios in excess of 60% and to easily resolve binaries at the diffraction limit of the telescope. In more typical usage Strehl ratios in the range 10-15% can be achieved over a wide field (~2'); and the limiting magnitude is currently V~<12.5. We also present some of the first spectroscopy at diffraction limited scales, showing we are able to distinguish spectra of binary stars with a separation of only 0.26''. Our last set of results are on Abell galaxy clusters, including a correction on a galaxy using the laser guide star as the reference. There are still a number of difficulties associated with the laser, but our best result to date is of the galaxy UGC 1347 in Abell 262. Correcting tip-tilt on a star 41'' away and higher orders on the laser, we achieved in increase in peak intensity of 2.5, and a reduction in FWHM from 1.07'' to 0.40''. It is expected that further significant advances will be made in the next 6 months and beyond., Comment: 11 pages; contribution to the ESO topical meeting on Astronomy with Adaptive Optics (Sept 1998)

Published
1998

18. Evaluation of Phase Change Materials for Personal Cooling Applications

Author

L.P.J. Teunissen, Kaspar M. B. Jansen, Joost Schootstra, Linda Plaude, and Emiel Janssen

Subjects
Materials science, Polymers and Plastics, Materials Science (miscellaneous), cooling garment, Mechanical engineering, General Business, Management and Accounting, Phase-change material, cooling power, Phase change, PCM, Cooling power, Business, Management and Accounting (miscellaneous), hotplate, phase change material
Abstract

Eleven phase change materials (PCMs) for cooling humans in heat-stressed conditions were evaluated for their cooling characteristics. Effects of packaging material and segmentation were also investigated. Sample packs with a different type PCM (water- and oil-based PCMs, cooling gels, inorganic salts) or different packaging (aluminum, TPU, TPU + neoprene) were investigated on a hotplate. Cooling capacity, duration, and power were determined. Secondly, a PCM pack with hexagon compartments was compared to an unsegmented version with similar content. Cooling power decreased whereas cooling duration increased with increasing melting temperature. The water-based PCMs showed a >2x higher cooling power than other PCMs, but were relatively short-lived. The flexible gels and salts did not demonstrate a phase change plateau in cooling power, compromising their cooling potential. Using a TPU or aluminum packaging was indifferent. Adding neoprene considerably extended cooling duration, while decreasing power. Segmentation has practical benefits, but substantially lowered contact area and therefore cooling power.

Published
2021

20. A transient thermal sensation equation fit for the modified Stolwijk model

Author

C.P.G. Roelofsen, Kaspar M. B. Jansen, and Peter Vink

Subjects
Thermal perception, Source code, indoor environmental quality, thermal comfort, Computer science, media_common.quotation_subject, Thermal comfort, Building and Construction, Thermal sensation, Computer Science Applications, workplace, computer simulation, Mathematical modeling, Transient (computer programming), Simulation, media_common
Abstract

There are different thermal perception models linked to a mathematical thermophysiological human model, with which the thermal sensation under stationary and/or dynamic conditions can be evaluated. Each of these perception and thermophysiological models have their own field of application. Stolwijk developed a thermophysiological human model without an associated thermal perception model, which today is still the basis for other mathematical thermophysiological models. Fiala developed the FPC model, also based on the Stolwijk model, and is one of the latest developments in the field of thermophysiological human models. In the FPC model, an equation is included with which the thermal sensation under stationary and dynamic conditions can be assessed; the so-called Dynamic Thermal Sensation (DTS). The DTS equation is, however, specifically developed for use in combination with the FPC model. In contrast to the Stolwijk model, the source code of the computer programs of the later developed thermophysiological human models is not freely available, which limits the use and applicability of the models in practice. It is precise because of the availability of the source code that the Stolwijk model is still used in industry and the research world. The question, therefore, arises: ‘To what extent can a human transient thermal sensation equation be derived, combined with the Stolwijk model, in a similar way to that used for the DTS equation in the FPC model?’.

Published
2021

22. Multiomics assessment of dietary protein titration reveals altered hepatic glucose utilization

Author

MacArthur, Michael R., primary, Mitchell, Sarah J., additional, Chadaideh, Katia S., additional, Treviño-Villarreal, J. Humberto, additional, Jung, Jonathan, additional, Kalafut, Krystle C., additional, Reynolds, Justin S., additional, Mann, Charlotte G., additional, Trocha, Kaspar M., additional, Tao, Ming, additional, Aye Cho, Tay-Zar, additional, Koontanatechanon, Anantawat, additional, Yeliseyev, Vladimir, additional, Bry, Lynn, additional, Longchamp, Alban, additional, Ozaki, C. Keith, additional, Lewis, Caroline A., additional, Carmody, Rachel N., additional, and Mitchell, James R., additional

Published
2022
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24. Performance and thermoregulation of Dutch Olympic and Paralympic athletes exercising in the heat: Rationale and design of the Thermo Tokyo study: The journal Temperature toolbox

Author

L.P.J. Teunissen, Johannus Q. de Korte, Hein A.M. Daanen, Jan-Willem van Dijk, Kaspar M. B. Jansen, Thijs M. H. Eijsvogels, Coen C. W. G. Bongers, Boris Kingma, Maarten H. Moen, Kamiel Maase, Maria T. E. Hopman, Sam B. Ballak, Physiology, and AMS - Sports

Subjects
medicine.medical_specialty, biology, core temperature, Physiology, Athletes, Vascular damage Radboud Institute for Health Sciences [Radboudumc 16], Metabolic Disorders Radboud Institute for Health Sciences [Radboudumc 6], exercise performance, Anthropometry, hyperthermia, biology.organism_classification, Heat stress, Toolbox, Physiological responses, Incremental exercise, Olympic Games, Heat acclimation, Physiology (medical), Exercise performance, Physical therapy, medicine, Elite athletes, Psychology
Abstract

Contains fulltext : 238809.pdf (Publisher’s version ) (Open Access) The environmental conditions during the Tokyo Olympic and Paralympic Games are expected to be challenging, which increases the risk for participating athletes to develop heat-related illnesses and experience performance loss. To allow safe and optimal exercise performance of Dutch elite athletes, the Thermo Tokyo study aimed to determine thermoregulatory responses and performance loss among elite athletes during exercise in the heat, and to identify personal, sports-related, and environmental factors that contribute to the magnitude of these outcomes. For this purpose, Dutch Olympic and Paralympic athletes performed two personalized incremental exercise tests in simulated control (15°C, relative humidity (RH) 50%) and Tokyo (32°C, RH 75%) conditions, during which exercise performance and (thermo)physiological parameters were obtained. Thereafter, athletes were invited for an additional visit to conduct anthropometric, dual-energy X-ray absorptiometry (DXA), and 3D scan measurements. Collected data also served as input for a thermophysiological computer simulation model to estimate the impact of a wider range of environmental conditions on thermoregulatory responses. Findings of this study can be used to inform elite athletes and their coaches on how heat impacts their individual (thermo)physiological responses and, based on these data, advise which personalized countermeasures (i.e. heat acclimation, cooling interventions, rehydration plan) can be taken to allow safe and maximal performance in the challenging environmental conditions of the Tokyo 2020 Olympic and Paralympic Games.

Published
2021

25. Things that help out: designing smart wearables as partners in stress management

Author

Eric Vermetten, Catholijn M. Jonker, Marco C. Rozendaal, Xueliang (Sean) Li, and Kaspar M. B. Jansen

Subjects
Stress management, Interaction design, Computer science, Chronic posttraumatic stress disorder, Internet privacy, Wearable computer, Wearable technologies, 02 engineering and technology, Artificial Intelligence, Health care, 0202 electrical engineering, electronic engineering, information engineering, Smart wearables, Chronic PTSD, 0501 psychology and cognitive sciences, Affective computing, 050107 human factors, Wearable technology, business.industry, 05 social sciences, 020207 software engineering, Human-Computer Interaction, Philosophy, business
Abstract

We propose an approach to designing smart wearables that act as partners to help people cope with stress in daily life. Our approach contributes to the developing field of smart wearables by addressing how technological capabilities can be designed to establish partnerships that consider the person, the situation, and the appropriate type of support. As such, this study also contributes to healthcare by opening up novel technology-supported routes to stress treatment and care. We present the results of a phenomenological study conducted with three war veterans who suffer from chronic posttraumatic stress disorder. We describe how their experiences of dealing with their stress informed our design approach, and discuss the implications of these results on smart wearables and stress management in general. We conclude by reflecting on the limitations of this study and directions for future work.

Published
2020

26. An inertial measurement unit based method to estimate hip and knee joint kinematics in team sport athletes on the field

Author

Doris van der Laan, Erik Wilmes, Kaspar M. B. Jansen, Koen A.P.M. Lemmink, Frans C. T. van der Helm, Cornelis J. de Ruiter, Riemer J K Vegter, Annemarijn Steijlen, Geert J.P. Savelsbergh, Bram J C Bastiaansen, Michel Brink, Edwin A Goedhart, SMART Movements (SMART), AMS - Sports, Motor learning & Performance, Physiology, and IBBA

Subjects
Male, Kinematics, Knee Joint, Team sport, General Chemical Engineering, 02 engineering and technology, Running, POSITION, Mathematics, SWING PHASE, Orthodontics, 0303 health sciences, biology, General Neuroscience, MENS PROFESSIONAL FOOTBALL, TRAINING LOAD, Smart textiles, 021001 nanoscience & nanotechnology, Inertial measurement units, Biomechanical Phenomena, medicine.anatomical_structure, Sprint, Hip Joint, Performance enhancement, 0210 nano-technology, musculoskeletal diseases, HAMSTRING INJURIES, Angular velocity, EXERCISE, General Biochemistry, Genetics and Molecular Biology, Young Adult, 03 medical and health sciences, Inertial measurement unit, Issue 159, Soccer, medicine, Humans, SOCCER PLAYERS, Pelvis, Mechanical Phenomena, 030304 developmental biology, Behavior, Lower extremity, General Immunology and Microbiology, Athletes, Injury prevention, PERFORMANCE, biology.organism_classification, PREVENTION, Hockey, MECHANICS
Abstract

Current athlete monitoring practice in team sports is mainly based on positional data measured by global positioning or local positioning systems. The disadvantage of these measurement systems is that they do not register lower extremity kinematics, which could be a useful measure for identifying injury-risk factors. Rapid development in sensor technology may overcome the limitations of the current measurement systems. With inertial measurement units (IMUs) securely fixed to body segments, sensor fusion algorithms and a biomechanical model, joint kinematics could be estimated. The main purpose of this article is to demonstrate a sensor setup for estimating hip and knee joint kinematics of team sport athletes in the field. Five male subjects (age 22.5 +/- 2.1 years; body mass 77.0 +/- 3.8 kg; height 184.3 +/- 5.2 cm; training experience 15.3 +/- 4.8 years) performed a maximal 30-meter linear sprint. Hip and knee joint angles and angular velocities were obtained by five IMUs placed on the pelvis, both thighs and both shanks. Hip angles ranged from 195 degrees (+/- 8 degrees) extension to 100.5 degrees (+/- 8 degrees) flexion and knee angles ranged from 168.6 degrees (+/- 12 degrees) minimal flexion and 62.8 degrees (+/- 12 degrees) maximal flexion. Furthermore, hip angular velocity ranged between 802.6 degrees.s(-1) (+/- 192 degrees.s(-1)) and -674.9 degrees.s(-1) (+/- 130 degrees.s(-1)). Knee angular velocity ranged between 1155.9 degrees.s(-1) (+/- 200 degrees.s(-1)) and -1208.2 degrees.s(-1) (+/- 264 degrees.s(-1)). The sensor setup has been validated and could provide additional information with regard to athlete monitoring in the field. This may help professionals in a daily sports setting to evaluate their training programs, aiming to reduce injury and optimize performance.

Published
2020

27. Multi-scale experimental testing on variable stiffness and damping components for semi-active structural control

Author

Qinyu Wang, Arjan P.H.W. Habraken, Kaspar M. B. Jansen, Patrick Teuffel, Gennaro Senatore, and Innovative Structural Design

Subjects
Damping ratio, seismic protection, Materials science, of-the-art, vibration control, dampers, Truss, Flexural rigidity, Bending, Viscoelasticity, Viscoelastic material, state, shape-memory polymers, Flexural strength, variable stiffness and damping, structural joint, semi-active vibration control, Ultimate tensile strength, adaptive structures, Ceramics and Composites, Multiscale experimental testing, Composite material, Ductility, control-systems, Civil and Structural Engineering
Abstract

This paper presents experimental testing of a new semi-active vibration control device comprising a shape memory polymer (SMP) core that is reinforced by an SMP-aramid composite skin. This control device works as a load-transfer component that can be integrated into truss and frame structures in the form of a joint. At the material level, thermal actuation from ambient (25 degrees C) to transition temperature (65 degrees C) causes a significant 40fold increase in damping due to viscoelastic effects. At the component level, uniaxial tensile and four-point bending tests have shown that tensile strength depends primarily on the bond strength between the reinforcement skin and the structural element while flexural strength depends on the strength of the reinforcement skin fibers. Through cyclic testing, it has been observed that material viscoelasticity is beneficial to ductility and energy dissipation. When the joint core is actuated to the SMP transition temperature, axial and flexural stiffness decrease by up to 50% and 90%, respectively. The property change at material and component levels enable tuning the frequency and damping ratio at the structure level, which has been successfully employed to mitigate the dynamic response of a 1/10 scale three-story prototype frame under resonance and earthquake loadings.

Published
2022

28. Impact of different climatic conditions on peak core temperature of elite athletes during exercise in the heat: a Thermo Tokyo simulation study

Author

Lennart P J Teunissen, Kaspar M B Jansen, Emiel Janssen, Boris R M Kingma, Johannus Q de Korte, and Thijs M H Eijsvogels

Subjects
All institutes and research themes of the Radboud University Medical Center, Athlete, Vascular damage Radboud Institute for Health Sciences [Radboudumc 16], Physical Therapy, Sports Therapy and Rehabilitation, Orthopedics and Sports Medicine, Thermoregulation, Heat stress, Olympics
Abstract

ObjectivesTo evaluate how separate and combined climatic parameters affect peak core temperature during exercise in the heat using computer simulations fed with individual data.MethodsThe impact of eight environmental conditions on rectal temperature (Tre) was determined for exercise under heat stress using the Fiala-thermal-Physiology-and-Comfort simulation model. Variations in ambient temperature (Ta±6°C), relative humidity (RH±15%) and solar radiation (SR+921 W/m2) were assessed in isolation and combination (worst-case/best-case scenarios) and compared with baseline (Ta32°C, RH 75%, SR 0 W/m2). The simulation model was fed with personal, anthropometric and individual exercise characteristics.Results54 athletes exercised for 46±10 min at baseline conditions and achieved a peak core temperature of 38.9±0.5°C. Simulations at a higher Ta (38°C) and SR (921 W/m2) resulted in a higher peak Tre compared with baseline (+0.6±0.3°C and +0.5±0.2°C, respectively), whereas a higher RH (90%) hardly affected peak Tre (+0.1±0.1°C). A lower Ta (26°C) and RH (60%) reduced peak Tre by −0.4±0.2°C and a minor −0.1±0.1°C, respectively. The worst-case simulation yielded a 1.5±0.4°C higher Tre than baseline and 2.0±0.7°C higher than the best-case condition.ConclusionCombined unfavourable climatic conditions produce a greater increase in peak core temperature than the sum of its parts in elite athletes exercising in the heat.

Published
2022

29. Low-Cost Wearable Fluidic Sweat Collection Patch for Continuous Analyte Monitoring and Offline Analysis

Author

Annemarijn S. M. Steijlen, Kaspar M. B. Jansen, Jeroen Bastemeijer, Paddy J. French, and Andre Bossche

Subjects
Ions, Wearable Electronic Devices, Humans, Sweating, Biosensing Techniques, Sweat, Analytical Chemistry, Monitoring, Physiologic
Abstract

Sweat sensors allow for new unobtrusive ways to continuously monitor an athlete's performance and health status. Significant advances have been made in the optimization of sensitivity, selectivity, and durability of electrochemical sweat sensors. However, comparing the in situ performance of these sensors in detail remains challenging because standardized sweat measurement methods to validate sweat sensors in a physiological setting do not yet exist. Current collection methods, such as the absorbent patch technique, are prone to contamination and are labor-intensive, which limits the number of samples that can be collected over time for offline reference measurements. We present an easy-to-fabricate sweat collection system that allows for continuous electrochemical monitoring, as well as chronological sampling of sweat for offline analysis. The patch consists of an analysis chamber hosting a conductivity sensor and a sequence of 5 to 10 reservoirs that contain level indicators that monitor the filling speed. After testing the performance of the patch in the laboratory, elaborate physiological validation experiments (3 patch locations, 6 participants) were executed. The continuous sweat conductivity measurements were compared with laboratory [Na+] and [Cl-] measurements of the samples, and a strong linear relationship (R2 = 0.97) was found. Furthermore, sweat rate derived from ventilated capsule measurement at the three locations was compared with patch filling speed and continuous conductivity readings. As expected from the literature, sweat conductivity was linearly related to sweat rate as well. In short, a successfully validated sweat collection patch is presented that enables sensor developers to systematically validate novel sweat sensors in a physiological setting.

Published
2022

31. Performance and thermoregulation of Dutch Olympic and Paralympic athletes exercising in the heat: Rationale and design of the Thermo Tokyo study: The journal

Author

Johannus Q, de Korte, Coen C W G, Bongers, Maria T E, Hopman, Lennart P J, Teunissen, Kaspar M B, Jansen, Boris R M, Kingma, Sam B, Ballak, Kamiel, Maase, Maarten H, Moen, Jan-Willem, van Dijk, Hein A M, Daanen, and Thijs M H, Eijsvogels

Subjects
Olympic Games, core temperature, exercise performance, Method Article, hyperthermia, Heat stress, Research Article
Abstract

The environmental conditions during the Tokyo Olympic and Paralympic Games are expected to be challenging, which increases the risk for participating athletes to develop heat-related illnesses and experience performance loss. To allow safe and optimal exercise performance of Dutch elite athletes, the Thermo Tokyo study aimed to determine thermoregulatory responses and performance loss among elite athletes during exercise in the heat, and to identify personal, sports-related, and environmental factors that contribute to the magnitude of these outcomes. For this purpose, Dutch Olympic and Paralympic athletes performed two personalized incremental exercise tests in simulated control (15°C, relative humidity (RH) 50%) and Tokyo (32°C, RH 75%) conditions, during which exercise performance and (thermo)physiological parameters were obtained. Thereafter, athletes were invited for an additional visit to conduct anthropometric, dual-energy X-ray absorptiometry (DXA), and 3D scan measurements. Collected data also served as input for a thermophysiological computer simulation model to estimate the impact of a wider range of environmental conditions on thermoregulatory responses. Findings of this study can be used to inform elite athletes and their coaches on how heat impacts their individual (thermo)physiological responses and, based on these data, advise which personalized countermeasures (i.e. heat acclimation, cooling interventions, rehydration plan) can be taken to allow safe and maximal performance in the challenging environmental conditions of the Tokyo 2020 Olympic and Paralympic Games.

Published
2021

33. 4D printing of reconfigurable metamaterials and devices

Author

Kaspar M. B. Jansen, Amir A. Zadpoor, Teunis van Manen, and S. Janbaz

Subjects
Fabrication, Fused deposition modeling, Computer science, Metamaterial, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, 3d printer, law.invention, Mechanics of Materials, law, TA401-492, Electronic engineering, General Materials Science, 0210 nano-technology, Material properties, Materials of engineering and construction. Mechanics of materials, 4d printing
Abstract

Shape-shifting materials are a powerful tool for the fabrication of reconfigurable materials. Upon activation, not only a change in their shape but also a large shift in their material properties can be realized. As compared with the 4D printing of 2D-to-3D shape-shifting materials, the 4D printing of reconfigurable (i.e., 3D-to-3D shape-shifting) materials remains challenging. That is caused by the intrinsically 2D nature of the layer-by-layer manner of fabrication, which limits the possible shape-shifting modes of 4D printed reconfigurable materials. Here, we present a single-step production method for the fabrication and programming of 3D-to-3D shape-changing materials, which requires nothing more than a simple modification of widely available fused deposition modeling (FDM) printers. This simple modification allows the printer to print on curved surfaces. We demonstrate how this modified printer can be combined with various design strategies to achieve high levels of complexity and versatility in the 3D-to-3D shape-shifting behavior of our reconfigurable materials and devices. We showcase the potential of the proposed approach for the fabrication of deployable medical devices including deployable bifurcation stents that are otherwise extremely challenging to create. Shape-shifting structures are important building blocks in the design of reconfigurable materials and devices with advanced functionalities. Here, versatile metamaterials with 3D-to-3D shape-shifting behavior upon thermal activation are fabricated by adapting a 3D printer to print on curved surfaces.

Published
2021

34. Creep behaviour of FM906 glass-fibre epoxy as used in heated fibre metal laminates

Author

Jos Sinke, Michiel Hagenbeek, Marcelo M Dias, and Kaspar M. B. Jansen

Subjects
Materials science, Long term durability, Mechanical Engineering, Glass fiber, Epoxy, Metal, Creep, Time–temperature superposition, Mechanics of Materials, visual_art, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Composite material
Abstract

An innovative deicing system for aircraft leading edges has been developed which integrates heater elements into fibre metal laminates. Such an electrical system can lead to weight reductions and more efficient performances compared to conventional bleed air systems. However, the combination of thermal and mechanical loadings also raises new questions on the durability of such a structure, in particular due to the repeated heating to elevated temperature. The linear viscoelastic creep behaviour, including the effects of temperature and ageing, is therefore investigated for manufactured FM906 glass-fibre epoxy composite as used in heated GLARE. A master curve is derived based on the time–temperature and time–age superposition. The effect of physical ageing during loading is included in a long-term creep prediction.

Published
2019

36. Protection to thermal impact of solar radiation

Author

Linda Plaude, L.P.J. Teunissen, and Kaspar M. B. Jansen

Subjects
Sunlight, Materials science, Infrared, solar radiation, Thermal impact, TA213-215, Textile bleaching, dyeing, printing, etc, Radiation, medicine.disease_cause, thermal impact, Temperature measurement, Atomic and Molecular Physics, and Optics, heat stress, Engineering machinery, tools, and implements, TP890-933, Heat transfer, medicine, Electrical and Electronic Engineering, Composite material, Ultraviolet, reflective fabric, Visible spectrum
Abstract

Prolonged exposure to solar radiation can cause considerable heat stress. The application of reflective materials in garments or sunscreens is generally considered as an appropriate protective strategy. In this study, we aimed to compare a range of reflective and control fabrics on their ability to reduce the thermal impact of solar radiation. We evaluated 16 reflective and 5 control fabrics, varying in applicability for garments and/or sunscreens. Transmission of ultraviolet, visible light and infrared radiation was studied using artificial solar light. Thermal impact reduction was first studied using artificial infrared light and secondly using natural sunlight, measuring temperature right at the back and 10 cm behind the fabric after a 10-minute exposure. Most samples showed comparably low radiation transmission (

Published
2021

37. Seismic control performance of a three-story frame prototype equipped with semi-active variable stiffness and damping structural joints

Author

Gennaro Senatore, Arjan P.H.W. Habraken, Qinyu Wang, Patrick Teuffel, Kaspar M. B. Jansen, and Innovative Structural Design

Subjects
Damping ratio, Materials science, business.industry, of-the-art, dampers, shake-table test, Natural frequency, Structural engineering, Geotechnical Engineering and Engineering Geology, viscoelastic material, state, Shear (sheet metal), Core (optical fiber), semi-active control, Shape-memory polymer, Acceleration, variable stiffness and damping, seismic response control, Thermal, adaptive structures, Earth and Planetary Sciences (miscellaneous), business, control-systems, Excitation
Abstract

This paper presents numerical and experimental studies on semi-active seismic response control of structures equipped with variable stiffness and damping structural joints. Such adaptive joints, which are comprised of a shape memory polymer (SMP) core reinforced by an SMP-aramid composite skin, function as load-transfer components as well as semi-active control devices. The SMP core material can transition from a glassy to a rubbery state through thermal actuation resulting in a shift of the structural natural frequencies and a parallel increase of damping ratio, which enables a new semi-active control strategy. Control performance has been evaluated on a three-story frame equipped with 12 adaptive joints and subjected to seismic excitations. Full-transient analysis has shown that when the joints are thermally actuated to the transition temperature (65 degrees C), acceleration and base shear are reduced by up to 62% and 65%, respectively. Shake-table tests have been carried out on a 1/10-scale prototype, confirming that through thermal actuation of the adaptive joints the structural damping ratio increases from 2.6% to 11.3% and the first natural frequency shifts by up to 37%. As the structure becomes more flexible, an increase of displacements and interstory drift might occur. However, depending on the seismic excitation, top-story acceleration and base shear are significantly reduced in the range 43%-50% and 35%-51%, respectively. These results confirm that semi-active control through thermal actuation of variable stiffness and damping structural joints is effective to mitigate the structure response under seismic excitation.

Published
2021

38. Smart sensor tights: Movement tracking of the lower limbs in football

Author

Erik Wilmes, J Bastemeijer, Andre Bossche, Annemarijn Steijlen, Kaspar M. B. Jansen, Patrick J. French, Bram J C Bastiaansen, and Bastiaan Burgers

Subjects
Wearable Sensors, Movement tracking, football, inertial measurement units, Computer science, business.industry, Computer vision, Artificial intelligence, Football, business
Abstract

This article presents a novel smart sensor garment with integrated miniaturized inertial measurements units (IMUs) that can be used to monitor lower body kinematics during daily training activities, without the need of extensive technical assistance throughout the measurements. The smart sensor tights enclose five ultra-light sensor modules that measure linear accelerations, angular velocities, and the earth magnetic field in three directions. The modules are located at the pelvis, thighs, and shanks. The garment enables continuous measurement in the field at high sample rates (250 Hz) and the sensors have a large measurement range (32 g, 4,000°/s). They are read out by a central processing unit through an SPI bus, and connected to a centralized battery in the waistband. A fully functioning prototype was built to perform validation studies in a lab setting and in a field setting. In the lab validation study, the IMU data (converted to limb orientation data) were compared with the kinematic data of an optoelectronic measurement system and good validity (CMCs >0.8) was shown. In the field tests, participants experienced the tights as comfortable to wear and they did not feel restricted in their movements. These results show the potential of using the smart sensor tights on a regular base to derive lower limb kinematics in the field.

Published
2021

39. A larger statistical basis and a wider application area of the PMV equation in the Fanger model

Author

Peter Vink, Paul Roelofsen, and Kaspar M. B. Jansen

Subjects
workplace, Mathematical modelling, Model application, Heating Ventilation and Air Conditioning (HVAC) systems, thermal comfort, Statistics, Thermal comfort, Building and Construction, performance, Computer Science Applications, Mathematics
Abstract

For sedentary activities, the PMV equation, derived by Fanger, is mainly based on the research of Nevins et al. (720 test subjects). Nevins' experiments were later on repeated by Fanger, but with 128 college-age Danish subjects and 128 elderly Danish subjects, instead of American subjects. Rohles did the research from Nevins et al. again, but over a more extensive temperature range and more, namely 1600, test subjects. Rohles' research results have been partly included in the derivation of the PPD equation, but not in the derivation for the PMV equation. Rohles' experimental results are published at a later time than the publication of the thesis of Fanger. The question arises: ‘If Rohles' experimental results were included in the derivation of the PMV equation, instead of Nevins' experimental results, to what extent does that change the PMV equation and the application area of the PMV equation, with regard of validity, for sedentary activities?'. In the same way, as Fanger described in his thesis, and using the results of Rohles’ experiment, this study is limited to the derivation of a PMV equation with a wider PMV range than −2 to 2, for sedentary activities.

Published
2021

40. Performance Evaluation of Knitted and Stitched Textile Strain Sensors

Author

Kaspar M. B. Jansen

Subjects
Textile, Computer science, conductive yarns, Mechanical engineering, 02 engineering and technology, Review, lcsh:Chemical technology, 01 natural sciences, Biochemistry, textile strain sensors, Analytical Chemistry, lcsh:TP1-1185, Sensitivity (control systems), Electrical and Electronic Engineering, Instrumentation, stitched sensor, business.industry, 010401 analytical chemistry, Usability, knitted sensor, 021001 nanoscience & nanotechnology, Clothing, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Working range, performance evaluation, Gauge factor, 0210 nano-technology, business
Abstract

By embedding conductive yarns in, or onto, knitted textile fabrics, simple but robust stretch sensor garments can be manufactured. In that way resistance based sensors can be fully integrated in textiles without compromising wearing comfort, stretchiness, washability, and ease of use in daily life. The many studies on such textile strain sensors that have been published in recent years show that these sensors work in principle, but closer inspection reveals that many of them still have severe practical limitations like a too narrow working range, lack of sensitivity, and undesired time-dependent and hysteresis effects. For those that intend to use this technology it is difficult to determine which manufacturing parameters, shape, stitch type, and materials to apply to realize a functional sensor for a given application. This paper therefore aims to serve as a guideline for the fashion designers, electronic engineers, textile researchers, movement scientists, and human–computer interaction specialists planning to create stretch sensor garments. The paper is limited to textile based sensors that can be constructed using commercially available conductive yarns and existing knitting and embroidery equipment. Within this subtopic, relevant literature is discussed, and a detailed quantitative comparison is provided focusing on sensor characteristics like the gauge factor, working range, and hysteresis.

Published
2020

42. Vibration Suppression Through Variable Stiffness and Damping Structural Joints

Author

Gennaro Senatore, Patrick Teuffel, Qinyu Wang, Arjan P.H.W. Habraken, Kaspar M. B. Jansen, and Innovative Structural Design

Subjects
Materials science, vibration control, Geography, Planning and Development, 0211 other engineering and technologies, Vibration control, Truss, 020101 civil engineering, 02 engineering and technology, Viscoelasticity, viscoelastic material, 0201 civil engineering, lcsh:HT165.5-169.9, medicine, 021110 strategic, defence & security studies, variable stiffness and damping joint, business.industry, Stiffness, Moving load, Building and Construction, Structural engineering, lcsh:City planning, structural dynamics, Urban Studies, Vibration, Truss bridge, lcsh:TA1-2040, Dynamic loading, adaptive structures, medicine.symptom, lcsh:Engineering (General). Civil engineering (General), frequency shift, business
Abstract

This paper introduces a new semi-active strategy for vibration control of truss and frame structures equipped with variable stiffness and damping joints which consist of a shape memory polymer (SMP) core reinforced by an SMP-aramid composite skin. When the joints are actuated to the transition temperature through thermal actuation, the SMP core transitions from a glassy to a rubbery state through a viscoelastic region, which causes a stiffness reduction and an increase of damping. The mechanic behavior of the joint can be thought of as transitioning from a moment to a pin connection. This way, it is possible to cause a shift of the structure natural frequencies and to increase damping, which is employed to obtain a significant reduction of the dynamic response. This paper comprises two parts: (1) characterization of a variable stiffness and damping material model through experimental testing; (2) numerical simulations of a truss bridge and a four-story frame, which are equipped with variable stiffness and damping joints. The truss bridge (case A) is subjected to a resonance and a moving load while the four-story frame (case B) is subjected to El Centro earthquake loading. For case A under resonance loading, the dynamic response can be reduced exclusively through a frequency shift and ignoring viscoelastic effects. For case A under moving load and case B under earthquake loading, vibration suppression is mostly caused by the increase of damping due to viscoelastic effects. Control time delays due to joint heating have been included in the analysis. When the joints are actuated to the transition range 55°C–65°C, which is specific to the SMP adopted in this study, the acceleration peak amplitude reduces by up to 95% and 87%, for case A and case B, respectively. For both cases, damping increases by up to 2.2% from undamped conditions (25°C). This work has shown that the adoption of variable stiffness and damping structural joints has great potential to enable a new and effective semi-active control strategy to significantly reduce the structure response under a wide range of dynamic loading conditions.

Published
2020

43. ThermalWear: Exploring Wearable On-chest Thermal Displays to Augment Voice Messages with Affect

Author

Pablo Cesar, Xingyu Yang, Abdallah El Ali, Jack Jansen, Jess Hartcher-O’Brien, Swamy Ananthanarayan, Kaspar M. B. Jansen, Thomas Röggla, and Centrum Wiskunde & Informatica, Amsterdam (CWI), The Netherlands

Subjects
medicine.medical_specialty, media_common.quotation_subject, emotion, Wearable computer, chest, 02 engineering and technology, Audiology, Affect (psychology), wearable, thermal, prosody, Perception, 0202 electrical engineering, electronic engineering, information engineering, medicine, 0501 psychology and cognitive sciences, Valence (psychology), Prosody, 050107 human factors, media_common, Modality (human–computer interaction), 05 social sciences, voice, 020207 software engineering, display, Emotional prosody, affect, Augment, Psychology
Abstract

Voice is a rich modality for conveying emotions, however emotional prosody production can be situationally or medically impaired. Since thermal displays have been shown to evoke emotions, we explore how thermal stimulation can augment perception of neutrally-spoken voice messages with affect. We designed ThermalWear, a wearable on-chest thermal display, then tested in a controlled study (N=12) the effects of fabric, thermal intensity, and direction of change. Thereafter, we synthesized 12 neutrally-spoken voice messages, validated (N=7) them, then tested (N=12) if thermal stimuli can augment their perception with affect. We found warm and cool stimuli (a) can be perceived on the chest, and quickly without fabric (4.7-5s) (b) do not incur discomfort (c) generally increase arousal of voice messages and (d) increase / decrease message valence, respectively. We discuss how thermal displays can augment voice perception, which can enhance voice assistants and support individuals with emotional prosody impairments.

Published
2020

44. A novel sweat rate and conductivity sensor patch made with low-cost fabrication techniques

Author

Andre Bossche, Annemarijn Steijlen, J. Bastemeijer, Paddy J. French, and Kaspar M. B. Jansen

Subjects
Materials science, Fabrication, Laser cutting, business.industry, Sweat patch, 010401 analytical chemistry, 02 engineering and technology, Conductivity, 021001 nanoscience & nanotechnology, 01 natural sciences, Conductivity sensor, 0104 chemical sciences, Sweat rate sensor, Printed circuit board, Electrode, Optoelectronics, Adhesive, 0210 nano-technology, business, Electrical impedance, FOIL method
Abstract

Sweat sensor patches offer new opportunities for unobtrusive monitoring of an athlete’s physical status. This paper presents a novel sweat rate and sweat conductivity patch that is easy to prototype and can be made with common low-cost production techniques: laser cutting and standard printed circuit board (PCB) manufacturing. The device consists of a patch made from hydrophilic PET foil, a double-sided adhesive and a thin PCB with gold electrodes. Two electrodes, which are continuously in contact with the inflowing fluid, measure the sweat conductivity and a separate system with interdigitated electrodes measures the filling process of the reservoirs. Impedance measurement results of both systems demonstrate the working of the concept.

Published
2020

45. Effect of temperature and humidity on moisture diffusion in an epoxy moulding compound material

Author

M.F. Zhang, Duc-Khoi Vu, L.J. Ernst, Kaspar M. B. Jansen, and Laurens Weiss

Subjects
Materials science, 02 engineering and technology, 01 natural sciences, Modelling, Diffusion, Desorption, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Composite material, Diffusion (business), Safety, Risk, Reliability and Quality, Moisture, 010302 applied physics, 020208 electrical & electronic engineering, Humidity, Sorption, Condensed Matter Physics, Fick's laws of diffusion, Atomic and Molecular Physics, and Optics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Diffusion process, Moulding compound, Saturation (chemistry), Micro-electronic device
Abstract

In this paper we propose a new multistep characterisation method to be able to map out the dependency of moisture diffusion parameters of a polymeric material over a range of temperature and humidity conditions in a limited amount of time. We do that by (1) using a moisture sorption analyser which can continuously monitor weight changes with microgram accuracy, (2) using thin samples which speeds up the diffusion process and (3) already switch to the next humidity level at 90 or 95% completion of a diffusion step. A multistep diffusion model was developed to account for the overlapping diffusion steps. This model showed to be extremely accurate for fitting experiments consisting of five absorption and one desorption steps. We show that for temperatures up to 85 °C and humidity level between 0 and 85% RH the diffusion of our material was essentially Fickian with a diffusion coefficient ranging from 3.8 × 10−7 mm2/s at 20 °C to 3.6 × 10−6 mm2/s at 85 °C. The moisture saturation concentrations showed a slightly non-linear variation with the applied humidity level.

Published
2020

46. Development of a microfluidic collection system to measure electrolyte variations in sweat during exercise

Author

Annemarijn Steijlen, Andre Bossche, Kaspar M. B. Jansen, J. Bastemeijer, Paddy J. French, and W. A. Groen

Subjects
Change over time, Materials science, integumentary system, Microfluidics, 010401 analytical chemistry, Sweating, 02 engineering and technology, Electrolyte, 021001 nanoscience & nanotechnology, Collection system, 01 natural sciences, 0104 chemical sciences, SWEAT, Electrolytes, Sweat, 0210 nano-technology, Exercise, Biomedical engineering
Abstract

A wide variety of electrochemical sweat sensors are recently being developed for real-time monitoring of biomarkers. However, from a physiological perspective, little is known about how sweat biomarkers change over time. This paper presents a method to collect and analyze sweat to identify inter and intraindividual variations of electrolytes during exercise. A new microfluidic sweat collection system is developed which consists of a patch covering the collection surface and a sequence of reservoirs. Na+, Cl- and K+ are measured with ion chromatography afterwards. The measurements show that with the new collector, variations in these ion concentrations can be measured reliably over time.

Published
2020

47. Aging of Polyphenylene Sulfide-Glass Composite and Polysulfone in Highly Oxidative and Strong Alkaline Environments

Author

J. van Kranendonk, Kaspar M. B. Jansen, J. van Turnhout, A. J. Böttger, and X. X. Zheng

Subjects
Materials science, Sulfide, Materials Science (miscellaneous), Glass fiber, 02 engineering and technology, Electrolyte, polysulfone, 010402 general chemistry, 01 natural sciences, lcsh:Technology, law.invention, chemistry.chemical_compound, law, accelerated aging, Polysulfone, Dissolution, polymers, chemistry.chemical_classification, Electrolysis, modular alkaline electrolysis, lcsh:T, Alkaline water electrolysis, polyphenylene sulfide, long-term creep, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Chemical engineering, pure oxygen, 0210 nano-technology, lifetime prediction
Abstract

Alkaline water electrolysis becomes increasingly important for the supply of renewable energy, and of raw material for the chemical industry. An attractive choice for the encapsulation of the electrolyte cell is an (advanced) engineering polymer. The objective of this paper is to find a suitable one that can withstand for many years: 30 wt% KOH solution and pure oxygen at a high pressure of 50 bar and at an elevated temperature of 90°C. Using CES EduPack, 12 possible thermoplastic polymers were selected, of which polyphenylene sulfide (PPS) and polysulfone (PSU) were further investigated using accelerated testing. The polymers have been exposed to three KOH concentrations (15, 30 and 45 wt%), two oxygen pressures (pure O2at 5 bar and air with pO2= 20%), and three temperatures (90°C, 120°C, and 170°C). Extensive characterization of the exposed samples has been carried out using various techniques, including weight, tensile, DMA, and creep-recovery measurements, as well as DSC, FTIR, XRD and SEM. After 12 weeks of aging, glass fiber reinforced PPS failed in a strong alkaline solution at high temperatures, due to the dissolution of the glass fibers. The PPS matrix itself and PSU turned out to be resistant to thermo-oxidative and chemical degradation under the conditions tested. Only marginal changes in mechanical, visco-elastic and thermal behavior were observed, which can be ascribed to physical rather than chemical aging. In view of the brittle nature of PPS, it could be concluded that PSU is the most promising candidate for the long-term application in alkaline electrolysis. Extrapolating the data using time-temperature superposition, it is predicted that PSU will retain its integrity and mechanical properties for a period of 20 years of operation.

Published
2020

48. Hydrophobin gene deletion and environmental growth conditions impact mechanical properties of mycelium by affecting the density of the material

Author

Appels, Freek V W, Dijksterhuis, Jan, Lukasiewicz, Catherine E, Jansen, Kaspar M B, Wösten, Han A B, Krijgsheld, Pauline, Sub Molecular Microbiology, Molecular Microbiology, Westerdijk Fungal Biodiversity Institute, Westerdijk Fungal Biodiversity Institute - Food and Indoor Mycology, Sub Molecular Microbiology, and Molecular Microbiology

Subjects
0301 basic medicine, Hypha, Hydrophobin, lcsh:Medicine, 02 engineering and technology, Schizophyllum, Article, Fungal Proteins, Physical Phenomena, 03 medical and health sciences, Tensile Strength, Ultimate tensile strength, Food science, lcsh:Science, Mycelium, Mushroom, Multidisciplinary, biology, Strain (chemistry), Chemistry, fungi, lcsh:R, Schizophyllum commune, Wild type, Temperature, 021001 nanoscience & nanotechnology, biology.organism_classification, equipment and supplies, 030104 developmental biology, Thermogravimetry, lcsh:Q, 0210 nano-technology, Gene Deletion
Abstract

Filamentous fungi colonize substrates by forming a mycelium. This network of hyphae can be used as a bio-based material. Here, we assessed the impact of environmental growth conditions and deletion of the hydrophobin gene sc3 on material properties of the mycelium of the mushroom forming fungus Schizophyllum commune. Thermogravimetric analysis showed that Δsc3 mycelium retained more water with increasing temperature when compared to the wild type. The Young’s modulus (E) of the mycelium ranged between 438 and 913 MPa when the wild type strain was grown in the dark or in the light at low or high CO2 levels. This was accompanied by a maximum tensile strength (σ) of 5.1–9.6 MPa. In contrast, E and σ of the Δsc3 strain were 3–4- fold higher with values of 1237–2727 MPa and 15.6–40.4 MPa, respectively. These values correlated with mycelium density, while no differences in chemical composition of the mycelia were observed as shown by ATR-FTIR. Together, genetic modification and environmental growth conditions impact mechanical properties of the mycelium by affecting the density of the mycelium. As a result, mechanical properties of wild type mycelium were similar to those of natural materials, while those of Δsc3 were more similar to thermoplastics.

Published
2018

49. Periprocedural Hydrogen Sulfide Therapy Improves Vascular Remodeling and Attenuates Vein Graft Disease

Author

Kip, Peter, primary, Tao, Ming, additional, Trocha, Kaspar M., additional, MacArthur, Michael R., additional, Peters, Hendrika A. B., additional, Mitchell, Sarah J., additional, Mann, Charlotte G., additional, Sluiter, Thijs J., additional, Jung, Jonathan, additional, Patterson, Suzannah, additional, Quax, Paul H. A., additional, de Vries, Margreet R., additional, Mitchell, James R., additional, and Keith Ozaki, C., additional

Published
2020
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