Deep Learning Enabled Early Predicting Cardiovascular Status Using Highly Sensitive Piezoelectric Sensor of Solution‐Processable Nylon‐11
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[1] Dongxue Han,et al. A self-protective piezoelectric-piezoresistive dual-mode device with superior dynamic-static mechanoresponse and energy harvesting performance enabled by flextensional transduction , 2022, Nano Energy.
[2] Nityananda Das,et al. Surface Potential Tuned Single Active Material Comprised Triboelectric Nanogenerator for a High Performance Voice Recognition Sensor. , 2022, Small.
[3] N. Annabi,et al. Recent Advances in Designing Electroconductive Biomaterials for Cardiac Tissue Engineering , 2022, Advanced healthcare materials.
[4] Zhenhui Kang,et al. Merkel receptor-inspired integratable and biocompatible pressure sensor with linear and ultrahigh sensitive response for versatile applications , 2022, Chemical Engineering Journal.
[5] Jacob T. Robinson,et al. A wireless millimetric magnetoelectric implant for the endovascular stimulation of peripheral nerves , 2022, Nature Biomedical Engineering.
[6] Jingquan Liu,et al. Piezoelectric Dynamics of Arterial Pulse for Wearable Continuous Blood Pressure Monitoring , 2022, Advanced materials.
[7] Varun Gupta,et al. Negatively bias driven enhancement in piezo response for self-powered biomedical and facial expression sensor , 2022, Applied Physics Letters.
[8] M. Yarmush,et al. Machine‐Assisted Discovery of Chondroitinase ABC Complexes toward Sustained Neural Regeneration , 2022, Advanced healthcare materials.
[9] C. Xiong,et al. Effect of Stretching on Crystalline Structure, Ferroelectric and Piezoelectric Properties of Solution-Cast Nylon-11 Films , 2021, Polymers.
[10] M. Ezzati,et al. Global epidemiology, health burden and effective interventions for elevated blood pressure and hypertension , 2021, Nature Reviews Cardiology.
[11] Joo Chuan Yeo,et al. Flexible Wearable Sensors for Cardiovascular Health Monitoring , 2021, Advanced healthcare materials.
[12] W. Asghar,et al. Advances in healthcare wearable devices , 2021, npj Flexible Electronics.
[13] Andres J. Rodriguez,et al. Sources of Inaccuracy in Photoplethysmography for Continuous Cardiovascular Monitoring , 2021, Biosensors.
[14] Michael A. Swiernik,et al. The emerging clinical role of wearables: factors for successful implementation in healthcare , 2021, npj Digital Medicine.
[15] M. Turakhia,et al. Smart wearable devices in cardiovascular care: where we are and how to move forward , 2021, Nature Reviews Cardiology.
[16] H. Haick,et al. Artificial Intelligence in Medical Sensors for Clinical Decisions. , 2021, ACS nano.
[17] S. Laurent,et al. Arterial Stiffness and Hypertension in the Elderly , 2020, Frontiers in Cardiovascular Medicine.
[18] M. M. Abolhasani,et al. Piezoelectric Nylon‐11 Fibers for Electronic Textiles, Energy Harvesting and Sensing , 2020, Advanced Functional Materials.
[19] Wei Gao,et al. Wireless battery-free wearable sweat sensor powered by human motion , 2020, Science Advances.
[20] Adrian Weller,et al. “Explaining” machine learning reveals policy challenges , 2020, Science.
[21] Yeon Sik Choi,et al. Unprecedented dipole alignment in α-phase nylon-11 nanowires for high-performance energy-harvesting applications , 2020, Science Advances.
[22] W. Kibbe,et al. Investigating sources of inaccuracy in wearable optical heart rate sensors , 2020, npj Digital Medicine.
[23] M. Blüher. Obesity: global epidemiology and pathogenesis , 2019, Nature Reviews Endocrinology.
[24] John A Rogers,et al. Bio-Integrated Wearable Systems: A Comprehensive Review. , 2019, Chemical reviews.
[25] Dongxue Han,et al. Bioinspired Microstructured Pressure Sensor Based on a Janus Graphene Film for Monitoring Vital Signs and Cardiovascular Assessment , 2018, Advanced Electronic Materials.
[26] Yonggang Huang,et al. Needle-shaped ultrathin piezoelectric microsystem for guided tissue targeting via mechanical sensing , 2018, Nature Biomedical Engineering.
[27] Robert Langer,et al. Flexible piezoelectric devices for gastrointestinal motility sensing , 2017, Nature Biomedical Engineering.
[28] Chang Kyu Jeong,et al. Self‐Powered Real‐Time Arterial Pulse Monitoring Using Ultrathin Epidermal Piezoelectric Sensors , 2017, Advanced materials.
[29] Dipankar Mandal,et al. Bio-assembled, piezoelectric prawn shell made self-powered wearable sensor for non-invasive physiological signal monitoring , 2017 .
[30] M. Haghi,et al. Wearable Devices in Medical Internet of Things: Scientific Research and Commercially Available Devices , 2017, Healthcare informatics research.
[31] M. Litt,et al. Unified Understanding of Ferroelectricity in n-Nylons: Is the Polar Crystalline Structure a Prerequisite? , 2016 .
[32] Yonggang Huang,et al. Conformal piezoelectric systems for clinical and experimental characterization of soft tissue biomechanics. , 2015, Nature materials.
[33] Geoffrey E. Hinton,et al. Deep Learning , 2015, Nature.
[34] Seiji Akita,et al. Toward Flexible and Wearable Human‐Interactive Health‐Monitoring Devices , 2015, Advanced healthcare materials.
[35] Sheng-Chia Chung,et al. The effect of obesity on quality of life in patients with diabetes and coronary artery disease. , 2010, American heart journal.
[36] Martin McKee,et al. Environmental and societal influences acting on cardiovascular risk factors and disease at a population level: a review. , 2009, International journal of epidemiology.
[37] Denise L. Smith,et al. Impact of excess body weight on arterial structure, function, and blood pressure in firefighters. , 2009, The American journal of cardiology.
[38] F. Hu,et al. Association of overweight with increased risk of coronary heart disease partly independent of blood pressure and cholesterol levels: a meta-analysis of 21 cohort studies including more than 300 000 persons. , 2007, Archives of internal medicine.
[39] J. Staessen,et al. Obesity is associated with increased arterial stiffness from adolescence until old age , 2005, Journal of hypertension.
[40] Alberto Radaelli,et al. Invited review: aging and the cardiovascular system. , 2003, Journal of applied physiology.
[41] P. Chowienczyk,et al. Determination of age-related increases in large artery stiffness by digital pulse contour analysis. , 2002, Clinical science.
[42] Geoffrey E. Hinton,et al. How neural networks learn from experience. , 1992, Scientific American.
[43] J. Scheinbeim,et al. Ferroelectric polarization mechanisms in nylon 11 , 1992 .
[44] J. Scheinbeim,et al. High-temperature characteristics of nylon-11 and nylon-7 piezoelectrics , 1991 .
[45] T. Soen,et al. Dielectric and Piezoelectric Properties of Nylon 9 and Nylon 11 , 1986 .
[46] J. Scheinbeim. Piezoelectricity in γ‐form Nylon 11 , 1981 .