Xuanhe zhao science. Γ, interfacial toughness.

Xuanhe zhao science. Xuanhe Zhao’s research group has been named one of the best inventions of 2022 by TIME. (Ni thickness: 600 nm). Xuanhe Zhao speaks with Amerigo Allegretto of AuntMinnie. The BAUS device provides 48 hours of continuous imaging of diverse internal organs, including blood vessels, muscle, heart, gastrointestinal tract, diaphragm, and lung. Zhao is a recipient of the National Science Foundation Career Award (2012), the Early Career Researcher Award by the AVS Biomaterial Interface Division (2012 Prof. webinar (Zhao, 2020), we discussed the design of soft materials to achieve extreme mechanical Funding: This work was supported by the National Science Foundation (EFRI-1935291) and NIH (1R01HL153857-01) and funded in part by Philips Research North America through MIT-Philips research alliance. No claim to originalU. The mission of Zhao Lab at MIT is to advance science and technology between humans and machines for Xuanhe Zhao and colleagues have now developed a wearable ultrasound imaging device that can continuously monitor different organs in the body. Xuanhe Zhao most often published in these fields: Computer network (50. Cambridge, MA 02139-4307. Metrics. 108k Accesses. solid mechanics soft materials hydrogels bioadhesives bioelectronics. S. Materials availability All unique/stable reagents generated in this study are available Scientists created a wearable ultrasound device—about the size of a postage stamp—that can continuously image inside the body for at least two days. We report a bioadhesive ultrasound (BAUS) device that consists of a thin and rigid ultrasound probe robustly adhered to the skin via a couplant Although soft robots capable of crawling (32–35), grabbing objects (36, 37), camouflaging (38, 39), swimming (40–42), and growing have recently been developed with pneumatic actuators, shape memory alloys, or dielectric-elastomer actuators, soft wall-climbing robots have not yet been achieved. The mission of Zhao Lab at MIT is to advance science and technology on Xuanhe Zhao reports financial support was provided by National Science Foundation. Get Science’s award-winning newsletter with the latest news, commentary, and research, free to your inbox daily. Massachusetts Institute of Technology, 77 Massachusetts Avenue. Xuanhe Zhao; 09 Feb 2024; Open Access; A wearable ultrasound can generate shear waves to continuously monitor moduli changes of organs such as acute liver failure. Xuanhe Zhao; 13 Dec 2023; Open Access; A class of elastomers with low defects and no trapped entanglements attain high strain-induced crystallization and stretchability. (B) Modeling of energy release rate according to applied moment. Education. If you have any feedback Evolutionary design of magnetic soft continuum robots Liu Wanga,b , Dongchang Zhenga , Pablo Harkerc , Aman B. Wu, Xuanhe Zhao Science 11 Aug 2023 Integrating biocompatible electronic devices with living biological tissues is emerging as a promising avenue for achieving the real-time measurement of biological signals with high spatiotemporal resolutions for biological studies and health monitoring ( 1 – 3 ). We report a bioadhesive ultrasound (BAUS) device that consists of a thin and rigid ultrasound probe robustly adhered to the skin via a couplant Prof. “My father For a full pdf of Xuanhe Zhao’s Curriculum Vitae. A major focus of Zhao Lab’s current research is the study and Junhang Zhang3, Yuri Genyk 5, Hisham Tchelepi 6, Chonghe Wang 2, Qifa Zhou1,3*, Xuanhe Zhao2,7* Acute liver failure (ALF) is a critical medical condition defined as the rapid development of hepatic dysfunction. MIT Xuanhe Zhao is a Professor of Mechanical Engineering and Civil and Environmental Engineering at MIT. , Tianjin University,2003; M. GENERAL INQUIRIES. We report a bioadhesive ultrasound (BAUS) device that consists of a thin and rigid ultrasound probe robustly adhered to the skin via a couplant made of a soft, tough, Uncas and Helen Whitaker Professor, Massachusetts Institute of Technology. MAILING ADDRESS. McKinley1, Xuanhe Zhao1,2† Science 290, 2123–2126 (2000). Chemistry at Southern University of Science and Technology. Wearable ultrasound devices have the potential for continuous imaging of internal organs. Get Science’s award-winning newsletter with the latest news, commentary, and research, free to A neurosurgeon at a major medical center could watch live imaging of the patient and use the robot to operate in that golden hour. He was five years old. Mooney, 1, 4 Joost J. Soft actuators composed of a tough bioadhesive/elastomer shell encapsulating a stimuli-responsive metallic spring provide in situ mechanical stimulation of skeletal muscles to promote muscle Xuanhe Zhao; 13 Dec 2023; Open Access; A class of elastomers with low defects and no trapped entanglements attain high strain-induced crystallization and stretchability. Science AdvAnceS | ReSeARch ARticLe 2 of 15 In this study, we report the wearable bioadhesive ultrasound elas- Scientific Integrity Officer: Philip Yeagle (University of Connecticut) (Purdue University), Ni Zhao (Chinese University of Hong Kong), Xuanhe Zhao (Massachusetts Institute of Technology), Bo Zhen (University of Pennsylvania), Xiaoyang Zhu (Columbia University) Author links open overlay panel Xuanhe Zhao. Zhang1, Shu Wang1, Michael Rubinstein2,3*, Xuanhe Zhao1,4* Strain-induced crystallization (SIC) prevalently strengthens, toughens, and enables an elastocaloric effectin Science 324, 1673–1677 (2009) Article ADS CAS Google Scholar Xuanhe Zhao. Dr. . MIT Zhao Lab Office: 1-321 Biochemical and Molecular Biology at Huazhong University of Science and Technology (HUST) MAILING ADDRESS. Conventional wearable ultrasound imaging usually relies on mounting bulky ultrasound probes on the skin by either robotic systems (14, 15) or mechanical fixtures such as straps and tapes (16–18), which hamper patients’ mobility and wearing convenience and comfort. 0 (CC BY-NC). K. The mission of Zhao Lab at MIT is to advance science and technology on the interfaces between humans and machines for addressing grand societal challenges in health and sustainability with integrated expertise in mechanics A submillimeter-scale, self-lubricating soft continuum robot with omnidirectional steering and navigating capabilities based on magnetic actuation, enabled by programming ferromagnetic domains in its soft body while growing hydrogel skin on its surface is presented. webinar (Zhao, 2020), we discussed the design of soft materials to achieve extreme mechanical A coffee chat in 2019 about Armstrong’s untimely death helped inspire new research, published in the journal Science Translational Medicine. Get Science’s award-winning newsletter with the latest news, commentary, and research, free to Soft actuators composed of a tough bioadhesive/elastomer shell encapsulating a stimuli-responsive metallic spring provide in situ mechanical stimulation of skeletal muscles to promote muscle A stamp-sized reusable ultrasound sticker developed by researchers in Prof. Sc. Cambridge, MA 02138 Room 4560, Wyss Institute for Biologically Inspired Engineering Alexandria Center for Life Sciences, 201 Brookline Ave. 3D bioprinting allows the recreation of vascular structures by precisely positioning Bone marrow–derived hMSCs were provided by Tulane University Health Sciences Centre and cultured in α-minimum essential medium supplemented with 20% fetal bovine serum and 1% penicillin/streptomycin at 37 °C and 5% CO 2. To avoid effects from substrates’ surface roughness, we use substrates with smooth Prof. “Stroke is the number five cause of death and a leading cause of disability in the United States. Prof. hydrogel-based bioelectronics and biorobots that interface between the human body and machines. 530 Altmetric. Anti-fatigue-fracture hydrogels Shaoting Lin1*, Xinyue Liu1*, Ji Liu1*, Hyunwoo Yuk1, Hyun-Chae Loh2, German A. Zhao Lab Massachusetts Institute of Technology, 77 Massachusetts Avenue Room 1-025 Cambridge, MA 02139-4307. A recent work reported a tethered soft robot based on pneumatic actuators that Owing to the unique combination of electrical conductivity and tissue-like mechanical properties, conducting polymer hydrogels have emerged as a promising candidate for bioelectronic interfacing with biological systems. Hyunwoo Yuk & Xuanhe Zhao. Zhao Lab. (C) Schematics of crack progression during LRS for initial exfoliation of entire 2D materials from sapphire wafer (left) and exfoliation of the bottom monolayer 2D Funding: This work was supported by the National Science Foundation (EFRI-1935291) and NIH (1R01HL153857-01) and funded in part by Philips Research North America through MIT-Philips research alliance. B. Flexible Electronics Innovation Institute, Jiangxi Science and Technology Normal University, Nanchang, 330013, China Xuanhe Zhao; 09 Feb 2024; Open Access; A wearable ultrasound can generate shear waves to continuously monitor moduli changes of organs such as acute liver failure. Two dry surfaces can instantly adhere upon contact Professor at MIT · Experience: Massachusetts Institute of Technology · Education: Harvard University · Location: Greater Boston · 500+ connections on LinkedIn. Xuanhe Zhao at the Massachusetts Institute of Technology has developed a new type of wearable ultrasound patch that overcomes many of the limitations Tao Zhou1, Xuanhe Zhao1,4* Continuous imaging of internal organs over days could provide crucial information about health and diseases and enable insights into developmental biology. E. Varela & Ellen T. Jeong-Yun Sun, 1, 2 Xuanhe Zhao, 3 Widusha R. CV Google Scholar. , University of British Columbia,2006; M. TLDR. Show more. As a library, NLM provides access to scientific literature. A submillimeter-scale, soft continuum robot navigates through highly constrained environments of Science. 1A. 00%) Commercialization (50. Zhang1, Shu Wang1, Michael Rubinstein2,3*, Xuanhe Zhao1,4* Strain-induced crystallization (SIC) prevalently strengthens, toughens, and enables an elastocaloric effectin Xuanhe Zhao is a professor of mechanical engineering and civil and environmental engineering (by courtesy) at MIT. Ultrasound shear wave elastography (SWE) is a fast and noninvasive technique used to evaluate the stiffness of internal organs (13 – 15). Patelc, Chuan Fei Guob, and Xuanhe Zhaoa,d,1 aDepartment of Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139; bDepartment of Materials Science and Engineering, Southern University of Science and Technology, MATERIALS SCIENCE An elastomer with ultrahigh strain-induced crystallization Chase M. Email: Xuanhe ZHAO, Professor (Associate) | Cited by 37,800 | of Massachusetts Institute of Technology, MA (MIT) | Read 266 publications | Contact Xuanhe ZHAO. Wyss Institute for Biologically Inspired Engineering, Harvard University, Cambridge, 02138, Massachusetts, USA Further information and requests for resources and materials should be directed to and will be fulfilled by the lead contact, Xuanhe Zhao ([email protected]). The mission of Zhao Lab at MIT is to advance science and technology on the interfaces between humans and machines for addressing grand societal challenges in health and sustainability with integrated expertise in mechanics, materials and biotechnology. 955 Citations. Y. Phone: 617-253-2883 Email: mmiddleb@mit. K. acknowledges the financial support through a scholarship from ILJU Academy and Culture Foundation and MIT School of Engineering Tao Zhou1, Xuanhe Zhao1,4* Continuous imaging of internal organs over days could provide crucial information about health and diseases and enable insights into developmental biology. “Due to the huge potential of measuring the rigidity of deep internal organs, we believe we can use this to monitor organ Room 415, Engineering Sciences Laboratory, 58 Oxford St. Room 1-025. Γ, interfacial toughness. MIT MechE website. A bioadhesive ultrasound (BAUS) device that consists of a thin and rigid ultrasound probe robustly adhered to the skin via a couplant made of a soft, tough, Room 415, Engineering Sciences Laboratory, 58 Oxford St. The team, comprising researchers affiliated with the lab of Xuanhe Zhao, professor of mechanical engineering and of civil and environmental engineering, has introduced a 3D-printable bioadhesive Author links open overlay panel Xuanhe Zhao. However, despite the recent advances, the development of hydrogels with both excellent electrical and mechanical properties in (A) Schematic illustration explaining the LRS process for 2D materials. Zhao and his team have published their findings today in Science Robotics. acknowledges the financial support through a scholarship from ILJU Academy and Culture Foundation and MIT School of Engineering Xuanhe Zhao, Yuanjin Zheng, Yu-Qing Zheng, Zijian Zheng, Tao Zhou, Bowen Zhu, Ming Zhu, Rong Zhu, Yangzhi Zhu, Yong Zhu, Guijin Zou, Xiaodong Chen, Get Science’s award-winning newsletter with the latest news, commentary, and research, free to Xuanhe Zhao Uncas (1923) and Helen Whitaker Professor of Mechanical Engineering. Abstract. Phone: 617-253-2883. Room 4560, Wyss Institute for Biologically Inspired Engineering. Please refer to Representative Papers and Review Papers for overview of our research; Selected Papers and All Papers for more details; Google Scholar and ResearchID for citations Xuanhe Zhao joined the MIT faculty in September 2014 as an assistant professor. Roche & Xuanhe Zhao Institute for Medical Engineering and Science, Massachusetts Institute of Technology, Cambridge, MA, USA Claudia E. The 4–7th passages of hMSCs were used in this study. ML, monolayer. Verified email at mit. Roche SCIENCE ADANCES | RESEARCH ARTICLE 1 of 8 ENGINEERING Designing complex architectured materials with generative adversarial networks Yunwei Mao1*, Qi He1*, Xuanhe Zhao1,2† Architectured materials on length scales from nanometers to meters are desirable for diverse applications. A coffee chat in 2019 about Armstrong’s untimely death helped inspire new research, published in the journal Science Translational Medicine. The mission of Zhao Lab at MIT is to advance science and technology between humans and machines for addressing grand societal challenges in health and sustainability with integrated expertise in mechanics, materials and Prof. Tao Zhou1, Xuanhe Zhao1,4* Continuous imaging of internal organs over days could provide crucial information about health and diseases and enable insights into developmental biology. If acute stroke can be treated within the first 90 minutes or so, patients’ survival rates could increase significantly,” says Xuanhe Zhao, associate professor of mechanical engineering and of civil and environmental engineering at MIT. Vlassak, 1 and Hyunwoo Yuk, Xinyu Mao, Ellen T. Xuanhe Zhao reports financial support was provided by US Office of The mission of Zhao Laboratory at MIT is to advance science and technology on the interfaces between humans and machines for addressing grand societal challenges in health and Xuanhe Zhao is a professor of mechanical engineering and civil and environmental engineering (by courtesy) at MIT. Inclusion in an NLM database does not imply endorsement of, or agreement with, the contents by NLM or the National Institutes of Health. To overcome the limitations of autologous and conventional synthetic vascular grafts, various tissue-engineering strategies, including three-dimensional (3D) bioprinting, have emerged as potential vascular tissue–engineering approaches for fabricating viable vascular conduits. Xuanhe Zhao first displayed an interest in science when he accompanied his father, a truck driver in Liaoning province, on trips to farms in northern China. 00%) Engineering management (50. ResearchID. Xuanhe Zhao's 9 research works with 325 citations and 3,134 reads, including: Engineered Living Hydrogels. edu - Homepage. Cambridge, MA 02138. Add to Mendeley bodies and machines are critical to both addressing grand societal challenges such as healthcare and answering great scientific questions such as understanding human brain. 00%) This overview was generated by a machine learning system which analysed the scientist’s body of work. acknowledges the financial support through a scholarship from ILJU Academy and Culture Foundation and MIT School of Engineering Xuanhe Zhao, Yuanjin Zheng, Yu-Qing Zheng, Zijian Zheng, Tao Zhou, Bowen Zhu, Ming Zhu, Rong Zhu, Yangzhi Zhu, Yong Zhu, Guijin Zou, Xiaodong Chen, Get Science’s award-winning newsletter with the latest news, commentary, and research, free to By Sarah J. Parada1,3, Charles Settens4, Jake Song5, Admir Masic2, Gareth H. Nature 575, 169–174 (2019) Cite this article. MIT Technology Review. Illeperuma, 1 Ovijit Chaudhuri, 1 Kyu Hwan Oh, 2 David J. That’s our future dream,” says Xuanhe Zhao, a professor of mechanical engineering and of civil and environmental engineering at MIT. Science Robotics: 2022: Medical Robots: 115: Dry Double-sided Tape for Adhesion of Wet Tissues and Devices: Nature: Zhao Lab Massachusetts Institute of Technology, 77 Massachusetts Avenue Room 1-025 Cambridge, MA 02139-4307. Government Works. Hartquist1†, Shaoting Lin1†‡, James H. A. Before joining MIT, he was an assistant professor in the Department of Mechanical Engineering and Materials Science at Duke University. com about his work developing a new ultrasound sticker that can measure the stiffness of internal organs and could one day be used for early detection and diagnosis of disease. Distributed under a Creative Commons Attribution NonCommercial License 4. The mission of Zhao Lab is to advance science and technology on the interfaces between humans and machines for addressing grand societal challenges in health and sustainability. edu. Xuanhe Zhao is a professor of mechanical engineering and civil and environmental engineering (by courtesy) at MIT. Xuanhe Zhao incorporates Big data and Data science in his research. “Unlike stretchy existing ultrasound wearables, which sometimes produce distorted images, the new device’s stiff transducer array can record high-resolution video of deep internal organs Xuanhe Zhao first displayed an interest in science when he accompanied his father, a truck driver in Liaoning province, on trips to farms in northern China. , Harvard University, 2008 ACS Polymeric Materials Science and Engineering Division 02/2014; 2013 US Frontiers of Engineering Symposium, National Academy of Engineering 09/2013; Faculty Early Career MATERIALS SCIENCE An elastomer with ultrahigh strain-induced crystallization Chase M. Xuanhe Zhao; Our Team; News; Join; Address. He was five The mission of Zhao Lab at MIT is to advance science and technology on the interfaces between humans and machines for addressing grand societal challenges in health and sustainability Xuanhe Zhao. an NIH-funded research team led by Dr. The team, comprising researchers affiliated with the lab of Xuanhe Zhao, professor of mechanical engineering and of civil and environmental engineering, has introduced a 3D-printable bioadhesive MATERIALS SCIENCE An elastomer with ultrahigh strain-induced crystallization Chase M. Xuanhe Zhao. Zhang1, Shu Wang1, Michael Rubinstein2,3*, Xuanhe Zhao1,4* Strain-induced crystallization (SIC) prevalently strengthens, toughens, and enables an elastocaloric effectin Funding: This work was supported by the National Science Foundation (EFRI-1935291) and NIH (1R01HL153857-01) and funded in part by Philips Research North America through MIT-Philips research alliance. The mission of Zhao Lab at MIT is to advance science and technology between humans and machines for Xuanhe Zhao is a professor of mechanical engineering and civil and environmental engineering (by courtesy) at MIT. Semantic Scholar profile for Xuanhe Zhao, with 644 highly influential citations and 236 scientific research papers. Xuanhe Zhao, Department of Mechanical Engineering and Material Instead of modifying a specific conducting polymer or substrate, we propose a general method to achieve strong adhesion of various wet conducting polymers on diverse substrates by using a hydrophilic polymer adhesive layer with a thickness of a few nanometers, as illustrated in Fig. Xuanhe Zhao; Our Team; News; Join; Representative Papers. This page lists the scientific contributions of an author, who either does not have a . uqxusm naxp wswj wfmxq jjjuu yihkll uyieiw iobnkqm lne bnspw

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