The Experts below are selected from a list of 4401 Experts worldwide ranked by ideXlab platform
David Drake - One of the best experts on this subject based on the ideXlab platform.
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the use of Microtechnology to monitor collision performance in professional rugby union
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P < .001; effect size [ES] = 0.53 and 0.80, respectively), tackles (P < .0001; ES = 0.60 and 0.56, respectively), and carries (P < .001; ES = 0.48 and 0.79, respectiv...
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The Use of Microtechnology to Monitor Collision Performance in Professional Rugby Union.
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P
Simon Macleod - One of the best experts on this subject based on the ideXlab platform.
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the use of Microtechnology to monitor collision performance in professional rugby union
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P < .001; effect size [ES] = 0.53 and 0.80, respectively), tackles (P < .0001; ES = 0.60 and 0.56, respectively), and carries (P < .001; ES = 0.48 and 0.79, respectiv...
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The Use of Microtechnology to Monitor Collision Performance in Professional Rugby Union.
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P
Joong Yull Park - One of the best experts on this subject based on the ideXlab platform.
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regulating microenvironmental stimuli for stem cells and cancer cells using microsystems
Integrative Biology, 2010Co-Authors: Joong Yull Park, Shuichi TakayamaAbstract:Cells express hundreds of different types of receptors, which they use to continuously monitor their chemical and mechanical microenvironments. Stem cells and cancer cells are particularly sensitive to microenvironmental cues because their interactions have profound effects on stem cell potency and tumorigenesis, respectively. Unlike conventional tissue culture in wells and dishes, Microtechnology with dimensions on the cellular scale can be combined with materials, chemicals, physiological flows, and other effectors to provide high levels of control in a format more flexible than macroscale in vitro or in vivo systems, revealing stimulation-specific responses of stem cells and cancer cells. Microtechnology-integrated biology enable the simultaneous control of multiple numbers of biological microenvironmental factors in a high-throughput manner. In this review we present representative examples of the use of Microtechnology systems to regulate the mechanical, chemical, topological, adhesive, and other environments of individual stem cells and cancer cells. We then explore the possibilities for simultaneous multimodal control of combinations of these environmental factors.
Chris Hagan - One of the best experts on this subject based on the ideXlab platform.
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the use of Microtechnology to monitor collision performance in professional rugby union
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P < .001; effect size [ES] = 0.53 and 0.80, respectively), tackles (P < .0001; ES = 0.60 and 0.56, respectively), and carries (P < .001; ES = 0.48 and 0.79, respectiv...
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The Use of Microtechnology to Monitor Collision Performance in Professional Rugby Union.
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P
Mikel Egaña - One of the best experts on this subject based on the ideXlab platform.
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the use of Microtechnology to monitor collision performance in professional rugby union
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P < .001; effect size [ES] = 0.53 and 0.80, respectively), tackles (P < .0001; ES = 0.60 and 0.56, respectively), and carries (P < .001; ES = 0.48 and 0.79, respectiv...
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The Use of Microtechnology to Monitor Collision Performance in Professional Rugby Union.
International Journal of Sports Physiology and Performance, 2018Co-Authors: Simon Macleod, Chris Hagan, Mikel Egaña, Jonny Davis, David DrakeAbstract:Purpose: To determine if Microtechnology-derived collision loads discriminate between collision performance and compare the physical and analytical components of collision performance between positional groups. Methods: Thirty-seven professional male rugby union players participated in this study. Collision events from 11 competitive matches were coded using specific tackle and carry classifications based on the ball-carrier’s collision outcome. Collisions were automatically detected using 10 Hz Microtechnology units. Collision events were identified, coded (as tackle or carry), and timestamped at the collision contact point using game analysis software. Attacking and defensive performances of 1609 collision events were analyzed. Results: Collision loads were significantly greater during dominant compared with neutral and passive collisions (P
