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Hurry Up and Get Out of the Way! Exploring the Limits of Muscle-Based Latch Systems for Power Amplification
Animals can amplify the mechanical power output of their muscles as they jump to escape predators or strike to capture prey. One mechanism for amplification involves muscle–tendon unit (MT) systems in which a spring element (series elastic element [SEE]) is pre-stretched while held in place by a “la...
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| Published in: | Integrative and comparative biology 2019-12, Vol.59 (6), p.1546-1558 |
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| creator | Abbott, Emily M. Nezwek, Teron Schmitt, Daniel Sawicki, Gregory S. |
| description | Animals can amplify the mechanical power output of their muscles as they jump to escape predators or strike to capture prey. One mechanism for amplification involves muscle–tendon unit (MT) systems in which a spring element (series elastic element [SEE]) is pre-stretched while held in place by a “latch” that prevents immediate transmission of muscle (or contractile element, CE) power to the load. In principle, this storage phase is followed by a triggered release of the latch, and elastic energy released from the SEE enables power amplification (P
RATIO = P
LOAD/P
CE,max >1.0), whereby the peak power delivered from MT to the load exceeds the maximum power limit of the CE in isolation. Latches enable power amplification by increasing the muscle work generated during storage and reducing the duration over which that stored energy is released to power a movement. Previously described biological “latches” include: skeletal levers, anatomical triggers, accessory appendages, and even antagonist muscles. In fact, many species that rely on high-powered movements also have a large number of muscles arranged in antagonist pairs. Here, we examine whether a decaying antagonist force (e.g., from a muscle) could be useful as an active latch to achieve controlled energy transmission and modulate peak output power. We developed a computer model of a frog hindlimb driven by a compliant MT. We simulated MT power generated against an inertial load in the presence of an antagonist force “latch” (AFL) with relaxation time varying from very fast (10 ms) to very slow (1000 ms) to mirror physiological ranges of antagonist muscle. The fastest AFL produced power amplification (P
RATIO = 5.0) while the slowest AFL produced power attenuation (P
RATIO = 0.43). Notably, AFLs with relaxation times shorter than ∼300 ms also yielded greater power amplification (P
RATIO>1.20) than the system driving the same inertial load using only an agonist MT without any AFL. Thus, animals that utilize a sufficiently fast relaxing AFL ought to be capable of achieving greater power output than systems confined to a single agonist MT tuned for maximum P
RATIO against the same load. |
| doi_str_mv | 10.1093/icb/icz141 |
| format | article |
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RATIO = P
LOAD/P
CE,max >1.0), whereby the peak power delivered from MT to the load exceeds the maximum power limit of the CE in isolation. Latches enable power amplification by increasing the muscle work generated during storage and reducing the duration over which that stored energy is released to power a movement. Previously described biological “latches” include: skeletal levers, anatomical triggers, accessory appendages, and even antagonist muscles. In fact, many species that rely on high-powered movements also have a large number of muscles arranged in antagonist pairs. Here, we examine whether a decaying antagonist force (e.g., from a muscle) could be useful as an active latch to achieve controlled energy transmission and modulate peak output power. We developed a computer model of a frog hindlimb driven by a compliant MT. We simulated MT power generated against an inertial load in the presence of an antagonist force “latch” (AFL) with relaxation time varying from very fast (10 ms) to very slow (1000 ms) to mirror physiological ranges of antagonist muscle. The fastest AFL produced power amplification (P
RATIO = 5.0) while the slowest AFL produced power attenuation (P
RATIO = 0.43). Notably, AFLs with relaxation times shorter than ∼300 ms also yielded greater power amplification (P
RATIO>1.20) than the system driving the same inertial load using only an agonist MT without any AFL. Thus, animals that utilize a sufficiently fast relaxing AFL ought to be capable of achieving greater power output than systems confined to a single agonist MT tuned for maximum P
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RATIO = P
LOAD/P
CE,max >1.0), whereby the peak power delivered from MT to the load exceeds the maximum power limit of the CE in isolation. Latches enable power amplification by increasing the muscle work generated during storage and reducing the duration over which that stored energy is released to power a movement. Previously described biological “latches” include: skeletal levers, anatomical triggers, accessory appendages, and even antagonist muscles. In fact, many species that rely on high-powered movements also have a large number of muscles arranged in antagonist pairs. Here, we examine whether a decaying antagonist force (e.g., from a muscle) could be useful as an active latch to achieve controlled energy transmission and modulate peak output power. We developed a computer model of a frog hindlimb driven by a compliant MT. We simulated MT power generated against an inertial load in the presence of an antagonist force “latch” (AFL) with relaxation time varying from very fast (10 ms) to very slow (1000 ms) to mirror physiological ranges of antagonist muscle. The fastest AFL produced power amplification (P
RATIO = 5.0) while the slowest AFL produced power attenuation (P
RATIO = 0.43). Notably, AFLs with relaxation times shorter than ∼300 ms also yielded greater power amplification (P
RATIO>1.20) than the system driving the same inertial load using only an agonist MT without any AFL. Thus, animals that utilize a sufficiently fast relaxing AFL ought to be capable of achieving greater power output than systems confined to a single agonist MT tuned for maximum P
RATIO against the same load.</description><subject>Animals</subject><subject>Anura - physiology</subject><subject>Biomechanical Phenomena</subject><subject>Hindlimb - physiology</subject><subject>Models, Biological</subject><subject>Movement - physiology</subject><subject>Muscle Contraction</subject><subject>Muscle, Skeletal - physiology</subject><subject>S3 Playing with Power: Mechanisms of Energy Flow in Organismal Movement</subject><subject>Tendons - physiology</subject><issn>1540-7063</issn><issn>1557-7023</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2019</creationdate><recordtype>article</recordtype><recordid>eNp90M0vBDEYBvBGiI_l4k7qIBHJ0K-Zdo4IS7JCgjhOOt2WMrMdbSesv17X4OjQ9M3bX5_DA8A2RkcYlfTYqjqdT8zwEljHec4zjghdXswMpbmga2AjhBeE0iPCq2CNJiu4YOvg9bL3fg4fOihnUzjWEd70EToD47OGj3K-B88_usZ5O3v6Xk1sa2NYgOs-qEZnpzLoKZzIqJ7h3TxE3QZonIe37l17eNJ2jTVWyWjdbBOsGNkEvfVzj8DDxfn92WU2uRlfnZ1MMkV5HrNSKF0zJQxiNZPcTDExrKwFlybnhCFJy1IwUhuCMCFCoFypuqiFYTR9pIKOwMGQ23n31usQq9YGpZtGzrTrQ0UIz0mR45wkejhQ5V0IXpuq87aVfl5hVC3KrVK51VBuwrs_uX3d6ukf_W0zgf0BuL77P2hncC8hOv8nSSEKzktOvwCvIotK</recordid><startdate>20191201</startdate><enddate>20191201</enddate><creator>Abbott, Emily M.</creator><creator>Nezwek, Teron</creator><creator>Schmitt, Daniel</creator><creator>Sawicki, Gregory S.</creator><general>Oxford University Press</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope></search><sort><creationdate>20191201</creationdate><title>Hurry Up and Get Out of the Way! Exploring the Limits of Muscle-Based Latch Systems for Power Amplification</title><author>Abbott, Emily M. ; Nezwek, Teron ; Schmitt, Daniel ; Sawicki, Gregory S.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c375t-98ceb4c8f04b4a7fd12f49b87af57240a399842bf201228805ccb6b8f43ceb383</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2019</creationdate><topic>Animals</topic><topic>Anura - physiology</topic><topic>Biomechanical Phenomena</topic><topic>Hindlimb - physiology</topic><topic>Models, Biological</topic><topic>Movement - physiology</topic><topic>Muscle Contraction</topic><topic>Muscle, Skeletal - physiology</topic><topic>S3 Playing with Power: Mechanisms of Energy Flow in Organismal Movement</topic><topic>Tendons - physiology</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Abbott, Emily M.</creatorcontrib><creatorcontrib>Nezwek, Teron</creatorcontrib><creatorcontrib>Schmitt, Daniel</creatorcontrib><creatorcontrib>Sawicki, Gregory S.</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><jtitle>Integrative and comparative biology</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Abbott, Emily M.</au><au>Nezwek, Teron</au><au>Schmitt, Daniel</au><au>Sawicki, Gregory S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Hurry Up and Get Out of the Way! Exploring the Limits of Muscle-Based Latch Systems for Power Amplification</atitle><jtitle>Integrative and comparative biology</jtitle><addtitle>Integr Comp Biol</addtitle><date>2019-12-01</date><risdate>2019</risdate><volume>59</volume><issue>6</issue><spage>1546</spage><epage>1558</epage><pages>1546-1558</pages><issn>1540-7063</issn><eissn>1557-7023</eissn><abstract>Animals can amplify the mechanical power output of their muscles as they jump to escape predators or strike to capture prey. One mechanism for amplification involves muscle–tendon unit (MT) systems in which a spring element (series elastic element [SEE]) is pre-stretched while held in place by a “latch” that prevents immediate transmission of muscle (or contractile element, CE) power to the load. In principle, this storage phase is followed by a triggered release of the latch, and elastic energy released from the SEE enables power amplification (P
RATIO = P
LOAD/P
CE,max >1.0), whereby the peak power delivered from MT to the load exceeds the maximum power limit of the CE in isolation. Latches enable power amplification by increasing the muscle work generated during storage and reducing the duration over which that stored energy is released to power a movement. Previously described biological “latches” include: skeletal levers, anatomical triggers, accessory appendages, and even antagonist muscles. In fact, many species that rely on high-powered movements also have a large number of muscles arranged in antagonist pairs. Here, we examine whether a decaying antagonist force (e.g., from a muscle) could be useful as an active latch to achieve controlled energy transmission and modulate peak output power. We developed a computer model of a frog hindlimb driven by a compliant MT. We simulated MT power generated against an inertial load in the presence of an antagonist force “latch” (AFL) with relaxation time varying from very fast (10 ms) to very slow (1000 ms) to mirror physiological ranges of antagonist muscle. The fastest AFL produced power amplification (P
RATIO = 5.0) while the slowest AFL produced power attenuation (P
RATIO = 0.43). Notably, AFLs with relaxation times shorter than ∼300 ms also yielded greater power amplification (P
RATIO>1.20) than the system driving the same inertial load using only an agonist MT without any AFL. Thus, animals that utilize a sufficiently fast relaxing AFL ought to be capable of achieving greater power output than systems confined to a single agonist MT tuned for maximum P
RATIO against the same load.</abstract><cop>England</cop><pub>Oxford University Press</pub><pmid>31418784</pmid><doi>10.1093/icb/icz141</doi><tpages>13</tpages><oa>free_for_read</oa></addata></record> |
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| ispartof | Integrative and comparative biology, 2019-12, Vol.59 (6), p.1546-1558 |
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| language | eng |
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| source | Oxford Journals Online |
| subjects | Animals Anura - physiology Biomechanical Phenomena Hindlimb - physiology Models, Biological Movement - physiology Muscle Contraction Muscle, Skeletal - physiology S3 Playing with Power: Mechanisms of Energy Flow in Organismal Movement Tendons - physiology |
| title | Hurry Up and Get Out of the Way! Exploring the Limits of Muscle-Based Latch Systems for Power Amplification |
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