Mobility, motion, and exercise

IF 5.6 2区 医学 Q1 PHYSIOLOGY
Pontus B. Persson, Anja Bondke Persson
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Importantly, humans can convey complex information through speech, while animals must often also move their bodies to communicate. This is highly relevant for animal models with respect to translational physiology and has inspired numerous creative solutions by bioscientists to enable the study of, for example, the brain during movement.<span><sup>3</sup></span> Translational biomedical research—still so, and across disciplines—relies on animal models.<span><sup>4, 5</sup></span> When cognitive processes are studied, free movement is, despite the additional challenge of controlling or monitoring sensory input in a mobile subject, a prerequisite, as, for example, crucial behavioral patterns can only be observed and studied during free movement.<span><sup>3</sup></span> Nevertheless, telemetry-based studies in freely moving animals are extremely valuable for many more areas of application in physiology, for example in cardiovascular research,<span><sup>6</sup></span> studies of vegetative function and cardiovascular reflex responses<span><sup>7</sup></span> or renal function.<span><sup>8</sup></span> This is exemplified in recent studies: Wu et al. show the relevance of VIP+ miRNAs in sensory processing, olfactory neural activity, and “successful” olfactory function in rodents.<span><sup>9</sup></span> Toledo et al<span><sup>10</sup></span> did not primarily observe behavioral changes; however, the modulating effects of RVLM-C1 neurons on cardiorespiratory function at rest had never before studied in conscious, adult animals able to move freely, which adds great relevance to their results. As Pilowsky remarks, one crucial advantage of this study in awake animals, with reflexes intact, is the possibility to study changes in the sleep–wake cycle and normal breathing patterns, while, however, the effects of reflexes on the phenomena observed confounds the results and need to be taken into account critically.<span><sup>11</sup></span> Baseline heart rate recordings at rest in freely moving animals<span><sup>12</sup></span> are of particular value from a translational perspective, as they more closely resemble the natural situation.</p><p>At the cellular level, movement occurs during cell division, intracellular transport, and the functioning of immune cells. Movement is also integral to growth, such as phototropism and gravitropism, whereby plants grow toward light and/or against gravity to optimize their conditions for photosynthesis and stability. Both growing and mature organisms respond to environmental stimuli: Tropisms in plants and taxis in microorganisms are examples of how movement helps adapt to environmental conditions. Organisms do not only move for homeostasis and survival, but also for reproductive processes: Sperms move toward the egg for fertilization in many animals, and pollen movement via wind, water, or pollinators is crucial for plant reproduction. Movement can thus be seen as a defining characteristic of living organisms that supports essential functions such as feeding, growth, reproduction, and adaptation to the environment.</p><p>When we study movement, there is a multitude of technical terms being used. Most of them share the Latin root “movēre,” which highlights their common origin related to the concept of moving or being in motion. These different terms warrant a closer look to avoid unwanted ambiguity, especially since database search engines, which rely on automatically generated thesauri for efficiency and speed, unfortunately automatically and often incorrectly synonymize these terms.</p><p><i>Momentum</i> is a fundamental concept in physics: It quantitatively describes the motion an object possesses. It is thus a vector quantity with both a magnitude and direction. In a closed system with no external forces, the total momentum remains constant, which is crucial in analyzing collisions and interactions between objects. In a simplistic view, momentum is a measure of how much motion an object has and how difficult it would be to stop or change its motion. Momentum is also fundamental concept for applied human physiology: It aids, for example, the study of movement mechanics, performance enhancement, and is needed during the design process of, for example, rehabilitation and ergonomic solutions. Studying the momentum of limbs during walking or running helps in understanding the efficiency and mechanics of gait, balance, and stability. In exercise or sports physiology, momentum is vital for optimizing performance and preventing injuries when, for example, throwing a ball—properly managing and transferring momentum can lead to more effective and powerful movements. Also, understanding momentum is important in designing rehabilitation protocols and prosthetic devices to replicate the momentum of natural limbs, to help achieve smooth and efficient movement for the user. In ergonomics, momentum helps in designing tools and workspaces that minimize the risk of injury, reduce strain, and improve efficiency.</p><p>The distinction between <i>movement</i> and <i>motion</i> is essential in physiological studies of non-sedentary life. While motion is the mere change in position of an organism or object, dictated by physical laws, movement involves an intentional and coordinated action, usually driven by an organism's nervous and muscular systems. The terms motion, movement, mobility, and motility, while related, have distinct meanings. While motion refers to the change in position of both animate or inanimate objects,<span><sup>13</sup></span> movement implies purposeful and coordinated behavior, intention and control, typically involving a musculoskeletal system.<span><sup>14</sup></span> <i>Mobility</i> and <i>motility</i>, on the other hand, refer to capacities:</p><p>Mobility describes the ability of an organism or a part of an organism to either move or be moved freely and easily, thus, an overall capacity for movement—the range of motion and flexibility of joints, limbs, or the whole organism. Mobility can include passive movements (e.g., being moved by external forces) and refer to the overall ease of movement.</p><p>Motility usually refers to the ability of an organism or cell to move spontaneously and actively, consuming energy in the process—sperm cells swimming toward an egg, the movement of white blood cells toward a site of engagement,<span><sup>15</sup></span> or the contractions of the gastrointestinal tract.<span><sup>16</sup></span> This term is more focused on self-propelled movement, often (but not only: Delbono et al. use the term “motility” to refer to skeletal muscle innervation,<span><sup>17</sup></span> which Fan et. al refer to as movement<span><sup>18</sup></span>) at the cellular or microbial level for active, energy-consuming processes.<span><sup>19-21</sup></span></p><p>When we look at the movement of individuals in groups or “swarms,” this adds another layer of complexity, when organisms adapt and synchronize their movements to form cohesive groups. Swarming and coordinated movement require communication and interaction of individual entities. Visual, auditory, chemical, or tactile signals help coordinate movements and maintain group cohesion. “Social” interactions in swarms or moving groups, such as aligning with neighbors or following a leader, can fine-tune more sophisticated group behaviors. Common general mechanisms of coordination include adjustment in direction to align with neighbors, attraction toward the center of the group to maintain cohesion, and repulsion to help individuals maintain a certain distance to, for example, avoid collisions. Benefits of swarming include predator avoidance or confusion and safe and efficient foraging and long-distance migration, seen in insects, birds, fish, and mammals alike. Understanding swarming and coordinated movement in groups does not only provide insights into the underlying principles of collective behavior, but may also have novel applications in fields ranging from robotics and artificial intelligence to crowd management and environmental conservation.</p><p>None.</p><p>None.</p><p>None.</p>","PeriodicalId":107,"journal":{"name":"Acta Physiologica","volume":"240 11","pages":""},"PeriodicalIF":5.6000,"publicationDate":"2024-07-31","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/apha.14210","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Acta Physiologica","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/apha.14210","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"PHYSIOLOGY","Score":null,"Total":0}
引用次数: 0

Abstract

Sir Isaac Newton's 1686 “Philosophiae Naturalis Principia Mathematica”1 has repeatedly, and notably by biomedical scientists, been cited as the most influential single piece of scientific writing ever produced2: Movement, the laws pertaining to which are laid down in this work, is a fundamental characteristic of life, and as such, essential for various biological functions. Thus, life scientists across disciplines study processes that involve changes in location, from a molecular level to that of groups of complex organisms.

Most complex organisms move from one place to another—in search for nutrition, new habitats, mates or to escape predators. Importantly, humans can convey complex information through speech, while animals must often also move their bodies to communicate. This is highly relevant for animal models with respect to translational physiology and has inspired numerous creative solutions by bioscientists to enable the study of, for example, the brain during movement.3 Translational biomedical research—still so, and across disciplines—relies on animal models.4, 5 When cognitive processes are studied, free movement is, despite the additional challenge of controlling or monitoring sensory input in a mobile subject, a prerequisite, as, for example, crucial behavioral patterns can only be observed and studied during free movement.3 Nevertheless, telemetry-based studies in freely moving animals are extremely valuable for many more areas of application in physiology, for example in cardiovascular research,6 studies of vegetative function and cardiovascular reflex responses7 or renal function.8 This is exemplified in recent studies: Wu et al. show the relevance of VIP+ miRNAs in sensory processing, olfactory neural activity, and “successful” olfactory function in rodents.9 Toledo et al10 did not primarily observe behavioral changes; however, the modulating effects of RVLM-C1 neurons on cardiorespiratory function at rest had never before studied in conscious, adult animals able to move freely, which adds great relevance to their results. As Pilowsky remarks, one crucial advantage of this study in awake animals, with reflexes intact, is the possibility to study changes in the sleep–wake cycle and normal breathing patterns, while, however, the effects of reflexes on the phenomena observed confounds the results and need to be taken into account critically.11 Baseline heart rate recordings at rest in freely moving animals12 are of particular value from a translational perspective, as they more closely resemble the natural situation.

At the cellular level, movement occurs during cell division, intracellular transport, and the functioning of immune cells. Movement is also integral to growth, such as phototropism and gravitropism, whereby plants grow toward light and/or against gravity to optimize their conditions for photosynthesis and stability. Both growing and mature organisms respond to environmental stimuli: Tropisms in plants and taxis in microorganisms are examples of how movement helps adapt to environmental conditions. Organisms do not only move for homeostasis and survival, but also for reproductive processes: Sperms move toward the egg for fertilization in many animals, and pollen movement via wind, water, or pollinators is crucial for plant reproduction. Movement can thus be seen as a defining characteristic of living organisms that supports essential functions such as feeding, growth, reproduction, and adaptation to the environment.

When we study movement, there is a multitude of technical terms being used. Most of them share the Latin root “movēre,” which highlights their common origin related to the concept of moving or being in motion. These different terms warrant a closer look to avoid unwanted ambiguity, especially since database search engines, which rely on automatically generated thesauri for efficiency and speed, unfortunately automatically and often incorrectly synonymize these terms.

Momentum is a fundamental concept in physics: It quantitatively describes the motion an object possesses. It is thus a vector quantity with both a magnitude and direction. In a closed system with no external forces, the total momentum remains constant, which is crucial in analyzing collisions and interactions between objects. In a simplistic view, momentum is a measure of how much motion an object has and how difficult it would be to stop or change its motion. Momentum is also fundamental concept for applied human physiology: It aids, for example, the study of movement mechanics, performance enhancement, and is needed during the design process of, for example, rehabilitation and ergonomic solutions. Studying the momentum of limbs during walking or running helps in understanding the efficiency and mechanics of gait, balance, and stability. In exercise or sports physiology, momentum is vital for optimizing performance and preventing injuries when, for example, throwing a ball—properly managing and transferring momentum can lead to more effective and powerful movements. Also, understanding momentum is important in designing rehabilitation protocols and prosthetic devices to replicate the momentum of natural limbs, to help achieve smooth and efficient movement for the user. In ergonomics, momentum helps in designing tools and workspaces that minimize the risk of injury, reduce strain, and improve efficiency.

The distinction between movement and motion is essential in physiological studies of non-sedentary life. While motion is the mere change in position of an organism or object, dictated by physical laws, movement involves an intentional and coordinated action, usually driven by an organism's nervous and muscular systems. The terms motion, movement, mobility, and motility, while related, have distinct meanings. While motion refers to the change in position of both animate or inanimate objects,13 movement implies purposeful and coordinated behavior, intention and control, typically involving a musculoskeletal system.14 Mobility and motility, on the other hand, refer to capacities:

Mobility describes the ability of an organism or a part of an organism to either move or be moved freely and easily, thus, an overall capacity for movement—the range of motion and flexibility of joints, limbs, or the whole organism. Mobility can include passive movements (e.g., being moved by external forces) and refer to the overall ease of movement.

Motility usually refers to the ability of an organism or cell to move spontaneously and actively, consuming energy in the process—sperm cells swimming toward an egg, the movement of white blood cells toward a site of engagement,15 or the contractions of the gastrointestinal tract.16 This term is more focused on self-propelled movement, often (but not only: Delbono et al. use the term “motility” to refer to skeletal muscle innervation,17 which Fan et. al refer to as movement18) at the cellular or microbial level for active, energy-consuming processes.19-21

When we look at the movement of individuals in groups or “swarms,” this adds another layer of complexity, when organisms adapt and synchronize their movements to form cohesive groups. Swarming and coordinated movement require communication and interaction of individual entities. Visual, auditory, chemical, or tactile signals help coordinate movements and maintain group cohesion. “Social” interactions in swarms or moving groups, such as aligning with neighbors or following a leader, can fine-tune more sophisticated group behaviors. Common general mechanisms of coordination include adjustment in direction to align with neighbors, attraction toward the center of the group to maintain cohesion, and repulsion to help individuals maintain a certain distance to, for example, avoid collisions. Benefits of swarming include predator avoidance or confusion and safe and efficient foraging and long-distance migration, seen in insects, birds, fish, and mammals alike. Understanding swarming and coordinated movement in groups does not only provide insights into the underlying principles of collective behavior, but may also have novel applications in fields ranging from robotics and artificial intelligence to crowd management and environmental conservation.

None.

None.

None.

移动、运动和锻炼。
在运动或体育生理学中,动量对于优化运动表现和防止受伤至关重要,例如在投掷球类运动中--适当地管理和传递动量可以使运动更有效、更有力。此外,了解动量对于设计康复方案和假肢装置也很重要,这些方案和装置可以复制自然肢体的动量,帮助使用者实现流畅高效的运动。在人体工程学中,动量有助于设计工具和工作空间,从而最大限度地降低受伤风险、减少劳损并提高效率。运动是指生物体或物体在物理规律支配下位置的单纯变化,而移动则涉及有意的协调动作,通常由生物体的神经和肌肉系统驱动。运动、移动、机动性和运动性这些术语虽然相互关联,但却有着不同的含义。运动指的是有生命或无生命物体的位置变化,13 而移动则意味着有目的和协调的行为、意图和控制,通常涉及肌肉骨骼系统。14 另一方面,移动性和运动性指的是能力:移动性描述的是生物体或生物体一部分自由轻松地移动或被移动的能力,因此是一种整体的移动能力--关节、肢体或整个生物体的运动范围和灵活性。运动能力通常指生物体或细胞自发主动运动的能力,在此过程中消耗能量--精细胞游向卵子,白细胞向交战部位运动,15 或胃肠道收缩:16 这一术语更侧重于自我推动的运动,通常(但不仅限于:Delbono 等人使用 "运动 "一词来指骨骼肌神经支配,17 Fan 等人将其称为运动18)是在细胞或微生物水平上的主动耗能过程19-21。当我们研究个体在群体或 "蜂群 "中的运动时,这又增加了一层复杂性,因为此时生物会调整并同步运动,以形成有凝聚力的群体。蜂群和协调运动需要个体间的交流和互动。视觉、听觉、化学或触觉信号有助于协调运动和保持群体凝聚力。蜂群或移动群体中的 "社会 "互动,如与邻居结盟或追随领导者,可以微调更复杂的群体行为。常见的一般协调机制包括调整方向以与邻居保持一致,向群体中心吸引以保持凝聚力,以及排斥以帮助个体保持一定距离,例如避免碰撞。蜂群的好处包括避免或混淆捕食者,安全高效地觅食和长途迁徙,这在昆虫、鸟类、鱼类和哺乳动物身上都能看到。了解蜂群和群体中的协调运动不仅可以深入了解集体行为的基本原理,还可能在机器人和人工智能、人群管理和环境保护等领域产生新的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Acta Physiologica
Acta Physiologica 医学-生理学
CiteScore
11.80
自引率
15.90%
发文量
182
审稿时长
4-8 weeks
期刊介绍: Acta Physiologica is an important forum for the publication of high quality original research in physiology and related areas by authors from all over the world. Acta Physiologica is a leading journal in human/translational physiology while promoting all aspects of the science of physiology. The journal publishes full length original articles on important new observations as well as reviews and commentaries.
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