Muscle spindle morphology in the tenuissimus muscle of the golden syrian hamster

Patten, Robert Michael

January 1990

The tenuissimus is a long, thin hindlimb skeletal muscle which in hamsters contains about 200 extrafusal muscle fibers. Embedded in this richly innervated muscle is a continuous array of 16-20 closely packed muscle spindles suggesting that it may play a role in hindlimb proprioception. This high spindle density also makes the muscle ideal for the isolation and harvesting of these sensory receptors. In this correlative light and electron microscopic study, freshly frozen specimens were first prepared for serial microscopic analysis. Camera lucida reconstruction of spindle distribution showed a close proximity to the main artery and nerve in the central core of the muscle. Oxidative enzyme and myosin ATPase staining profiles were examined in both the intrafusal and extrafusal fiber populations. Type I and type II extrafusal fibers were present in even numbers and were distributed evenly throughout muscle cross-sections. Enzyme staining varied along the lengths of the three intrafusal fiber types. The fine structure of spindles was examined using transmission (TEM), conventional scanning (SEM), and high resolution scanning electron microscopy (HRSEM). For conventional SEM, isolated spindles were first fixed in 2.5% buffered glutaraldehyde, followed by 1% osmication, and mechanical disruption of the outer capsule under the dissecting microscope. Preparation for HRSEM included aldehyde/osmium fixation and freeze-cleavage of entire tenuissimus muscles in liquid N₂. Selective extraction of the cytosol with 0.1% OsO4 permitted the visualization of numerous intracellular structures. In these specimens, the capsular sleeve showed a multilayered pattern of vesicle-laden cells with variant surface topography in certain locations. Punctate sensory nerve endings adhered intimately to the surfaces of underlying intrafusal fibers in the equatorial and juxtaequatorial regions. By TEM and HRSEM these endings appeared crescent-shaped and were enveloped by external laminae. Each profile contained a plethora of mitochondria and cytoskeletal organelles. The methodology used in this study provides, for the first time, a three-dimensional view of the exquisite cytological architecture of this neuromuscular receptor. / Medicine, Faculty of / Graduate

Neuromuscular spindles

Hamsters -- Physiology

Cricetinae -- physiology

Muscle Spindles

Efeitos de diferentes freqüências e amplitudes de vibração unilateral do tendão calcâneo na orientação postural e no reflexo H em humanos / Effects of Achilles tendon vibration of different frequencies and amplitudes on postural orientation and H reflex in humans

Pedão, Sabrina Tiago

30 March 2010

Uma vibração aplicada a um tendão muscular aumenta a freqüência de disparos de aferentes, como os de fusos neuromusculares Ia e II, cujas terminações afetam circuitos da medula espinhal e com isto podem influenciar o controle motor. O objetivo deste estudo foi analisar o efeito de vibrações a duas freqüências (15 e 80Hz) e amplitudes de 1 e 2,5mm aplicadas ao tendão calcâneo direito sobre o sistema de controle postural e sobre a circuitaria neural associada a reflexos monosinápticos da perna. A hipótese era de que a vibração de alta freqüência ativasse preferencialmente os aferentes de fuso neuromuscular de tipo Ia enquanto a vibração a 15 Hz ativasse preferencialmente os aferentes de tipo II. Isto significaria que a vibração a 80 Hz teria forte efeito sobre o reflexo H, enquanto a vibração a 15 Hz teria um efeito significativo sobre a postura. Participaram deste estudo 14 sujeitos sãos. Na postura ereta quieta, foi realizada a aquisição do reflexo H enquanto o tendão calcâneo era vibrado. Após um intervalo de descanso, foi realizada a aquisição do Centro de Pressão (COP) tanto na direção Ântero-Posterior (AP) quanto na Médio-Lateral (ML) em paralelo à aquisição bilateral do EMG dos músculos (SO, TA, GL e GM) nas três condições (antes, durante e após a vibração do tendão calcâneo). Para os estímulos de 1 e 2,5mm realizados a 80 Hz as diferenças foram significativas em relação a todas as variáveis quando comparadas nas três condições, com exceção apenas do DP do TA e GM e, do valor médio do COP ML a 1mm. Em relação à freqüência de 15 Hz, notou-se que não houve diferenças significativas tanto no COP AP e ML quanto no DP do EMG dos músculos da perna esquerda entre as três condições. Quanto aos dados referentes ao DP dos músculos analisados na perna direita, os resultados mostraram que não houve efeitos significativos tanto ao utilizar 15Hz como 80Hz em todas as três condições. Em geral, estes dados mostraram que durante um estímulo vibratório mais forte o COP deslocouse mais para a direção posterior e lateral esquerda do sujeito. E, após interromper o estímulo, em alguns casos o COP ainda mostrava uma alteração prolongada. Em relação à amplitude média do reflexo H, para as amplitudes de vibração de 1 e 2,5 mm a 15 e 80 Hz, as análises apontaram que durante a vibração houve uma forte redução na amplitude do reflexo, sendo que em alguns casos ainda permaneceram reduzidas na condição pós-vibratória. Os resultados mostram que a vibração aplicada ao tendão calcâneo pode ser um forte estímulo à medula e capaz de alterar o controle postural, dependendo de suas características, uma vez que, com parâmetros apropriados, induziu alterações imediatas nos resultados do reflexo H, do COP e do EMG (p.e.). Porém, as alterações a vibrações aplicadas de modo a ativar seletivamente as fibras aferentes do grupo Ia e II mostraram efeitos diferenciais. Vibrações a 80Hz de frequência e a 1 e 2,5mm foram as que mais causaram alterações. A significativa ação sobre o reflexo H é compatível com o aumento da frequência de disparos dos aferentes Ia. Entretanto a forte ação sobre o COP dessas vibrações a 80 Hz sugere que os aferentes Ia podem ter uma importância maior do que a literatura recente tem preconizado, pelo menos para correções a perturbações posturais, uma vez que pode-se supor que a 80 Hz e 1 mm de amplitude os aferentes tipo II são pouco ativados. Por outro lado, a vibração a 15 Hz teve um efeito signficativo sobre o reflexo H mas sem afetar o COP, o que sugere que esta frequência consegue ativar a via Ia, causando depressão homossináptica e/ou inibição pré-sináptica dos aferentes Ia, mas sem chegar a influir no COP de forma significativa. Os resultados são interessantes do ponto de vista de aplicações em potencial para áreas como fisioterapia e reabilitação de pessoas com alterações posturais na clínica. Adicionalmente, abrem novas questões quanto às interpretações fisiológicas de vibrações a diferentes freqüências sobre o tendão calcâneo. / A vibration applied to a muscle tendon increases the firing frequency of afferents of types Ia and II innervating muscle spindles, and hence affects the spinal cord circuits and this can affect motor control. The aim of this study was to analyze the effect of vibrations of two frequencies (15 and 80Hz) and two amplitudes (1 and 2.5 mm) applied to the right Achilles tendon on the standing posture and on the H reflex. The hypothesis was that the high frequency vibration activates preferentially the Ia axons while the 15 Hz vibration activates preferentially the type II axons and hence the 80 Hz vibration would have a strong effect on the H reflex and the 15 Hz vibration would have a strong effect on posture. Fourteen subjects participated in this study. Their H reflex was acquired in the upright position while their Achilles tendon was vibrated. After an interval of rest, the center of pressure (COP) signal was acquired for both the antero-posterior (AP) and the medio-lateral (ML) directions in parallel with the acquisition of bilateral electromyograms (EMG) (SO, TA, and GL GM) in the three conditions (before, during and after the vibration of the Achilles tendon). For 1 and 2.5 mm vibrations at 80 Hz the differences were significant for all variables compared in the three conditions, except for the standard deviation (SD) of the TA and GM EMGs and the average value of COP ML for 1mm vibration. For the 15 Hz vibration, there were no significant differences in both the AP and ML COP and SD of the EMG of the left leg in the three conditions. The results for the EMG SD of the right leg showed no significant effects when using both 15Hz and 80Hz in all three conditions. These data showed that during a stronger vibratory stimulus the COP shifted more to the posterior direction and the left side of the subject. And, after stopping the stimulus, in some cases, the COP had not returned to the initial position. In relation to the mean H reflex amplitude for 1 and 2.5 mm vibrations at 15 and 80 Hz, the analysis showed that during vibration there was a stronger reduction in the amplitude of the H reflex, and in some cases the amplitude remained reduced in the post-vibratory period. The results showed that the vibration applied to the Achilles tendon can be a powerful stimulus to the spinal cord and capable of altering the postural control. The effects depended on the vibration features, since, with appropriate parameters, it led to immediate changes in the results of the H reflex, the COP and left leg EMG. However, 80 Hz vibration (1 and 2.5 mm) was the one that caused the largest changes both on COP and H reflex amplitude. The significant action on the H reflex is consistent with the increased frequency of firing of Ia afferent. However the strong action on the COP of vibrations at 80 Hz suggests that the Ia afferents may have a greater importance than what the recent literature has suggested, at least for postural corrections to disturbances, since it can be assumed that the type II afferents are little activated at 80 Hz and 1 mm amplitude. Furthermore, vibration at 15 Hz had a significant effect on the H reflex without affecting the COP, suggesting that vibrations at this frequency can activate Ia afferents, causing homosynaptic depression and / or presynaptic inhibition of Ia afferents, but without influencing the COP significantly. The results are interesting from the standpoint of potential applications to areas such as physical therapy and rehabilitation of patients in the clinic. Additionally, they raise new questions about the physiological mechanisms behind vibratory stimuli applied at different frequencies on the Achilles tendon.

Electromiography

Eletromiografia

Fusos musculares

H reflex

Muscle spindles

Postura

Posture

Reflexo h

Vibração

Vibration

The effects of static stretching on flexibility, muscle myoelectric activity, muscle performance, passive resistance of hamstrings and rating of perceived stretch.

January 1998

by Chan Suk Ping. / Thesis (M.Phil.)--Chinese University of Hong Kong, 1998. / Includes bibliographical references (leaves 105-119). / Abstract also in Chinese. / Acknowledgments --- p.i / Abstract --- p.ii / List of Tables --- p.ix / List of Figures --- p.xii / Abbreviation --- p.xiv / Chapter CHAPTER ONE --- INTRODUCTION / Chapter 1.1 --- Background --- p.1 / Chapter 1.2 --- The Research Problem --- p.7 / Chapter 1.2.1 --- Purpose of The Study --- p.7 / Chapter 1.2.2 --- Variables and Definition of Terms --- p.8 / Chapter 1.2.3 --- Hypotheses --- p.10 / Chapter 1.2.4 --- Significance of The Study --- p.11 / Chapter CHAPTER TWO --- REVIEW OF LITERATURE / Chapter 2.1 --- Benefits and Potential Disadvantages of Stretching --- p.12 / Chapter 2.1.1 --- Benefits of Stretching --- p.12 / Chapter (a) --- Muscle Relaxation --- p.12 / Chapter (b) --- Performance Enhancement --- p.14 / Chapter (c) --- Prevention of Injury --- p.17 / Chapter (d) --- Increase of Range of Motion --- p.19 / Chapter (e) --- Prevention of Muscle Soreness --- p.20 / Chapter 2.1.2 --- The Potential Disadvantages of Stretching --- p.20 / Chapter 2.2 --- Limiting Factors of Flexibility --- p.22 / Chapter 2.2.1 --- Muscle --- p.22 / Chapter (a) --- Histologic Components of Muscle --- p.22 / Chapter (b) --- Muscular Elongation --- p.23 / Chapter (c) --- The Effects of Immobilization --- p.23 / Chapter 2.2.2 --- Connective Tissue --- p.24 / Chapter (a) --- Collagen --- p.25 / Chapter (b) --- Elastic Tissue --- p.27 / Chapter (c) --- Tissue Composed of Connective Tissue --- p.27 / Chapter 2.2.3 --- The Mechanical Properties of Soft Tissue --- p.30 / Chapter 2.2.4 --- "Age, Gender, Physical Activity and Temperature" --- p.33 / Chapter 2.3 --- Neurophysiology of Stretching --- p.34 / Chapter 2.3.1 --- Muscle Spindles and Golgi Tendon Organs --- p.34 / Chapter (a) --- Structure and Role of Muscle Spindle --- p.35 / Chapter (b) --- Structure and Role of Golgi Tendon Organs --- p.38 / Chapter (c) --- Parallel and Series End Organs --- p.38 / Chapter 2.3.2 --- Electromyography --- p.39 / Chapter 2.4 --- Hamstrings --- p.43 / Chapter 2.4.1 --- Functions of Hamstrings --- p.43 / Chapter 2.4.2 --- Limited Range of Motion in Hamstrings --- p.45 / Chapter 2.4.3 --- Measurement of Hamstrings Flexibility --- p.46 / Chapter 2.5 --- Stretching Protocol --- p.50 / Chapter 2.5.1 --- Modes of Stretching --- p.50 / Chapter 2.5.2 --- Intensity of Stretching --- p.53 / Chapter CHAPTER THREE --- METHOD / Chapter 3.1 --- Subjects --- p.55 / Chapter 3.2 --- Instrumentation --- p.57 / Chapter 3.3 --- Procedure --- p.60 / Chapter 3.4 --- Reliability Study --- p.69 / Chapter 3.5 --- Data Analysis --- p.70 / Chapter CHAPTER FOUR --- RESULTS / Chapter 4.1 --- Reliability Study --- p.72 / Chapter 4.2 --- Experimental Study --- p.73 / Chapter 4.2.1 --- Range of Motion of Pre-Test and Post-Test --- p.74 / Chapter 4.2.2 --- Passive Resistance of Pre-Test and Post-Test --- p.75 / Chapter 4.2.3 --- Subjective Rating of Pre-Test and Post-Test --- p.76 / Chapter 4.2.4 --- Myoelectric Activities of Hamstrings of Pre-Test and Post-Test --- p.76 / Chapter 4.2.5 --- Hamstrings Performance of Pre-Test and Post-Test --- p.79 / Chapter 4.2.6 --- Range of Motion Difference among Trained and Untrained Groups --- p.81 / Chapter 4.2.7 --- Passive Resistance of Hamstrings Difference among Trained and Untrained Groups --- p.82 / Chapter 4.2.8 --- Subjective Rating of Perceived Stretch Difference among Trained and Untrained Groups --- p.82 / Chapter 4.2.9 --- Myoelectric Activities of Hamstrings Difference among Trained and Untrained Groups --- p.83 / Chapter 4.3.0 --- Performance of Hamstrings Difference among Trained and Untrained Groups --- p.83 / Chapter CHAPTER FIVE --- DISCUSSION / Chapter 5.1 --- Hamstrings Flexibility Analysis --- p.92 / Chapter 5.2 --- Hamstrings Passive Resistance Analysis --- p.94 / Chapter 5.3 --- Rating of Perceived Stretch Analysis --- p.97 / Chapter 5.4 --- Hamstrings Myoelectric Activities Analysis --- p.98 / Chapter 5.5 --- Hamstrings Performance Analysis --- p.100 / Chapter 5.6 --- Limitations and Suggestions --- p.102 / Chapter 5.7 --- Conclusions --- p.103 / REFERENCES --- p.105 / APPENDIX / Appendix A. Informed Consent / Appendix B. Personal Particulars and Past Medical History Screening Sheet / Appendix C. Perceived Stretch Rating Scale / Appendix D. Record Sheet

Muscles--physiology

Muscle Spindles--physiology

Muscle Relaxation--physiology

Range of Motion, Articular--physiology

Efeitos de diferentes freqüências e amplitudes de vibração unilateral do tendão calcâneo na orientação postural e no reflexo H em humanos / Effects of Achilles tendon vibration of different frequencies and amplitudes on postural orientation and H reflex in humans

Sabrina Tiago Pedão

30 March 2010

Uma vibração aplicada a um tendão muscular aumenta a freqüência de disparos de aferentes, como os de fusos neuromusculares Ia e II, cujas terminações afetam circuitos da medula espinhal e com isto podem influenciar o controle motor. O objetivo deste estudo foi analisar o efeito de vibrações a duas freqüências (15 e 80Hz) e amplitudes de 1 e 2,5mm aplicadas ao tendão calcâneo direito sobre o sistema de controle postural e sobre a circuitaria neural associada a reflexos monosinápticos da perna. A hipótese era de que a vibração de alta freqüência ativasse preferencialmente os aferentes de fuso neuromuscular de tipo Ia enquanto a vibração a 15 Hz ativasse preferencialmente os aferentes de tipo II. Isto significaria que a vibração a 80 Hz teria forte efeito sobre o reflexo H, enquanto a vibração a 15 Hz teria um efeito significativo sobre a postura. Participaram deste estudo 14 sujeitos sãos. Na postura ereta quieta, foi realizada a aquisição do reflexo H enquanto o tendão calcâneo era vibrado. Após um intervalo de descanso, foi realizada a aquisição do Centro de Pressão (COP) tanto na direção Ântero-Posterior (AP) quanto na Médio-Lateral (ML) em paralelo à aquisição bilateral do EMG dos músculos (SO, TA, GL e GM) nas três condições (antes, durante e após a vibração do tendão calcâneo). Para os estímulos de 1 e 2,5mm realizados a 80 Hz as diferenças foram significativas em relação a todas as variáveis quando comparadas nas três condições, com exceção apenas do DP do TA e GM e, do valor médio do COP ML a 1mm. Em relação à freqüência de 15 Hz, notou-se que não houve diferenças significativas tanto no COP AP e ML quanto no DP do EMG dos músculos da perna esquerda entre as três condições. Quanto aos dados referentes ao DP dos músculos analisados na perna direita, os resultados mostraram que não houve efeitos significativos tanto ao utilizar 15Hz como 80Hz em todas as três condições. Em geral, estes dados mostraram que durante um estímulo vibratório mais forte o COP deslocouse mais para a direção posterior e lateral esquerda do sujeito. E, após interromper o estímulo, em alguns casos o COP ainda mostrava uma alteração prolongada. Em relação à amplitude média do reflexo H, para as amplitudes de vibração de 1 e 2,5 mm a 15 e 80 Hz, as análises apontaram que durante a vibração houve uma forte redução na amplitude do reflexo, sendo que em alguns casos ainda permaneceram reduzidas na condição pós-vibratória. Os resultados mostram que a vibração aplicada ao tendão calcâneo pode ser um forte estímulo à medula e capaz de alterar o controle postural, dependendo de suas características, uma vez que, com parâmetros apropriados, induziu alterações imediatas nos resultados do reflexo H, do COP e do EMG (p.e.). Porém, as alterações a vibrações aplicadas de modo a ativar seletivamente as fibras aferentes do grupo Ia e II mostraram efeitos diferenciais. Vibrações a 80Hz de frequência e a 1 e 2,5mm foram as que mais causaram alterações. A significativa ação sobre o reflexo H é compatível com o aumento da frequência de disparos dos aferentes Ia. Entretanto a forte ação sobre o COP dessas vibrações a 80 Hz sugere que os aferentes Ia podem ter uma importância maior do que a literatura recente tem preconizado, pelo menos para correções a perturbações posturais, uma vez que pode-se supor que a 80 Hz e 1 mm de amplitude os aferentes tipo II são pouco ativados. Por outro lado, a vibração a 15 Hz teve um efeito signficativo sobre o reflexo H mas sem afetar o COP, o que sugere que esta frequência consegue ativar a via Ia, causando depressão homossináptica e/ou inibição pré-sináptica dos aferentes Ia, mas sem chegar a influir no COP de forma significativa. Os resultados são interessantes do ponto de vista de aplicações em potencial para áreas como fisioterapia e reabilitação de pessoas com alterações posturais na clínica. Adicionalmente, abrem novas questões quanto às interpretações fisiológicas de vibrações a diferentes freqüências sobre o tendão calcâneo. / A vibration applied to a muscle tendon increases the firing frequency of afferents of types Ia and II innervating muscle spindles, and hence affects the spinal cord circuits and this can affect motor control. The aim of this study was to analyze the effect of vibrations of two frequencies (15 and 80Hz) and two amplitudes (1 and 2.5 mm) applied to the right Achilles tendon on the standing posture and on the H reflex. The hypothesis was that the high frequency vibration activates preferentially the Ia axons while the 15 Hz vibration activates preferentially the type II axons and hence the 80 Hz vibration would have a strong effect on the H reflex and the 15 Hz vibration would have a strong effect on posture. Fourteen subjects participated in this study. Their H reflex was acquired in the upright position while their Achilles tendon was vibrated. After an interval of rest, the center of pressure (COP) signal was acquired for both the antero-posterior (AP) and the medio-lateral (ML) directions in parallel with the acquisition of bilateral electromyograms (EMG) (SO, TA, and GL GM) in the three conditions (before, during and after the vibration of the Achilles tendon). For 1 and 2.5 mm vibrations at 80 Hz the differences were significant for all variables compared in the three conditions, except for the standard deviation (SD) of the TA and GM EMGs and the average value of COP ML for 1mm vibration. For the 15 Hz vibration, there were no significant differences in both the AP and ML COP and SD of the EMG of the left leg in the three conditions. The results for the EMG SD of the right leg showed no significant effects when using both 15Hz and 80Hz in all three conditions. These data showed that during a stronger vibratory stimulus the COP shifted more to the posterior direction and the left side of the subject. And, after stopping the stimulus, in some cases, the COP had not returned to the initial position. In relation to the mean H reflex amplitude for 1 and 2.5 mm vibrations at 15 and 80 Hz, the analysis showed that during vibration there was a stronger reduction in the amplitude of the H reflex, and in some cases the amplitude remained reduced in the post-vibratory period. The results showed that the vibration applied to the Achilles tendon can be a powerful stimulus to the spinal cord and capable of altering the postural control. The effects depended on the vibration features, since, with appropriate parameters, it led to immediate changes in the results of the H reflex, the COP and left leg EMG. However, 80 Hz vibration (1 and 2.5 mm) was the one that caused the largest changes both on COP and H reflex amplitude. The significant action on the H reflex is consistent with the increased frequency of firing of Ia afferent. However the strong action on the COP of vibrations at 80 Hz suggests that the Ia afferents may have a greater importance than what the recent literature has suggested, at least for postural corrections to disturbances, since it can be assumed that the type II afferents are little activated at 80 Hz and 1 mm amplitude. Furthermore, vibration at 15 Hz had a significant effect on the H reflex without affecting the COP, suggesting that vibrations at this frequency can activate Ia afferents, causing homosynaptic depression and / or presynaptic inhibition of Ia afferents, but without influencing the COP significantly. The results are interesting from the standpoint of potential applications to areas such as physical therapy and rehabilitation of patients in the clinic. Additionally, they raise new questions about the physiological mechanisms behind vibratory stimuli applied at different frequencies on the Achilles tendon.

Eletromiografia

Fusos musculares

Postura

Reflexo h

Vibração

Electromiography

H reflex

Muscle spindles

Posture

Vibration

Analysis of Stretch Reflex Responses in Mice Lacking Munc18-1 in Proprioceptors

Mohi, Amr

January 2017

No description available.

Neurosciences

Anatomy and Physiology

Stretch reflex

Ia afferents

spinal cord circuits

Munc18-1

Cre

proprioceptors

muscle spindles

Classification of muscle stretch receptor afferents in humans

Edin, Benoni B.

January 1988

The response patterns of human stretch receptors in the finger extensor muscles of the forearm were studied using the microneurography technique. Single-unit recordings were obtained from one-hundred and twenty-four afferents. A procedure was developed to classify the units in muscle spindle primary afferents, secondary afferents, and Golgi tendong organ afferents. The procedure allows an objective and reproducible classification on the basis of the afferents’ responses to a series of tests which individually are non-conclusive. It was demonstrated that maximal twitch contractions can be elicited in the finger extensor muscles of the forearm, without causing undue discomfort to the subjects, or hazarding the single-unit recording. The response of the units to this test allowed, in most cases but not always, a separation in muscle spindle and tendon organ afferents. Thus the test was not adequate for an unequivocal classification. Three discrete response parameters were extracted from ramp-and-hold stretches, viz. the presence or absence of an initial burst and a deceleration response, and prompt silencing at slow muscle shortening. The distributions of the parameters were significantly different among the three unit types. These parameters which were pair-wise independent constituted a set of considerable discriminative power. It was shown that human muscle spindles have about the same static position sensitivity to fractional muscle stretch as previously found in animals. Stretch sensitization was demonstrated by rapid, repeated stretches of the muscle which enhanced the réponse to subsequent slow stretches of muscle spindles. Sensitization was different with primary and secondary muscle spindle afferents whereas Golgi tendon organ afferents never displayed stretch sensitization. One-to-one driving with small-amplitude sinusoidal stretches superimposed on ramp-and- hold stretches was almost exclusively seen with primary muscle spindle afferents, whereas secondaries seldom and tendon organ afferents never displayed driving. The afferent responses during slowly increasing isometric contractions and rapid relaxations were analysed. An increased discharge rate on relaxation was common among spindle afferents whereas it was never seen in tendon organs afferents. Two separate groups of spindles afferents were found with regard to fusimotor recruitment. The largest group was recruited at rather low and variable contractile forces whereas the smaller group was not recruited at all. The proportions of the three unit types, spindle primary, spindle secondary, and Golgi tendon organ afferents were estimated from a preliminary classification and the distribution of the eight response features were analyzed for each class of afferents. On the basis of these estimates and the response pattern of the individual unit Bayes’ theorem was used to calculate the probabilities that the unit was a spindle primary, a spindle secondary, or a tendon organ afferent. Estimates indicate that about 19 out of 20 muscle afferents are correctly classified when all eight features are analyzed. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 1988, härtill 6 uppsatser.</p> / digitalisering@umu

Muscle spindles

Golgi tendon organs

Classification of muscle receptors

Microneurography

Human hand

Stretch sensitization

Voluntary contraction

Static position sensitivity

Fusimotor control

Tônus muscular = uma contribuição para os estudos em imagem corporal / Muscle Tonus : a contribution to the studies of body image

Castillo, Andrea Amaral

18 August 2018

Orientador: Maria da Consolação Gomes Cunha Fernandes Tavares / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Educação Física / Made available in DSpace on 2018-08-18T10:27:09Z (GMT). No. of bitstreams: 1 Castillo_AndreaAmaral_M.pdf: 1424495 bytes, checksum: 2e616dc1accf2266891ba1011fc14c1e (MD5) Previous issue date: 2011 / Resumo: A Imagem Corporal foi conceituada por Paul Schilder (1999) como a representação mental do corpo. Neste conceito ele aponta para uma abordagem sistêmica dos aspectos fisiológicos, psíquicos, sociais e culturais no processo dinâmico da expressão singular da identidade corporal. Em seu livro "The Image and appearance of humam body", publicado em 1935, Schilder chama a atenção para a relação entre o Tônus Muscular e a Imagem Corporal num capítulo exclusivo sobre o tema. Ressaltou que a Imagem Corporal era tracionada em direção ao Tônus Muscular uma vez que a ação de um único segmento corporal é capaz de colocar o corpo como um todo em uma nova relação com o ambiente. No entanto esta relação não se encontra sistematizada e valorizada dentro das diversas áreas do saber e tem sido pouco abordada nas pesquisas em Imagem Corporal. O foco direcionado ora ao Tônus Muscular, ora à Imagem Corporal implica muitas vezes num entendimento fragmentado capaz de desconsiderar a singularidade do indivíduo e/ou o dinamismo neurofisiológico na sua relação com o meio e com o outro. Assim a proposta deste estudo é sistematizar e analisar o conhecimento sobre o Tônus Muscular nas perspectivas de Charles Scott Sherrington cujo foco se apóia na Ação Reflexa; de Henry Head, que apresenta o Modelo Postural como a base para as pesquisas em Imagem Corporal; e da Neurociência, que propõe análises do comportamento humano na relação com o ambiente. Dentre as inúmeras contribuições feitas por Charles Scott Sherrington, foi a perspectiva da Ação Integrativa do sistema nervoso que trouxe um novo entendimento ao meio científico da época. Ao considerar a ação reflexa como uma resposta adaptativa do organismo, Sherrington encontrou no Tônus Muscular o exemplo explícito de um processo integrativo cuja proposta é manter a postura do organismo contra a gravidade. Henry Head influenciado por esse novo olhar, e inquieto com suas observações clínicas tornou-se o próprio objeto experimental numa investigação sobre os tipos de sensibilidade. A partir dos resultados de suas pesquisas e apoiado nas idéias e conceitos de Sherrington, Head propõe a existência de um Modelo Postural como uma medida de referência sobre a qual o corpo se ajusta constantemente através das variações do Tônus Muscular. Estas medidas são então registradas dentro de um esquema plástico de representação mental da postura e do movimento. A neurociência intensifica suas investigações sobre o organismo dentro do contexto do ambiente onde um é capaz de influenciar o outro. Com isso abriu-se uma nova perspectiva acerca do Tônus Muscular e o comportamento humano. As descobertas sobre a participação do fuso neuromuscular na elaboração da Imagem Corporal, as alterações mecânicas que implicam em alterações sensoriais e a ação segmentar que se propaga ao longo de todo o corpo trazem contribuições importantes que reforçam a relação íntima entre o Tônus Muscular e a representação mental do corpo. A partir deste estudo espera-se trazer uma reflexão mais profunda sobre o papel do Tônus Muscular e contribuir para futuras pesquisas e estudos sobre a Imagem Corporal / Abstract: Paul Schilder (1999) defined Body Image as the mental representation of the body. In this concept, he points out to a systemic approach of physiological, psychological, social and cultural aspects in the dynamic process of the body image unique expression. In his book "The Image and appearance of human body", published in 1935, Schilder draws attention to the relationship between Muscle Tonus and Body Image, dedicating a whole chapter to this theme. He emphasized that Body Image was pulled towards Muscle Tonus, since the action of a single body segment can place the whole body in a new interaction with the environment. However, this relationship has not been schematized and given the proper value by different areas of knowledge and it has been little addressed in studies about Body Image. Changing the focus from Muscle Tonus to Body Image back and forth can frequently lead to a fragmented understanding which may disregard each individual particularity and/or the neurophysiological dynamics in the individual interaction with the environment and others. Hence, this study aims to systematize and discuss the knowledge about muscle tone, as seen by Charles Scott Sherrington who focus on Reflex Action; by Henry Head, who presents Postural Model as fundamental for Body Image researches; and by Neuroscience, which suggests the study of human behavior and its relation with the environment. One of the several contributions by Charles Scott Sherrington, the Integrative Action of the nervous system brought a new understanding to the scientific community at the time. By considering reflex action as an adjustable response of the body, Sherrington saw the Muscle Tonus as a clear example of an integrative process which aims to keep the body posture against gravity. Henry Head was influenced by this new approach, and, out of a strong urge towards his clinical observation, became his own experiment subject on his study about sensitivity types. Supported by the results of his own researches and backed by Sherrington's concepts and ideas, Head suggests that there is a Postural Model acting as a reference measure which the body constantly fits into according to Muscle Tonus variations. These measures are registered within a scheme of posture and movement representations. Neuroscience stresses the focus of studies about the body within a context where one causes an impact on the other, bringing out a new outlook for Muscle Tone and human behavior. Findings about neuromuscular fuse participation in Body Image building, mechanical changes which cause sensorial changes and the segmental action which spreads throughout the body play an important role and corroborate the close relationship between Muscle Tonus and body mental representation. This study is expected to bring up a more comprehensive discussion on the role of Muscle Tonus and to enhance future researches and studies on Body Image / Mestrado / Atividade Fisica Adaptada / Mestre em Educação Física

Tensão muscular

Reflexos

Postura

Fuso neuromuscular

Imagem corporal

Muscle tonus

Reflex strech

Posture

Muscle spindles

Body image

A Novel Method for Analysis of Proprioceptor Sensory Neuron Subtypes in the Mouse Dorsal Root Ganglia

Grant, Delaney C.

05 May 2021

No description available.

Neurobiology

Neurosciences

Physiology

Proprioception

proprioceptors

muscle spindles

Golgi tendon organs

Parvalbumin

movement sensing

proprioceptive sensory neurons

proprioceptive sensory afferents

DRG

dorsal root ganglia

rhodamine