Spelling suggestions: "subject:"locomotion"" "subject:"iocomotion""
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State-dependent corrective reactions for backward balance losses during human walkingUno, Yoji, Ohta, Yu, Kagawa, Takahiro 12 1900 (has links)
No description available.
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Functional changes in rat achilles tendon following collagenase injury and manual soft tissue mobilizationLim, Young-tae January 1994 (has links)
The purpose of this study was to determine the functional changes due to the Graston Therapeutic Technique (GTT) in an animal model. This study attempted to verify the biomechanical changes associated with the Graston Therapeutic Technique (GTT) in order to possibly apply it to humans as a major physical therapy modality. Eighteen adult, male Sprague-Dawley rats were assigned randomly to three groups. The groups were classified as follows: (a) no injured plus GTT treatment, (b) injured minus GTT treatment, (c) injured plus GTT treatment. The GTT therapy began after one week following injury to allow for optimum inflammation and scar formation. The animals receiving GTT had six treatments over the course of two weeks. Running tests were performed on a treadmill at a velocity of 22 cm/s prior to induction of injury, one week following injury, two weeks following injury, and three weeksfollowing injury in the experimental groups. Variables analyzed were knee and ankle range of motion (ROM), stride length (SL), and stride frequency (SF). Significance of effect between experimental groups were determined by repeated measures one-way ANOVA, Scheffe's post hoc test, and Newman-Keuls post hoc test. The stride length and stride frequency results of the present study appeared to indicate that the Graston Therapeutic Technique (GTT) had an effect on changes in the stride length and stride frequency after injury. Statistical analysis between observations for the GTT plus groups indicated a significant difference in the swing phase of knee ROM. The results of this study also indicated that the Graston Therapeutic Technique may have had an influence on knee joint range of motion. / School of Physical Education
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The effects of stroke rate and stroke length on upper quadrant stroke patterns in competitive swimmingUpshaw, Kris January 1995 (has links)
The purpose of this study was to describe women collegiate swimmers' armstroke sequence at selected velocities. In addition, this study was designed to determine the timing angle during the course of a stroke cycle. Seven members of the Ball State University Women's Swim Team were asked to participate in this study. The test consisted of the subject swimming approximately fifteen meters freestyle (front crawl) at stroke rates of 24, 30, 40, 48, 60 strokes per minute. The subjects attempted three trials at each stroke rate, on a continuum from slow to fast. The following parameters were determined from video analysis: stroke length (SL), velocity (m/s), time of one complete stroke cycle (SCT), timing between the arm cycles (RAE), recovery arm entry as a percentage of SCT (RAE%) and the timing angle. A correlation between the timing angle and V of r = 0.48 was found to be significant at the 0.05 level. A correlation between the SCT and the timing angle of r = -0.62 was found to be significant at the 0.05 level. A correlation of r = -0.43 between SL and the timing angle of less than 90 degrees is believed to benefit theangle was found to be significant at the 0.05 level. This indicates that as the swimmers' SCT decreased, the timing angle increased. And, as the swimmers' SL decreased the timing angle increased. It appears that timing angles increase with increasing V. The mean timing angle for ninety trials was 66.03 degrees with a SD of 17.68. This study indicates that women collegiate swimmers use a timing angle of less than 90 degrees. A timing swimmers' body position, balance and SL. / School of Physical Education
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Minimalist Dynamic ClimbingDegani, Amir 01 November 2010 (has links)
Dynamics in locomotion is highly useful, as can be seen in animals and is becomingapparent in robots. For instance, chimpanzees are dynamic climbers that canreach virtually any part of a tree and even move to neighboring trees, while sloths arequasistatic climbers confined only to a few branches. Although dynamic maneuversare undoubtedly beneficial, only a few engineered systems use them, most of whichlocomote horizontally. This is because the design and control are often extremelycomplicated.This thesis explores a family of dynamic climbing robots which extend roboticdynamic legged locomotion from horizontal motions such as walking, hopping, andrunning, to vertical motions such as leaping maneuvers. The motion of these dynamicrobots resembles the motion of an athlete jumping and climbing inside achute. Whereas this environment might be an unnavigable obstacle for a slow, quasistaticclimber, it is an invaluable source of reaction forces for a dynamic climber.The mechanisms described here achieve dynamic, vertical motions while retainingsimplicity in design and control.The first mechanism called DSAC, for Dynamic Single Actuated Climber, comprisesonly two links connected by a single oscillating actuator. This simple, openlooposcillation, propels the robot stably between two vertical walls. By rotating theaxis of revolution of the single actuator by 90 degrees, we also developed a simplerrobot that can be easily miniaturized and can be used to climb inside tubes.The DTAR, for Dynamic Tube Ascending Robot, uses a single continuously rotatingmotor, unlike the oscillating DSAC motor. This continuous rotation even furthersimplifies and enables the miniaturization of the robot to enable robust climbinginside small tubes. The last mechanism explored in this thesis is the ParkourBot,which sacrifices some of the simplicity shown in the first two mechanism in favorof efficiency and more versatile climbing. This mechanism comprises two efficientspringy legs connected to a body.We use this family of dynamic climbers to explore a minimalist approach to locomotion.We first analyze the open-loop stability characteristics of all three mechanisms.We show how an open-loop, sensorless control, such as the fixed oscillationof the DSAC’s leg can converge to a stable orbit. We also show that a change inthe mechanism’s parameters not only changes the stability of the system but alsochanges the climbing pattern from a symmetric climb to a limping, non-symmetricclimb. Corresponding analyses are presented for the DTAR and ParkourBot mechanisms.We finally show how the open-loop behavior can be used to traverse morecomplex terrains by incrementally adding feedback. We are able to achieve climbinginside a chute with wall width changes without the need for precise and fast sensingand control.
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The effect of age on neuromechanical responses to electrical stimulation of superficial peroneal nerve during walkingBrodie, Ryan 16 January 2014 (has links)
In the healthy young, stimulation of superficial peroneal nerve (SPn) cutaneous afferents at the ankle during walking has been shown to elicit functionally relevant neural and mechanical responses that contribute to obstacle avoidance during swing and have been referred to as stumble corrective responses. However, specific age-related differences in the stumble corrective response induced by electrically evoked cutaneous stimulation have yet to be determined. As a confounding contributor to age related changes in dynamic stability during locomotion, neural and mechanical changes in the stumble corrective response may result in a decreased ability to recover from a destabilizing incident and provide key markers of neuromuscular decline. Therefore the purpose of this study was to compare age-dependent differences in responses to electrically evoked stimulation of the superficial peroneal nerve at the ankle during walking in healthy young and elderly groups. Electromyograms (EMG) of the tibialis anterior (TA), soleus (Sol), medial gastrocnemius (MG), biceps femoris (BF) and vastus lateralis (VL) were recorded along with gait kinematics including joint displacement and angular velocity at the ankle and knee as well as toe clearance relative to the walking surface. Overall, the stumble corrective response was preserved in the elderly as evident by significant responses in kinematics and muscle activity that were similar in sign and phase to those seen in the healthy young. However, the magnitude of the kinematic responses and resulting toe clearance in older adults were significantly smaller than in the young. Further, during the swing phase of unstimulated walking cycles, there were reduced knee flexion, plantarflexion and toe clearance in the elderly with corresponding differences in muscle activity. Therefore, smaller kinematic responses to stimulation, in the elderly, superimposed on a different undisturbed gait profile, resulting in reduced toe clearance, reflects early degradation of the stumble corrective response. This early degradation is likely a prodromal sign of increased fall risk. This supports the potential use of cutaneous reflexes in quantifying degradation of neuromuscular control and its contribution to fall risk. / Graduate / 0317 / 0758 / rbrodie@uvic.ca
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Relationships among amphetamine-induced locomotor activity, stereotypy, memory facilitation and conditioned taste aversionCarr, Geoffrey David. January 1981 (has links)
No description available.
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Crossing the Midline : Locomotor Neuronal Circuitry FormationMemic, Fatima January 2012 (has links)
Networks at various levels of the nervous system coordinate different motor patterns such as respiration, eye or hand movements and locomotion. Intrinsic rhythm-generating networks that are located in the spinal cord generate motor behaviors that underlie locomotion in vertebrates. These networks give a continuous and measurable coordinated rhythmic motor output and are referred to as locomotor central pattern generators (CPGs). Characterization of the mammalian locomotor CPG and its molecular control is depending on the identification of participating neurons and neuronal populations. In this thesis I present work where we have studied the significance of subpopulations of neurons in the formation and function of the left-right circuitry. In summary, we show that the axon guidance receptor DCC has a central role in the formation of spinal neuronal circuitry underlying left-right coordination, and that both Netrin-1 and DCC are required for normal function of the locomotor CPG. Commissural interneurons (CINs), which send their axons across the ventral midline in the spinal cord, play a critical role in left–right coordination during locomotion. A complete loss of commissural axons in the spinal cord, as seen in the Robo3 null mutant mouse, resulted in uncoordinated fictional locomotor activity. Removing CIN connections from either dorsal or ventral neuronal populations led to a shift from alternation to strict synchronous locomotor activity. Inhibitory dI6 CIN have been suggested as promising candidate neurons in coordinating bilateral alternation circuitry. We have identified that Dmrt3, expressed in inhibitory dI6 CINs, is a crucial component for the normal development of coordinated locomotor movements in both horses and mice. We have also concluded that the prominent hopping phenotype seen in hop/hop mice is a result of abnormal developmental processes including induction from the notochord and Shh signaling. Together, these findings increase our knowledge about the flexibility in neuronal circuit development and further confirm the role of dI6 neurons in locomotor circuits.
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Walking stability in young, old and neuropathic subjectsMenz, Hylton, Physiology, UNSW January 2002 (has links)
This thesis investigates walking patterns in healthy young people and in people with an increased risk of falling, and determines the physiological contributions to walking stability. First, a review of the relevant literature on techniques for assessing walking stability, age-related changes in balance and gait, and the contributions of vision, vestibular function, peripheral sensation and strength was undertaken. In response to a critical analysis of these findings, a new technique and protocol for the assessment of walking stability was developed. This involved measuring and analysing head and pelvis accelerations while subjects walked on a level surface and an irregular surface. Gait patterns were studied in 30 young healthy subjects and two groups known to be at increased risk of falling - 100 subjects over the age of 75, and 30 subjects with diabetic peripheral neuropathy. A series of vision, sensation, strength, reaction time and balance tests were also undertaken to identify subjects??? physiological abilities and risk of falls. Acceleration patterns of the head and pelvis differed according to physiological risk of falling, particularly when walking on the irregular surface. Those with a high risk of falling walked with a reduced velocity, cadence and step length, and exhibited less rhythmic acceleration patterns at the head and pelvis. Gait patterns were significantly associated with leg strength, peripheral sensation and reaction time. It is concluded that subjects with a high physiological risk of falling exhibit characteristic patterns of walking that indicate an impaired ability to control the movement of the pelvis and head, which may predispose to loss of balance.
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A biomechanical analysis of relationship between the head and neck position, vertebral column and limbs in the horse at walk and trot /Rhodin, Marie, January 2008 (has links) (PDF)
Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniversitet, 2008. / Härtill 4 uppsatser.
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Physical capacity in individuals with cerebral palsy : problems, needs and resources, with special emphasis on locomotion /Andersson, Christina, January 2005 (has links)
Diss. (sammanfattning) Stockholm : Karol. inst., 2005. / Härtill 4 uppsatser.
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