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1

Electronic Resource

Muscle and liver pyruvate kinases are closely related: amino acid sequence comparisons

Hoar, C.G. ; Nicoll, G.W. ; Schiltz, E. ; [et al.]

Amsterdam : Elsevier

FEBS Letters 171 (1984), S. 293-295

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ISSN: 0014-5793

Keywords: Amino acid sequence ; L isozyme ; M"1isozyme ; Phosphorylation ; Pyruvate kinase

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Biology , Chemistry and Pharmacology , Physics

Type of Medium: Electronic Resource

URL: http://linkinghub.elsevier.com/retrieve/pii/0014-5793(84)80507-4

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2

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Purification and characterization of fatty acid-binding proteins from brown adipose tissue of the rat

Dutta-Roy, A.K. ; Huang, Y. ; Dunbar, B. ; [et al.]

Amsterdam : Elsevier

Biochimica et Biophysica Acta (BBA)/Lipids and Lipid Metabolism 1169 (1993), S. 73-79

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ISSN: 0005-2760

Keywords: (Rat) ; Amino acid sequence ; Arachidonic acid ; Brown adipose tissue ; Fatty acid-binding protein

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Biology , Chemistry and Pharmacology , Medicine , Physics

Type of Medium: Electronic Resource

URL: http://linkinghub.elsevier.com/retrieve/pii/0005-2760(93)90084-M

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3

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Automatic postural responses in the cat: Responses to headward and tailward translation (1983)

Rushmer, D. S. ; Russell, C. J. ; Macpherson, J. ; [et al.]

Springer

Experimental brain research 50 (1983), S. 45-61

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ISSN: 1432-1106

Keywords: Postural reflexes ; Unexpected postural perturbations ; Electromyographic activity ; Hind limb and forelimb muscles ; Cat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary EMG responses, vertical and A-P shear forces and kinematics of “automatic postural responses” to unexpected translational perturbations in the headward and tailward directions were studied in cats. Muscles acting on the major joints of the forelimbs and hindlimbs were studied. Movement of the animals in response to perturbation were highly stereotyped and consisted of two phases: (1) motion of the feet during platform movement while the trunk remained relatively stationary followed by (2) active correction of posture by movement of the trunk in the direction of perturbation. Vertical force changes occurred after the perturbation was well underway (latency 65 ms) and were related to the displacement of the center of mass and active correction of trunk position. Shear forces showed both passive (inertial) and active components and suggested that the majority of the torque necessary for po,stural correction was generated by the hindlimb. EMG responses in forelimb and shoulder muscles were most correlated with increase in vertical force, showing a generalized co-contraction in tailward translation (when these limbs were loaded) and little activity when the forelimbs were unloaded. EMG responses in hindlimb showed reciprocal activation of agonists and antagonists during perturbation with strong synergies of thigh and foot flexors in tailward translation and thigh and foot extensors in headward translation. The forelimb EMG patterns were most consistent with the conclusion that the forelimb is used primarily for vertical support during perturbation. It was concluded that hindlimb EMG responses were appropriate for both vertical support and performance of the postural correction. The hindlimb muscle synergies observed during translation are the “mirror image” of those observed in humans by other workers.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00238231

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4

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Postural responses in the cat to unexpected rotations of the supporting surface: evidence for a centrally generated synergic organization (1986)

Macpherson, J. M. ; Rushmer, D. S. ; Dunbar, D. C.

Springer

Experimental brain research 62 (1986), S. 152-160

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ISSN: 1432-1106

Keywords: Posture ; Freely-standing cat ; Central program ; Muscle synergy ; EMG

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Postural reactions to disruptions of stance are rapid and automatic in both quadrupeds and bipeds. Current evidence suggests that these postural responses are generated by the central nervous system as patterns involving muscle synergies. This study attempted to test this hypothesis of a centrally generated postural mechanism by determining whether the same postural response could be evoked in the freely-standing cat under two different biomechanical conditions. The present work is an extension of previous experiments in which the stance of cats was perturbed by a horizontal translation of the supporting surface in the anterior and posterior directions (Rushmer et al. 1983). We now tested whether simple rotation of the metacarpo- and metatarsophalangeal (M-P) joints that mimics the digit rotation occurring during platform translation, was sufficient to evoke the translation postural response. The rotational perturbations were biomechanically different from translations in that the rotation did not cause displacement of the centre of mass of the animal, nor did it result in any significant movement about any but the M-P joints. Even so, rotational perturbations did evoke the appropriate translational muscle synergies in all four animals. Both plantar flexion rotation and headward translation activated the posterior hindlimb synergy (which included gluteus medius, semitendinosus and lateral gastrocnemius). Similarly, dorsiflexion rotation and tailward translation both activated the same anterior hindlimb synergy (iliopsoas, vastus lateralis and tibialis anterior) together with the forelimb synergy. The postural responses elicited by rotational perturbations were biomechanically inappropriate, and caused the animal to displace its own centre of mass away from the stable, control position. The most striking finding was that the group of muscles in which the medium latency postural response was evoked was different than the group from which short latency reflex responses were elicited. These data support the hypothesis that postural reactions are not merely reflex responses to local sensory inputs associated with the perturbation but, instead, represent a centrally generated response, with the muscle synergy being the controlled unit.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00237411

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5

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Automatic postural responses in the cat: responses of distal hindlimb muscles to paired vertical perturbations of stance (1987)

Rushmer, D. S. ; Dunbar, D. C. ; Russell, C. J. ; [et al.]

Springer

Experimental brain research 68 (1987), S. 477-490

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ISSN: 1432-1106

Keywords: Postural reflexes ; Unexpected postural perturbations ; Electromyographic activity ; Motor control ; Hindlimb muscles ; Cat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The active components of the quadrupedal diagonal stance response to rapid removal of the support from beneath a single limb were studied in cats to further define the mechanisms that trigger and generate the response. We recorded EMG activity from lateral gastrocnemius and tibialis anterior muscles in awake, behaving cats while they stood on an hydraulic posture platform. By dropping the support from beneath a single limb, we evoked the diagonal stance response, with its characteristic changes in vertical force and EMG patterns. As the animal responded to this drop, a second perturbation of posture was then presented at intervals of 10 to 100 ms following the first. This second perturbation, which consisted of dropping the support from beneath the two limbs that were loaded as a result of the initial limb drop, made the first response biomechanically inappropriate. The EMG responses observed in both muscles during paired perturbations were triggered by the somatosensory events related to the perturbations. Muscle responses that were appropriate for the first perturbation always occurred with amplitudes and latencies similar to control trials. This was true even when the second perturbation occurred 10–20 ms after the first, that is, when this perturbation either preceded or was coincident with the response to the initial limb drop. The EMG responses that were normally associated with the second perturbation were delayed and/or reduced in amplitude when the time interval between perturbations was short. As the inter-perturbation interval was lengthened beyond 60–100 ms, however, EMG responses to the second perturbation were unaffected by the occurrence of the first perturbation. When the hindlimb containing the recording electrodes was dropped as part of the second perturbation, a myotatic latency response was observed in tibialis anterior. The amplitude of this response to the second perturbation was greater than controls when this displacement was presented during the period between initiation of the first perturbation and execution of the response to it. When the second displacement was presented after execution of the first response began, the amplitude of the myotatic response was reduced below control levels. While the results do not preclude the possibility that these “automatic” postural responses are segmental or suprasegmental reflexes, they support the hypothesis that the active component of the response to drop of the support beneath a single limb is centrally programmed and that the appropriate response can be riggered very rapidly by the somatosensory information signalling the perturbation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00249792

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6

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Automatic postural responses in the cat: responses of proximal and distal hindlimb muscles to drop of support from a single hind- or forelimb (1987)

Rushmer, D. S. ; Macpherson, J. M. ; Dunbar, D. C. ; [et al.]

Springer

Experimental brain research 65 (1987), S. 527-537

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ISSN: 1432-1106

Keywords: Postural reflexes ; Unexpected postural perturbations ; Electromyographic activity ; Hindlimb muscles ; Cat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Cats respond to drop of the support from beneath a single limb with the “diagonal stance response” (Coulmance et al. 1979). They load the limbs on the diagonal opposite to the one containing the dropped limb and unload the third supporting limb in the diagonal containing the dropped limb. Characteristic biomechanical delays in limb motion and in vertical force changes imposed upon the limbs are observed. These delays range from 30 to 45 ms, depending upon the location of the dropped limb. This study describes the kinematics of the “diagonal stance response” and the activation of selected agonist-antagonist muscle pairs acting on the joints of the hindlimb during the response. Proximal and distal hindlimb muscles respond to perturbations in groups that are appropriate to the vertical forces imposed upon the limb. When the hindlimb containing the recording electrodes is loaded by drop of the contralateral hindlimb or the ipsilateral forelimb medium latency (25–45 ms) EMG responses occur in the extensors. This response serves to stiffen the limb against the increased vertical force of loading. A similar response is observed when the hindlimb is reloaded after being dropped. In this case, however, short latency responses precede the medium latency responses in muscles that are passively stretched by the limb drop. When drop of the diagonal forelimb unloads the hindlimb containing the electrodes, medium latency responses are observed in the distal hindlimb flexors, which indicates that the unloading is evoked in part by active lifting of the limb. In most cases, the medium latency responses precede or are coincident with the changes in force imposed on the limb, suggesting that the observed responses are centrally programmed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00235976

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7

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Stance dependence of automatic postural adjustments in humans (1989)

Macpherson, J. M. ; Horak, F. B. ; Dunbar, D. C. ; [et al.]

Springer

Experimental brain research 78 (1989), S. 557-566

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ISSN: 1432-1106

Keywords: Posture and stance ; Biped ; Quadruped ; EMG ; Human

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary This study investigated the effect of initial stance configuration on automatic postural responses in humans. Subjects were tested in both bipedal and quadrupedal stance postures. The postural responses to horizontal translations of the supporting surface were measured in terms of the forces at the ground, movement of the body segments, and electromyographic (EMG) activity. Postural responses to the same perturbations changed with initial stance posture; these responses were biomechanically appropriate for restoring centre of mass. A change in stance configuration prior to platform movement led to a change in both the spatial and temporal organization of evoked muscle activation. Specifically, for the same direction of platform movement, during bipedal stance muscles on one side of the lower limb were activated in a distal to proximal sequence; during quadrupedal stance, muscles on the opposite side of the lower limb were activated and in a proximal to distal sequence. The most significant finding was an asymmetry in the use of the upper limbs and the lower limbs during postural corrections in quadrupedal stance. Whereas antagonists of the upper limb were either co-activated or co-inhibited, depending on the direction of translation, lower limb antagonists were reciprocally activated and inhibited. Human subjects in a quadrupedal stance posture used the lower limbs as levers, protracting or retracting the hips in order to propel the trunk back to its original position with respect to the hands and feet. Postural responses of the subjects during quadrupedal stance were remarkably similar to those of cats subjected to similar perturbations of the supporting surface. Furthermore, the same predominance of lower limb correction is characteristic of both species, suggesting that the standing cat is a good model for studying postural control in humans.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00230243

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