G C Elder
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Explore the profile of G C Elder including associated specialties, affiliations and a list of published articles.
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18
Citations
344
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Recent Articles
1.
Toner L, Cook K, Elder G
Dev Med Child Neurol
. 1999 Jan;
40(12):829-35.
PMID: 9881679
The effect of biofeedback training on ankle function was studied in young children with cerebral palsy (CP) during a pilot study and a 6-week follow-up study. Patients underwent range of...
2.
Elder G, Toner L
J Physiol
. 1998 Sep;
512 ( Pt 1):251-65.
PMID: 9729634
1. A slow postural muscle was tenotomized to determine the role of muscle stretch on chronic recruitment patterns in freely moving animals. 2. Different amounts of muscle shortening were induced...
3.
Elder G, Kakulas B
Muscle Nerve
. 1993 Nov;
16(11):1246-53.
PMID: 8413378
When the histochemical and contractile properties of infant muscles change postnatally, and what influence muscle function has on these changes, were the focus of this study. Contractile properties were measured...
4.
Blewett C, Elder G
J Appl Physiol (1985)
. 1993 May;
74(5):2057-66.
PMID: 8335530
Activity levels in rat soleus (SOL) and plantaris (PL) were quantitated electromyographically during control (6 days), hindlimb suspension (HS, 28 days), and recovery (6 days). The number and amplitude of...
5.
Megeney L, Neufer P, Dohm G, Tan M, Blewett C, Elder G, et al.
Am J Physiol
. 1993 Apr;
264(4 Pt 1):E583-93.
PMID: 8476037
We examined glucose uptake and GLUT-4 in rat muscles [soleus (Sol), plantaris (PL), extensor digitorum longus (EDL), tibialis anterior, and the red and white gastrocnemius (WG)]. In the normally innervated...
6.
Elder G
Muscle Nerve
. 1992 Jun;
15(6):672-7.
PMID: 1508231
The objective of this study was to determine whether increased contractile activity is beneficial or detrimental to developing dystrophic muscle. Hamsters (20-days-old) were gradually introduced to running at a speed...
7.
Megeney L, Elder G, Tan M, Bonen A
Am J Physiol
. 1992 Jan;
262(1 Pt 1):E20-6.
PMID: 1733246
Changes in blood flow and muscle glycogen in nonexercising muscle during exercise suggest that glucose transport may be increased in nonexercising muscles. Therefore, we compared 3-O-methyl-D-glucose (3-MG) transport in exercised...
8.
McDermott J, Elder G, Bonen A
Pflugers Arch
. 1991 May;
418(4):301-7.
PMID: 1876479
Glycogen decrements have been observed in non-exercising muscles during exercise. We therefore investigated whether the degraded glycogen was retained within the muscle in the form of glycolytic intermediates, or whether...
9.
Bonen A, Blewett C, McDermott J, Elder G
Can J Physiol Pharmacol
. 1990 Jul;
68(7):914-21.
PMID: 2383805
Nonexercising muscles appear to be metabolically active during exercise. Animal models for this purpose have not been established. However, we have been able to teach animals to run on their...
10.
Bonen A, Elder G, Tan M
J Appl Physiol (1985)
. 1988 Oct;
65(4):1833-9.
PMID: 3053588
After 28 days of hindlimb-suspension, insulin binding, 2-deoxy-D-glucose (2-DG) uptake, and glucose metabolism (glycolysis and glycogenesis) were determined at various insulin concentrations (0.2-30 nM) in soleus muscle of young (18-day-old)...