Reducing Human Biceps Brachii Spinal Stretch Reflex Magnitude.
WOLF, STEVEN L. AND RICHARD L. SEGAL.
Departments of Rehabilitation Medicine and Anatomy and Cell Biology, Emory
University School of Medicine, Atlanta, GA 30322 USA.
APStracts 2:0311N, 1995.
SUMMARY AND CONCLUSIONS
1. Nine subjects received 6 baseline and 24 training sessions, each consisting
of 250 elbow joint stretch perturbations into extension. The training sessions
were designed to reduce their biceps brachii spinal stretch reflexes (SSR).
Changes in longer latency responses and short latency brachioradialis
responses were also monitored. Background EMG activity was recorded from the
lateral head of triceps brachii during the biceps sampling intervals. These
data were compared to 12 control subjects who received equal numbers of
stretches over an extended baseline (i.e., without application of a training
paradigm). 2. Training subjects reduced their mean biceps SSR responses by 24%
while control subjects increased their responses by 12%. When changes in
activity were grouped by sets of 6 consecutive sessions following the baseline
interval, a group by time interaction was observed. Training subjects showed
significant reductions from baseline after the first training set. The
increased magnitude of biceps SSR for control subjects was significantly
larger than baseline in sets 2-5. After the first training interval, all
subsequent differences between groups were statistically significant. 3. The
brachioradialis showed greater response variability, but these responses
paralleled those seen in biceps brachii. The training group reduced their
brachioradialis responses by 18% while the control group increased their
response by 12%. Background activity recorded over the lateral head of triceps
brachii during the biceps brachii SSR window became smaller in both groups. 4.
Comparison of data between control subjects and subjects who had undergone
biceps SSR up-training in previous studies, suggests that the small increase
seen among the present control subjects was probably not the result of a
direct training effect. 5. Baseline differences in longer latency response
onset time was seen between groups. Over extended baseline sessions longer
latency responses showed only a 1% later onset, representing a .3 msec change,
in the control group. A 1.3% later onset, equaling a 1.1 msec change, was
observed over conditioning sessions in the training group. When analyzed by
sets following baseline, neither group showed significant within or between
group changes over time. 6. The magnitude of the longer latency biceps brachii
responses showed 7% and 37% reductions for the control and training groups,
respectively. No difference in set averages were seen within groups, but a
significant difference was measured over sets 2-4 between groups. Reductions
in the magnitude of longer latency responses in training subjects were more
obvious in later training sessions. 7. These data suggest that: 1) the biceps
brachii SSR can be reduced in human subjects; 2) concurrent changes are often
observed in the synergist brachioradialis; and 3) the reduced biceps SSR
magnitude is not linked to a compensatory increase in antagonist muscle
activity. Reductions in the magnitude of longer latency biceps brachii
activity seen in parallel with the decreased SSR may imply that some degree of
supraspinal processing is required to achieve this task.
Received 27 April 1995; accepted in final form 24 October 1995.
APS Manuscript Number J284-5.
Article publication pending J. Neurophysiol.
ISSN 1080-4757 Copyright 1995 The American Physiological Society.
Published in APStracts on 6 November 95