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Autonomic dysreflexia following high level spinal cord injury: time course, mechanisms and possible intervention.

Following cervical or upper thoracic level spinal cord injury (SCI), motor, sensory and autonomic systems are disrupted. One form of this autonomic dysfunction is the condition autonomic dysreflexia (AD), which is characterised by episodes of high blood pressure in response to afferent input from regions below the injury level. An animal model of autonomic dysreflexia, the T4 transected rat, was used in this thesis to gain insight into the cardiovascular and temperature components of the disorder, possible peripheral mechanisms and interventions to prevent its development. Chapter 2 of the thesis includes the charaterisation of a T4 transection rat model of spinal cord injury. This characterisation includes confirmation of decreased baseline mean arterial pressure (MAP, 71 down from 117 mmHg) and elevated heart rate (HR, 431 bpm from 366 bpm) for 6 weeks post injury (p.i.). Documentation of the development of AD found that hypertensive responses were fully developed (+20 mmHg) by 4 weeks p.i. Further, during episodes of AD at Weeks 4 and 5 p.i., tail surface temperatures decreased significantly (mid-tail, -1.7oC), indicative of extensive vasoconstriction. Comparison of vascular responses of intact and SCI animals to adrenergic agonists (phenylephrine, PHE and methoxamine, METH) following ganglionic blockade in vivo found that SCI animals experienced prolonged vasoconstriction in blood vessels above and below injury level in response to PHE but not METH. Possible mechanisms of this change included decreased neuronal reuptake of PHE (METH is not a substrate for neuronal reuptake). The presence of prolonged vasoconstriction in blood vessels throughout the body, not just regions below injury level, suggests a widespread mechanism for the change, such as the decreased basal MAP, norepinephrine levels or neural activity present following injury. Thus, it was hypothesised that increased activity from an early stage post injury may prevent the peripheral adaptation and perhaps hinder development of AD. For this, the common rehabilitation technique, treadmill training, was used. Surprisingly, rather than preventing AD, the training actually accelerated its development, producing exaggerated hypertensive responses to colorectal distension (CRD) at Weeks 3 and 4 post-injury (Week 4, Trained: +38.5 ?? 1.5 mmHg; Sedentary: 23.4 ?? 3.1mmHg). Comparison of vascular responses of both groups to PHE injection found no significant difference indicating that the enhanced responses were not a result of peripheral vascular changes. Investigation of the central morphology following SCI, made via immunohistochemical processing of the post-mortem spinal cords, found that Treadmill Trained SCI animals had elevated calcitonin gene related peptide (CGRP) immunoreactivity within lamina III/IV of lumbar segments, compared to intact cords. It is possible that this finding indicates afferent sprouting that may have accelerated the development of AD in Treadmill Trained animals. The results within this thesis highlight the importance of awareness and examination of autonomic function in SCI patients, especially those undergoing rehabilitative training.

Identiferoai:union.ndltd.org:ADTP/212636
Date January 2007
CreatorsLaird, Angela S, Medical Sciences, Faculty of Medicine, UNSW
PublisherAwarded by:University of New South Wales. School of Medical Sciences
Source SetsAustraliasian Digital Theses Program
LanguageEnglish
Detected LanguageEnglish
RightsCopyright Angela S Laird, http://unsworks.unsw.edu.au/copyright

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