Study Effects of Intermittent Hypoxia on Restoring Hand Function Following SCI

Spinal Cord Injury

spinal cord injury, low oxygen, strength, motor control

The goal of the study is to examine the effects of repeated breathing episodes of mild intermittent hypoxia (reduced oxygen) training on hand strength and grasping ability following cervical spinal injury, and to determine whether these changes result in improved hand function. If so, such changes may indicate hypoxia-induced spinal plasticity (ability of the nervous system to strengthen neural pathways based on new experiences), which could result in improvements in hand use for persons with spinal cord injury (SCI).

The goal of the study is to examine the effects of repeated breathing episodes of mild intermittent hypoxia (reduced oxygen) training on hand strength and grasping ability following cervical spinal injury, and to determine whether these changes result in improved hand function. If so, such changes may indicate hypoxia-induced spinal plasticity (ability of the nervous system to strengthen neural pathways based on new experiences), which could result in improvements in hand use for persons with spinal cord injury (SCI). This idea stems from animal studies on respiration, in which investigators have shown that intermittent hypoxia induces spinal plasticity, strengthening neural connections within the spinal cord by a mechanism known as respiratory long-term facilitation. Exposure to mild hypoxia triggers oxygen sensors in the nervous system resulting in a cascade of events, including increased production of key proteins and, increased sensitivity of spinal cord circuitry necessary for improved respiration. Because previous work using animal models has shown that similar events occur along non-respiratory pathways, the investigators propose to investigate whether a comparable dosing scheme of daily, mild intermittent hypoxia can positively affect upper limb function in persons with cervical SCI. First, the investigators hypothesize that daily exposure of intermittent hypoxia training (7 consecutive days) will result in a sustained improvement in rat forelimb function that is dose-dependent. To test this hypothesis, the investigators will quantify the effects of variations in the number of intermittent hypoxia episodes on forelimb function in cervical spinal injured rats. Second, the investigators hypothesize that daily exposure of intermittent hypoxia training will improve hand function in persons with cervical spinal injury. To test this hypothesis, the investigators will quantify the effect of mild intermittent hypoxia exposure, using a protocol derived from the animal model, on volitional grip strength and grasp function in persons with cervical SCI. The effects of mild intermittent hypoxia, known to increase spinal motor activity, will be assessed as a possible therapeutic intervention to promote functionally useful hand recovery. Results from this study will be valuable for identifying novel strategies to control spinal neuron excitability and for improving motor function in persons with spinal cord injury.

United States