Pain (nociceptive) input soon after spinal cord injury (SCI) expands the area of tissue loss (secondary injury) and impairs long-term recovery. Evidence suggests that nociceptive stimulation has this effect because it promotes acute hemorrhage. Disrupting communication with the brain blocks this effect. The current study examined whether rostral systems exacerbate tissue loss because pain input drives an increase in systolic blood pressure (BP) and flow that fuels blood infiltration. Rats received a moderate contusion injury to the lower thoracic (T12) spinal cord. Communication with rostral processes was disrupted by cutting the spinal cord 18 h later at T2. Noxious electrical stimulation (shock) applied to the tail (Experiment 1), or application of the irritant capsaicin to one hind paw (Experiment 2), increased hemorrhage at the site of injury. Shock, but not capsaicin, increased systolic BP and tail blood flow in sham-operated rats. Cutting communication with the brain blocked the shock-induced increase in systolic BP and tail blood flow. Experiment 3 examined the effect of artificially driving a rise in BP with norepinephrine (NE) in animals that received shock. Spinal transection attenuated hemorrhage in vehicle-treated rats. Treatment with NE drove a robust increase in BP and tail blood flow but did not increase the extent of hemorrhage. The results suggest pain input after SCI can engage rostral processes that fuel hemorrhage and drive sustained cardiovascular output. An increase in BP was not, however, necessary or sufficient to drive hemorrhage, implicating other brain-dependent processes.
The authors discuss about a patient who, while undergoing a routine procedure to drain a subcutaneous abscess within his forehead, suffered cardiac arrest that we conclude was caused by an activation of the diving response. This reflex affects homeostatic function which alters respiration and preferentially distributes oxygen stores to the heart and brain. Under some conditions, however, this reflex can also trigger cardiovascular collapse and death. The diving reflex is can begin with triggering receptors that are sensitive to cold water, submersion, or pressure within the nasal cavity and other areas supplied by the trigeminal nerve. Studies have shown that this afferent response primarily involves branches of the infraorbital nerve and the anterior ethmoidal nerve. However, other more superior nerves such as those exclusive to the forehead region may also be involved. This study demonstrates for the first time the risks and dangers involved in surgical procedures or manipulation of the trigeminal innervated areas of the human face and in particular the forehead.
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