Journal of the neurological sciences
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Review
Hypothermia for neuroprotection after cardiac arrest: mechanisms, clinical trials and patient care.
Therapeutic hypothermia is a proven part of cardio-cerebral resuscitation after cardiac arrest as it improves neurologic outcomes after hypoxic brain injury. This article reviews the mechanisms of hypothermic neuroprotection, the clinical trials that support its use after cardiac arrest, as well as the impact of hypothermia on patient management and prognosis. In caring for patients suffering hypoxic brain injury after cardiac arrest, the role of the neurologist is no longer limited to prognosis but is now to become actively involved in clinical management which includes the use of therapeutic hypothermia.
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Outcome after aSAH depends on several factors, including the severity of the initial event, perioperative medical management, surgical variables, and the incidence of complications. Cerebral vasospasm (CV) is ure to consistently respond to treatment, emphasizing the need for further research into the underlying mechanisms of SAH-induced cerebrovascular dysfunction. ⋯ Current management of this condition consists of maximal medical therapy, including triple H regimen and oral administration of calcium antagonists, followed by endovascular balloon angioplasty and/or injection of vasodilatory agents for refractory cases. As the precise pathophysiology of CV is further elucidated, the development of promising investigational therapies will follow.
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In the neurointensive care unit, neurologic monitoring is depended upon to signal the onset of neurologic decline. Many monitoring techniques such as intracranial pressure monitoring, cerebral perfusion pressure measurement, jugular venous oxygen saturation, transcranial Doppler ultrasound and continuous electroencephalogram are commonly practiced. ⋯ When used in combination, as in multimodal monitoring, the goal is to overcome some of the disadvantages of each technique and to achieve a higher degree of accuracy in detecting secondary brain insults. However, such a large amount of data can be generated that such combinations have to be chosen carefully, or the monitoring data will not be able to be acted upon quickly enough to be of benefit to the patient.
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In order to meet the needs of the high acuity population in today's critical care environment, the role of the Acute Care Nurse practitioner (ACNP) has been adopted by many intensive care units (ICU's) across the country, including specialized neurocritical care units. In this chapter we will provide a brief historical review of the ACNP as well as their function in various ICU settings. Lastly, we will describe the current role of the ACNP in the Neurosciences Critical Care Unit at the Johns Hopkins Hospital as well as future plans and challenges of the role.
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Hypothermia has recently been shown to be beneficial in certain clinical settings of acute brain injury, such as cardiac arrest. The available technology to induce and maintain this state is advancing quickly. This review will focus on the current state of available technology and devices as well as their limitations in attaining this potentially neuroprotective state. Furthermore, we will present the efficacy of the individual systems as well as potential side effects and complications that are associated with the technology chosen.