View clinical trials related to Hypothermia.
Filter by:Hypothermia during surgery and in the postoperative period is associated with adverse outcomes including impaired drug metabolism, cardiac morbidity, shivering, impaired immune function, coagulopathy, and increased use of hospital resources. Several clinical studies have demonstrated that maintenance of normothermia during the perioperative period significantly reduces morbidity. Mercury Biomed has developed a patient-warming system, WarmSmart, that potentially transfers adequate heat through hands and feet based on the physiological principle of peripheral arterio-venous shunt vaso-dilation. The technology works as a two-step process by selective thermal stimulation along the spinal cord to up-regulate blood flow to arterio-venous shunts and triggering arterio-venous shunt vasodilation and by applying circulating water heat exchangers to the palmar and plantar glabrous skin to warm highly perfused shunts in that area. General anesthesia reduces the vasoconstriction threshold (triggering core temperature) by 1-2°C, thus promoting arteriovenous shunt dilation. It remains unknown, though, whether cervical spine warming further augments arterio-venous shunt dilation during general anesthesia. If spine heating proves unnecessary under anesthesia, Mercury Biomed's WarmSmart warming could be simpler and less expensive. Investigators therefore propose to test the hypothesis that cutaneous heating near the cervical spine does not further augment arterio-venous flow in fingers during general anesthesia. Investigators propose to enroll ten patients. The patients will be pre-warmed and warmed intraoperatively with forced-air to maintain a core temperature near 36°C. A ThermaZone® Device capable of heating the cervical spine area will be positioned behind the patient's neck upon arrival in the operating rooms. Additionally a forced-air warmer will be positioned appropriately and activated as soon as practical, usually after prepping and draping. Ambient temperature will be maintained near 20°C. After about one hour of anesthesia when temperature and other factors are stable, investigators will start a 30-minute observation period. Thereafter investigators will activate the cervical spine warming system for 30 minutes (warming measurement period) and thereafter have a 30 minutes control period again. Measurements will be recorded such as mean-skin temperature, distal esophageal temperature, MAC fraction, mean-arterial pressure and finger blood flow.
This study examines the effect of cord blood in the treatment of newborn infants with neonatal encephalopathy in combination with hypothermia, which is the standard treatment for this condition. The hypothesis is that the cord blood + hypothermia combination will produce better neuroprotection than the standard treatment of hypothermia alone.
The purpose of this study is to determine whether mild hypothermia causes reduction of vasoconstriction in microcirculation after clipping of aneurysms, and affects the blood flow in small diameter arteries at operating site (ischemia-hyperemia) and occurrence of vasospasms during the period of 14 postoperative days measured by transcranial Doppler.
The purpose of this study is to determine whether reducing a patient's body temperature (mild hypothermia of 33 degrees Centigrade) will significantly reduce the risk of brain injury (notably reperfusion injury and hemorrhagic conversion) in patients who have suffered a significant interruption of blood flow to an area of brain (occlusion of large proximal cerebral artery) and have undergone successful removal of that interruption (revascularization).This will be achieved by comparing patients who have undergone hypothermia to those who have not.
The study is a comparison of a patient warming system using a forced-air, non-compressible under-body mattress (Möck & Möck, Hamburg, Germany) versus a regular forced-air underbody mattress system during pediatric cardiac catheterization in 40 patients. The hypothesis is, that the non-compressible mattress provides better warming with less incidence of perioperative hypothermia (Core temperature < 36 °C) and faster warming slope (°C / time). The study is prospective, randomized, controlled and single-blinded. Inclusion criteria will be pediatric patients < 1 year of age without fever or a treatment of therapeutic hypothermia.
Background: Acute pancreatitis is characterized by a high mortality rate (10%-15%), and a remarkably unpredictable clinical course. Approximately 50% of deaths in acute pancreatitis occur early—within the first 14 days—and early mortality is attributable to sequelae of a severe systemic inflammatory response syndrome (SIRS), which is associated with multi-organ dysfunction syndrome (MODS) that can escalate to renal failure, respiratory failure, and death. Significant improvements in acute pancreatitis mortality will demand innovative approaches to counteract early organ failure. A series of destructive cellular processes begins within minutes of initial pancreatic injury, and the ensuing inflammatory cascade is compounded by disease sequelae including edema, ischemia, and tissue necrosis. Early interventions to reduce inflammation within the first 36 hours have been shown to have significant effects in minimizing progressive organ dysfunction. Hypothermia is clinically employed to combat cellular injury and systemic responses following ischemia-reperfusion, and is been studied as a mechanism of acute inflammatory inhibition in processes including cardiogenic shock, lung injury, local intestinal injury, and reperfusion injuries to the lung, liver, and endothelium. In numerous studies, effective immunomodulations have been observed including reduction of pro-inflammatory cytokines (TNF-α, IL-6), stimulation of anti-inflammatory cytokines (IL-10), inhibition of pro-apoptotic JNK signaling, reduction of systemic oxidative stress, and inhibition of neutrophils, monocytes, and monocyte-derived macrophages. Most saliently, in the caerulein model of murine acute pancreatitis, therapeutic hypothermia has been shown to reduce serum IL-1, IL-6, and TNF-α, increased serum IL-10, decrease serum amylase and lipase, lower the histological grade of pancreatic injury as compared to normothermic mice, and significant survival benefit. Although therapeutic hypothermia is actively employed in the treatment of traumatic brain injury, neonatal asphyxia, spinal cord injury, and cardiac arrest, no studies have yet been made of its application to acute pancreatitis. Hypothesis: Patients treated with therapeutic hypothermia (32-34°C) will sustain reduced organ-specific injury in acute pancreatitis. Proposal: In a Phase IIa pilot clinical trial, we will examine the effects of therapeutic hypothermia on organ-specific outcomes during the early stage of acute pancreatitis. We will recruit five patients aged 18 to 80 receiving medically-necessitated ventilator support under ICU monitoring with core temperatures ≥36°C and severe acute pancreatitis defined as either a Ranson Score ≥7, a CT indicating ≥50% pancreatic necrosis, or a significant deterioration in clinical status including dysfunction of two or more organ systems (defined by ACCP/SCCM Organ Failure Guidelines, Chest 2009). All patients will receive current standard management for severe acute pancreatitis and a standardized protocol for application of therapeutic hypothermia and rewarming. Our primary endpoints are organ-specific cardiovascular, respiratory, hematological, renal, and metabolic dysfunction as measured at 28 days. Logistic Organ Dysfunction Scores (LOD) will be compared before and after therapeutic hypothermia, establishing day 4 versus day 1 changes in LOD. Secondary endpoints include D-dimer, IL-6, C-reactive protein, APACHE II scores on day 1 and day 4, inpatient and ICU length-of-stay, infection, mortality, and hypothermia-associated side effects including cardiac arrhythmia, electrolyte imbalance, hyperglycemia, major bleeding, and acute pancreatitis. We believe that such a study will supply preliminary answers to our chief research questions: does therapeutic hypothermia reduce morbidity as assessed by organ-specific outcomes, does therapeutic hypothermia attenuate the steep rise in inflammation observed in severe acute pancreatitis, and does therapeutic hypothermia shorten the clinical course for these patients.
The purpose of this study is to determine whether reducing a patients body temperature (mild hypothermia of 33 degrees Centigrade) will significantly reduce the risk of brain injury (notably reperfusion injury and hemorrhagic conversion) in patients that have suffered a significant interruption of blood flow to an area of brain (occlusion of large proximal cerebral artery) and have undergone successful removal of that interruption (revascularization).This will be achieved by comparing patients that have undergone hypothermia to those that have not.
Newborn infants with severe respiratory failure are treated with extracorporeal membrane oxygenation (ECMO), a modified form of cardiopulmonary bypass. These infants as at risk for brain injury as a result of hypoxia and blood flow changes in the brain prior to and during ECMO. The investigators propose a clinical trial of a novel treatment (cooling during ECMO) and novel diagnostic tool (advanced MRI techniques) that will lead to improved outcomes, early diagnosis and intervention for brain injury, decreased cost and duration of clinical trials, decrease in the burden of chronic neurologic disease and disability in society, thus improving the health and quality of life of these infants as they progress through childhood into adulthood.
The overall hypothesis is that plastic bags used in combination with WHO thermoregulation care will reduce the incidence of hypothermia in preterm/low birth weight and full term infants when compared to routine WHO thermoregulation care alone. Part III is for preterm/low birth weight infants with or without a plastic torso wrap during the first hour after birth to assist with temperature regulation during placement in an incubator.
The overall hypothesis is that plastic bags used in combination with WHO thermoregulation care will reduce the incidence of hypothermia in preterm/low birth weight and full term infants when compared to routine WHO thermoregulation care alone. Part II is for preterm/low birth weight infant with or without plastic head cover used from 1 hour after birth until discharge or 24 hours after birth to assist with temperature regulation.