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Query: UMLS:C0020672 (
hypothermia
)
17,327
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
1 The
hypothermia
produced by intraventricular injections of thyrotropin releasing hormone (TRH) in unanaesthetized cats has been investigated. 2 TRH is more potent than either noradrenaline or calcium ions. It is estimated that the equi-potent molar ratio for TRH: noradrenaline:calcium is 1:900:27,000. 3 TRH injections is also produce profuse salivation, tachypnoea, cutaneous vasodilatation and frequently defaecation and vomiting. It is considered that the increased respiration is a major cause of the
hypothermia
. 4 Prior administration of phentolamine antagonized noradrenaline-induced
hypothermia
but did not affect
hypothermia
produced by TRH or calcium ions. Pretreatment with alpha-methyltyrosine did not affect the
hypothermia
induced by TRH, calcium ions or noradrenaline. 5 The calcium antagonists verapamil and xylocaine did not antagonize
hypothermia
induced by an injection of calcium ions. 6 The constituent amino acids of TRH did not produce
hypothermia
either individually or collectively.
Thyroxine sodium
produced a rise in temperature that was slow in onset, consistent with its known metabolic effects. TSH produced a small
hypothermia
unrelated to dose.
...
PMID:A comparison between the hypothermia induced by intra-ventricular injections of thyrotropin releasing hormone, noradrenaline or calcium ions in unanaesthetized cats. 82 97
In a recent
Letter
to the Editor, Clarke, et al, indicated that divers who deliberately chill themselves on a dive to reduce risk of decompression sickness (DCS) may be misinterpreting our 2007 Navy Experimental Diving Unit (NEDU) report. Indeed, we did not advocate that divers should risk
hypothermia
on bottom to reduce risk of DCS, nor do we dispute the authors' overall admonition to avoid diving cold unnecessarily. However, Clarke, et al, imply more generally that results of our study are not applicable to recreational or technical divers because the dives we tested were atypical of dives undertaken by such divers. We wish to clarify that our study does have implications for recreational and technical divers, implications that should not be ignored. The dives we tested were not intended to be typical of dives undertaken in any actual operational context. Instead, we chose to expose divers to temperatures at the extremes of their thermal tolerance in order to ensure that effects of diver thermal status on DCS susceptibility would be found if such effects existed. Our initial test dive profile provided appreciable time both on bottom and during decompression to allow any differential thermal effects during these two dive phases to manifest, while affording a baseline risk of DCS that could be altered by thermal effects without exposing subjects to inordinately high risks of DCS. Our results strongly indicate that the optimal diver thermal conditions for mitigation of DCS risk or minimization of decompression time entail remaining cool during gas uptake phases of a dive and warm during off-gassing phases. While the dose-response characteristics of our observed thermal effects are almost certainly non-linear in both exposure temperature and duration, it is only reasonable to presume that the effects vary monotonically with these factors. We have no reason to presume that such responses and effects under less extreme conditions would be in directions opposite to those found under the conditions we tested. Similarly, responses to thermal exposures even more extreme than we tested might not be larger than the responses we observed, but it would be unwise to ignore the trends in our results under some unfounded presumption that the effects reverse with changes in thermal conditions beyond those tested. Finally, thermal effects on bottom and during decompression in dives to depths other than the 120 feet of sea water (fsw) or 150 fsw depths of the dives we tested are unlikely to be qualitatively different from those observed in our tested dives. The original question has therefore been answered: chill on bottom decreases DCS susceptibility while chill during decompression increases DCS susceptibility. Under conditions encountered by recreational or technical divers, the only open issue is arguably magnitudes of effects, not directions. Neither does lack of technology to control thermal status during a dive render our study results inapplicable. It only renders the diver unable to actively optimize his or her thermal exposure to minimize DCS risk or decompression obligation. Effects of diver thermal status on bottom hold regardless of whether the dive has a decompression long enough for a thermal effect to manifest in the decompression phase of the dive. We pointed out that US Navy decompression tables have historically been developed and validated with test dives in which divers were cold and working during bottom phases and cold and resting during decompression phases. Thus, our results indicate that it is not prudent for very warm divers to challenge the US Navy no-stop limits. However, becoming deliberately chilled on bottom only to remain cold during any ensuing decompression stops is similarly ill-advised. We agree with Clarke et al. that relative conservatism of some dive computer algorithms or alternative decompression tables, or the depth and time roundups necessary to determine table-based prescriptions, work in the diver's favour, but note that diving any profile to a shorter bottom time is a ready means to reduce the risk of DCS - i.e., enhance safety - without compromising comfort. Any active diver heating is best limited while on bottom to a minimal level required to safely complete on-bottom tasks, and dialled up only during decompression. Diver warming during decompression should not be so aggressive as to risk heat stress, and care should be taken to ensure that divers remain hydrated.
...
PMID:On diver thermal status and susceptibility to decompression sickness. 2596 43
Automated health monitoring and alert system development is a demanding research area today. Most of the currently available monitoring and controlling medical devices are wired which limits freeness of working environment. Wireless sensor network (WSN) is a better alternative in such an environment. Neonatal intensive care unit is used to take care of sick and premature neonates.
Hypothermia
is an independent risk factor for neonatal mortality and morbidity. To prevent it an automated monitoring system is required. In this
Letter
, an automated neonatal health monitoring system is designed using sensor mobile cloud computing (SMCC). SMCC is based on WSN and MCC. In the authors' system temperature sensor, acceleration sensor and heart rate measurement sensor are used to monitor body temperature, acceleration due to body movement and heart rate of neonates. The sensor data are stored inside the cloud. The health person continuously monitors and accesses these data through the mobile device using an Android Application for neonatal monitoring. When an abnormal situation arises, an alert is generated in the mobile device of the health person. By alerting health professional using such an automated system, early care is provided to the affected babies and the probability of recovery is increased.
...
PMID:Design of smart neonatal health monitoring system using SMCC. 2826 91
