Physiological Impact of Hypothermia: The Good, the Bad, and the Ugly

Tveita, Torkjel; Sieck, Gary C.

doi:10.1152/physiol.00025.2021

Cited by 20 publications

(18 citation statements)

References 215 publications

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“…For the surgical treatment of complex heart abnormalities, due to the complicated operation, the large trauma to the patient, the long cardiopulmonary bypass time, and the need to maintain a long-term deep hypothermia state, the damage to the brain is relatively severe. One-third of children with complex congenital (116)(117)(118). Studies have reported that the incidence of epilepsy after surgery for children with congenital heart abnormalities is 4% to 10%, and the incidence of epilepsy after surgery for complex congenital heart abnormalities is even higher (113).…”

Section: Interventions For Congenital Heart Abnormalities and Brain D...mentioning

confidence: 99%

“…Deep hypothermic circulatory arrest is commonly used in open heart surgery for complex congenital heart abnormalities. In the state of deep hypothermic circulatory arrest, the energy metabolism of the brain is depleted, causing brain damage through mechanisms such as calcium overload and excitatory amino acid toxicity ( 116 – 118 ). Studies have reported that the incidence of epilepsy after surgery for children with congenital heart abnormalities is 4% to 10%, and the incidence of epilepsy after surgery for complex congenital heart abnormalities is even higher ( 113 ).…”

Section: Interventions For Congenital Heart Abnormalities and Brain D...mentioning

confidence: 99%

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Heart-brain axis: Association of congenital heart abnormality and brain diseases

Sha

Li²,

Zhang³

et al. 2023

Front. Cardiovasc. Med.

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Brain diseases are a major burden on human health worldwide, and little is known about how most brain diseases develop. It is believed that cardiovascular diseases can affect the function of the brain, and many brain diseases are associated with heart dysfunction, which is called the heart-brain axis. Congenital heart abnormalities with anomalous hemodynamics are common treatable cardiovascular diseases. With the development of cardiovascular surgeries and interventions, the long-term survival of patients with congenital heart abnormalities continues to improve. However, physicians have reported that patients with congenital heart abnormalities have an increased risk of brain diseases in adulthood. To understand the complex association between congenital heart abnormalities and brain diseases, the paper reviews relevant clinical literature. Studies have shown that congenital heart abnormalities are associated with most brain diseases, including stroke, migraine, dementia, infection of the central nervous system, epilepsy, white matter lesions, and affective disorders. However, whether surgeries or other interventions could benefit patients with congenital heart abnormalities and brain diseases remains unclear because of limited evidence.

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Section: Interventions For Congenital Heart Abnormalities and Brain D...mentioning

confidence: 99%

Section: Interventions For Congenital Heart Abnormalities and Brain D...mentioning

confidence: 99%

Heart-brain axis: Association of congenital heart abnormality and brain diseases

Sha

Li²,

Zhang³

et al. 2023

Front. Cardiovasc. Med.

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“…Our aim is to update the readers on physiological changes occurring in various organ systems, as a knowledge basis for rewarming victims of AH and HCA. Although the topic recently was reviewed by one of us, the different emphasis should make this paper be considered as complementary ( 22 ).…”

Section: Introductionmentioning

confidence: 99%

Physiological Changes in Subjects Exposed to Accidental Hypothermia: An Update

et al. 2022

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BackgroundAccidental hypothermia (AH) is an unintended decrease in body core temperature (BCT) to below 35°C. We present an update on physiological/pathophysiological changes associated with AH and rewarming from hypothermic cardiac arrest (HCA).Temperature Regulation and MetabolismTriggered by falling skin temperature, Thyrotropin-Releasing Hormone (TRH) from hypothalamus induces release of Thyroid-Stimulating Hormone (TSH) and Prolactin from pituitary gland anterior lobe that stimulate thyroid generation of triiodothyronine and thyroxine (T4). The latter act together with noradrenaline to induce heat production by binding to adrenergic β3-receptors in fat cells. Exposed to cold, noradrenaline prompts degradation of triglycerides from brown adipose tissue (BAT) into free fatty acids that uncouple metabolism to heat production, rather than generating adenosine triphosphate. If BAT is lacking, AH occurs more readily.Cardiac OutputAssuming a 7% drop in metabolism per °C, a BCT decrease of 10°C can reduce metabolism by 70% paralleled by a corresponding decline in CO. Consequently, it is possible to maintain adequate oxygen delivery provided correctly performed cardiopulmonary resuscitation (CPR), which might result in approximately 30% of CO generated at normal BCT.Liver and CoagulationAH promotes coagulation disturbances following trauma and acidosis by reducing coagulation and platelet functions. Mean prothrombin and partial thromboplastin times might increase by 40–60% in moderate hypothermia. Rewarming might release tissue factor from damaged tissues, that triggers disseminated intravascular coagulation. Hypothermia might inhibit platelet aggregation and coagulation.KidneysRenal blood flow decreases due to vasoconstriction of afferent arterioles, electrolyte and fluid disturbances and increasing blood viscosity. Severely deranged renal function occurs particularly in the presence of rhabdomyolysis induced by severe AH combined with trauma.ConclusionMetabolism drops 7% per °C fall in BCT, reducing CO correspondingly. Therefore, it is possible to maintain adequate oxygen delivery after 10°C drop in BCT provided correctly performed CPR. Hypothermia may facilitate rhabdomyolysis in traumatized patients. Victims suspected of HCA should be rewarmed before being pronounced dead. Rewarming avalanche victims of HCA with serum potassium > 12 mmol/L and a burial time >30 min with no air pocket, most probably be futile.

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“…However, currently used hypothermia triggered by peripheral cold sensors is ineffective in lowering the core body temperature ( T core ) to the desired level 13 , 15 . The cooling process also evokes vigorous counteractive shivering thermogenesis that is difficult to tolerate in awake patients 16 , 17 , and produces harmful side effects to the heart, lungs, and brain 9 . A better method to induce therapeutic hypothermia is urgently needed.…”

Section: Introductionmentioning

confidence: 99%

“…The molecular cascades that set in after cerebral ischaemia are complex [2][3][4][5] , which hamper the development of neuroprotective therapies. Hypothermia at mild to moderate levels (31-34 °C) during or following cerebral ischaemia is powerful neuroprotective [6][7][8][9][10][11][12] . Hypothermia can simultaneously inhibit multiple mechanisms of brain cell death and slow down metabolic processes to limit tissue damage 10,13,14 , providing additive or synergistic beneficial clinical effects for stroke patients.…”

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confidence: 99%

Hypothermia evoked by stimulation of medial preoptic nucleus protects the brain in a mouse model of ischaemia

Zhang

Zhong

et al. 2022

Nat Commun

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Therapeutic hypothermia at 32-34 °C during or after cerebral ischaemia is neuroprotective. However, peripheral cold sensor-triggered hypothermia is ineffective and evokes vigorous counteractive shivering thermogenesis and complications that are difficult to tolerate in awake patients. Here, we show in mice that deep brain stimulation (DBS) of warm-sensitive neurones (WSNs) in the medial preoptic nucleus (MPN) produces tolerable hypothermia. In contrast to surface cooling-evoked hypothermia, DBS mice exhibit a torpor-like state without counteractive shivering. Like hypothermia evoked by chemogenetic activation of WSNs, DBS in free-moving mice elicits a rapid lowering of the core body temperature to 32-34 °C, which confers significant brain protection and motor function reservation. Mechanistically, activation of WSNs contributes to DBS-evoked hypothermia. Inhibition of WSNs prevents DBS-evoked hypothermia. Maintaining the core body temperature at normothermia during DBS abolishes DBS-mediated brain protection. Thus, the MPN is a DBS target to evoke tolerable therapeutic hypothermia for stroke treatment.

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Physiological Impact of Hypothermia: The Good, the Bad, and the Ugly

Cited by 20 publications

References 215 publications

Heart-brain axis: Association of congenital heart abnormality and brain diseases

Heart-brain axis: Association of congenital heart abnormality and brain diseases

Physiological Changes in Subjects Exposed to Accidental Hypothermia: An Update

Hypothermia evoked by stimulation of medial preoptic nucleus protects the brain in a mouse model of ischaemia

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