**5. Hypothermia in ischemic stroke**

Body temperature is increased in 4% to 25 % of patients with acute ischemic stroke within the rst six hours after symptom onset.[40] The pathophysiology of this increase in body temperature is not completely understood. Higher body temperature may be a natural consequence of brain infarction. However, animal studies have suggested that higher body temperatures may increase the damage induced by cerebral ischemia.[41] Observational studies in patients with acute stroke have established the influence of body temperature on the clinical outcome of stroke. For each 1 °C increase in body temperature, the relative risk of poor outcome worsens more than two times.[42] This association may be limited to the first 12 to 24 hours from stroke onset.[42] These studies therefore suggest that control of body temperature and fever prevention may improve functional outcome after stroke.

Therapeutic Hypothermia in Acute Stroke 55

0.6º C/h, and target temperature was reached after 3 +/- 1 h (range, 2 to 4.5 h). During hypothermia, the maximal temperature observed was 33.4º C, and the minimal temperature was 32.2º C. Every patient developed pneumonia and hypotension. This small study demonstrated that induction and maintenance of hypothermia with an intravenous cooling

Cooling for acute ischemic brain damage (COOL-AID), was one of the first studies to evaluate hypothermia in ischemic stroke after thrombolysis.[46] This was a nonrandomized study that used surface cooling to achieve a cooling temperature of 32 ± 1°C for 12 to 72-h. To prevent shivering, all patients undergoing hypothermia were intubated, sedated, and pharmacologically paralyzed. The study demonstrated that hypothermia is technically feasible and safe for patients with acute ischemic strokes who are undergoing thrombolytic therapy. However, the study was too small (10 patients) to

A later version of the same study, evaluated and intravascular cooling device in the treatment of stroke through the induction of hypothermia. The second COOL-AID was a randomized controlled study of 40 patients presenting within 12- h of symptom onset. Eighteen patients were cooled and 22 received standard medical management, which included thrombolysis in 13 patients. Shivering was suppressed using a forced-air warming blanket, buspirone and meperidine. Eight patients in the hypothermia group required intubation during their hospitalization, one patient was intubated during the maintenance phase of hypothermia and the other for various reasons not related to cooling. Most patients tolerated hypothermia, and clinical outcomes were similar in both groups although there was a trend of reduced lesion growth on diffusion-weighted imaging in the group treated with hypothermia.[47] Side effects included pneumonia, cardiac arrhythmia, and deep vein thrombosis. The main lessons from these two studies (COOL-AID one and two) were that mild hypothermia can be achieved in awake patients with the appropriate cooling and antishivering protocols; and that endovascular cooling achieves target temperature faster than

ICTuS is another nonrandomized clinical trial that cooled 18 acute stroke patients using an endovascular cooling device.[48] Patients were cooled within 12 hours of symptom onset. An anti-shivering regimen with buspirone and meperidine was administered prophylactically. Overall, patients tolerated cooling well and the incidence of cerebral hemorrhage did not increase among patients (n=5) who received intravenous (IV) tPA. This trial confirmed that endovascular cooling with a proactive anti-shivering regimen can be accomplished in awake stroke patients. A later brain CT analysis of patients who were effectively cooled (n=7) versus those who were not (n=11), suggested that endovascular hypothermia decreases acute post-ichemic cerebral edema. [49] At the end of the cooling and rewarming period (36–48 h), patients who were effectively cooled had signicantly decreased cerebral edema compared to patients who were either ineffectively cooled or not cooled at all. The effect disappeared by 30 days, as might be expected given the natural

device was feasible.

surface cooling.

course of post-infarction cerebral edema.

determine any solid conclusions.

In a systematic review of animal studies, therapeutic hypothermia reduced infarct size by 44% (95% condence interval 40 to 47%). The best results were obtained with lower temperatures (≤ 31 °C), when treatment was started before or at the onset of ischemia, and in temporary rather than permanent ischemia models. However, a reduction in infarct volume by about one third was also observed with temperature reduction to 35 °C, with initiation of treatment between 90 and 180 minutes, and in permanent ischemia models.[39] The effects of hypothermia on functional outcome were broadly similar.[39] This suggests that temperature-lowering therapy might be effective for large numbers of patients with ischemic stroke.

#### **6. Human studies of hypothermia in ischemic stroke**

Clinical studies of induced hypothermia were conducted on humans based on successful cerebral ischemia animal models. One of the first studies cooled 17 patients with stroke admitted within 12 hours from symptom onset (mean 3.25 hours) for 6 hours.[43] Hypothermia was induced (35.5° C) with cooling blankets and shivering was treated with meperidine. Mortality at 6 months after stroke was 12% in the hypothermia group versus 23% in historical matched-controls. Unfortunately, no benefit in terms of outcome was observed. It has been suggested that a longer hypothermia duration of 48–72 h may be required to reduce the formation of cerebral edema which usually occurs during the first 72 h after symptom onset.

Another study by Keller and collaborators measured the cerebral blood flow (CBF) and cerebral metabolic rate of oxygen consumption (CMRO2) in six patients with middle cerebral artery (MCA) strokes treated with hypothermia.[44] Patients were intubated and cooled with cooling blankets for 48 to 96 hours. A total of 19 measurements of CBF and jugular bulb O2 saturation were performed. This preliminary study suggested that moderate hypothermia (33° C) seems to reduce CBF and CMRO2 in humans.

A small study evaluated the feasibility of inducing and maintaining moderate hypothermia with the use of endovascular rather than surface cooling.[45] Six patients with severe acute ischemic stroke were treated with moderate hypothermia. The pace of cooling was 1.4 +/- 0.6º C/h, and target temperature was reached after 3 +/- 1 h (range, 2 to 4.5 h). During hypothermia, the maximal temperature observed was 33.4º C, and the minimal temperature was 32.2º C. Every patient developed pneumonia and hypotension. This small study demonstrated that induction and maintenance of hypothermia with an intravenous cooling device was feasible.

54 Therapeutic Hypothermia in Brain Injury

ischemic stroke.

h after symptom onset.

**5. Hypothermia in ischemic stroke** 

Body temperature is increased in 4% to 25 % of patients with acute ischemic stroke within the rst six hours after symptom onset.[40] The pathophysiology of this increase in body temperature is not completely understood. Higher body temperature may be a natural consequence of brain infarction. However, animal studies have suggested that higher body temperatures may increase the damage induced by cerebral ischemia.[41] Observational studies in patients with acute stroke have established the influence of body temperature on the clinical outcome of stroke. For each 1 °C increase in body temperature, the relative risk of poor outcome worsens more than two times.[42] This association may be limited to the first 12 to 24 hours from stroke onset.[42] These studies therefore suggest that control of body temperature and fever prevention may improve functional outcome after stroke.

In a systematic review of animal studies, therapeutic hypothermia reduced infarct size by 44% (95% condence interval 40 to 47%). The best results were obtained with lower temperatures (≤ 31 °C), when treatment was started before or at the onset of ischemia, and in temporary rather than permanent ischemia models. However, a reduction in infarct volume by about one third was also observed with temperature reduction to 35 °C, with initiation of treatment between 90 and 180 minutes, and in permanent ischemia models.[39] The effects of hypothermia on functional outcome were broadly similar.[39] This suggests that temperature-lowering therapy might be effective for large numbers of patients with

Clinical studies of induced hypothermia were conducted on humans based on successful cerebral ischemia animal models. One of the first studies cooled 17 patients with stroke admitted within 12 hours from symptom onset (mean 3.25 hours) for 6 hours.[43] Hypothermia was induced (35.5° C) with cooling blankets and shivering was treated with meperidine. Mortality at 6 months after stroke was 12% in the hypothermia group versus 23% in historical matched-controls. Unfortunately, no benefit in terms of outcome was observed. It has been suggested that a longer hypothermia duration of 48–72 h may be required to reduce the formation of cerebral edema which usually occurs during the first 72-

Another study by Keller and collaborators measured the cerebral blood flow (CBF) and cerebral metabolic rate of oxygen consumption (CMRO2) in six patients with middle cerebral artery (MCA) strokes treated with hypothermia.[44] Patients were intubated and cooled with cooling blankets for 48 to 96 hours. A total of 19 measurements of CBF and jugular bulb O2 saturation were performed. This preliminary study suggested that moderate

A small study evaluated the feasibility of inducing and maintaining moderate hypothermia with the use of endovascular rather than surface cooling.[45] Six patients with severe acute ischemic stroke were treated with moderate hypothermia. The pace of cooling was 1.4 +/-

**6. Human studies of hypothermia in ischemic stroke** 

hypothermia (33° C) seems to reduce CBF and CMRO2 in humans.

Cooling for acute ischemic brain damage (COOL-AID), was one of the first studies to evaluate hypothermia in ischemic stroke after thrombolysis.[46] This was a nonrandomized study that used surface cooling to achieve a cooling temperature of 32 ± 1°C for 12 to 72-h. To prevent shivering, all patients undergoing hypothermia were intubated, sedated, and pharmacologically paralyzed. The study demonstrated that hypothermia is technically feasible and safe for patients with acute ischemic strokes who are undergoing thrombolytic therapy. However, the study was too small (10 patients) to determine any solid conclusions.

A later version of the same study, evaluated and intravascular cooling device in the treatment of stroke through the induction of hypothermia. The second COOL-AID was a randomized controlled study of 40 patients presenting within 12- h of symptom onset. Eighteen patients were cooled and 22 received standard medical management, which included thrombolysis in 13 patients. Shivering was suppressed using a forced-air warming blanket, buspirone and meperidine. Eight patients in the hypothermia group required intubation during their hospitalization, one patient was intubated during the maintenance phase of hypothermia and the other for various reasons not related to cooling. Most patients tolerated hypothermia, and clinical outcomes were similar in both groups although there was a trend of reduced lesion growth on diffusion-weighted imaging in the group treated with hypothermia.[47] Side effects included pneumonia, cardiac arrhythmia, and deep vein thrombosis. The main lessons from these two studies (COOL-AID one and two) were that mild hypothermia can be achieved in awake patients with the appropriate cooling and antishivering protocols; and that endovascular cooling achieves target temperature faster than surface cooling.

ICTuS is another nonrandomized clinical trial that cooled 18 acute stroke patients using an endovascular cooling device.[48] Patients were cooled within 12 hours of symptom onset. An anti-shivering regimen with buspirone and meperidine was administered prophylactically. Overall, patients tolerated cooling well and the incidence of cerebral hemorrhage did not increase among patients (n=5) who received intravenous (IV) tPA. This trial confirmed that endovascular cooling with a proactive anti-shivering regimen can be accomplished in awake stroke patients. A later brain CT analysis of patients who were effectively cooled (n=7) versus those who were not (n=11), suggested that endovascular hypothermia decreases acute post-ichemic cerebral edema. [49] At the end of the cooling and rewarming period (36–48 h), patients who were effectively cooled had signicantly decreased cerebral edema compared to patients who were either ineffectively cooled or not cooled at all. The effect disappeared by 30 days, as might be expected given the natural course of post-infarction cerebral edema.

A follow-up randomized, controlled study of endovascular cooling in awake patients after stroke (ICTuS-L), studied hypothermia with thrombolysis in patients presenting with acute ischemic stroke < 6 h from symptom onset.[50] Twenty eight patients were randomized to receive hypothermia and 30 to normothermia. There were no differences in outcome or incidence of adverse events comparing patients who were treated with tPA and hypothermia with those who were not cooled. For safety concerns, endovascular hypothermia with placement of the femoral cooling catheter was not begun until 30 to 180 minutes after completion of the tPA infusion, delaying cooling. Pneumonia was more frequent after hypothermia, although the occurrence of pneumonia did not significantly affect outcome at 90 days. The study used meperidine, oral buspirone, and surface skin warming to prevent shivering in awake patients. This study demonstrated the feasibility and preliminary safety of combining endovascular hypothermia after stroke with intravenous thrombolysis, similarly to what the COOL AID study demonstrated previously.[46]

Therapeutic Hypothermia in Acute Stroke 57

many serine proteases are affected by temperature, and the activity of tPA may be reduced in hypothermia.[54] In vitro analysis shows that cooling to 30°C to 33°C decreases tPA activity by 2% to 4%.[55] Moreover, it has been reported that the response to tPA may be related to body temperature at stroke presentation.[56] Investigators studied 111 acute stroke patients given tPA and found that patients presenting with a higher body temperature were more likely to have a favorable outcome compared with patients presenting with lower body temperatures. The authors suggested that this surprising finding might be explained by the benefit of im proved clot lysis by tPA at higher temperatures compared with the potential neuroprotective benefit of lower body

A recent analysis of 5586 patients with acute ischemic stroke (1980 patients received tPA) determined that tPA treatment effect was not associated with baseline temperature.[57] Point estimates showed benefit of tPA treatment across 35.5°C to 37.5°C but showed a negative trend >37.5°C. Temperature profiles did not influence tPA effectiveness over 72

Hypothermia has also been evaluated in the treatment of cerebral edema after large MCA infarctions. Schwab and collaborators induced moderate hypothermia in 25 patients with large MCA strokes.[58] Hypothermia was induced within 14 ± 7 hours after stroke onset by external cooling with cooling blankets, cold infusions, and cold washing. Hypothermia at 33°C body-core temperature was maintained for 48 to 72 hours, and intracranial pressure (ICP), cerebral perfusion pressure, and brain temperature were continuously monitored. Elevated ICP values were significantly reduced during hypothermia. Herniation caused by a secondary rise in ICP after rewarming was the cause of death in most patients. The most frequent complication of moderate hypothermia was pneumonia in 10 of the 25 patients [40%). Authors concluded that moderate hypothermia can help to control critically elevated ICP values in severe space-occupying edema after MCA stroke. This and a similar study by the same group were pivotal in demonstrating that hypothermia was safe and effective in

A prospective study performed by the same group, induced hypothermia in 50 patients with cooling blankets as well as alcohol and ice bags within 22 ± 9 hours after stroke onset.[59] Hypothermia was maintained for 24 to 72 hours and passive rewarming performed over a mean duration of 17 hours. Time required for cooling to < 33°C varied from 3.5 to 11 hours. The most frequent complications of hypothermic therapy were thrombocytopenia (70%). Faster rewarming (< 16 hours) was associated with rebound increased ICP, and most deaths occurred during the rewarming period. Further data in MCA infarct patients suggests that controlled rewarming rates of ≤ 0.1 per hour allow for improved control of ICP when compared with patients in whom rewarming is achieved in

**8. Hypothermia in the treatment of large MCA strokes** 

the treatment of increased ICP after malignant MCA infarction.[59]

temperature.

hours after stroke.

an uncontrolled fashion.[60]

The experience in the use of hypothermia with thrombolysis is limited in stroke patients. In the first COOL-AID study that used surface cooling, 4 of 10 patients received intra-arterial thrombolysis, and 2 received IV therapy.[46] In the second study, 3 of 18 patients were treated with intra-arterial therapy, and 10 received IV thrombolysis.[47] One patient who was treated with hypothermia and intra-arterial thrombolysis experienced retroperitoneal hemorrhage.[47] In the ICTuS-L trial, the rate of ICH was similar among patients who received tPA with hypothermia and those treated with tPA alone.[51]

Hypothermia has also been studied with other neuroprotective agents in the treatment of acute ischemic stroke. Twenty patients with acute ischemic stroke were treated with caffeinol (caffeine 8-9 mg/kg + ethanol 0.4 g/kg intravenously x 2 hours, started by 4 hours after symptom onset) and hypothermia (started by 5 hours and continued for 24 hours (33- 35º C), followed by 12 hours of rewarming).[52] IV tPA was given to 16 patients within 3 hours of symptom onset. Meperidine and buspirone were used to suppress shivering. Cooling was successfully achieved in 16 patients via endovascular and surface approaches. All patients reached target temperature, on average within 2 hours and 30 minutes from induction and 6 hours and 21 minutes from symptom onset. Three patients died: one from symptomatic hemorrhage, one from malignant cerebral edema, and one from unrelated medical complications. No adverse events were attributed to caffeinol.

A small study evaluated the use of ice-cold saline for the induction of mild hypothermia in 10 patients with acute ischemic stroke.[53] Ice-cold saline at 4°C (25 mL/kg body weight) was administered one time to induce mild hypothermia. Patients received buspirone and meperidine to prevent and treat shivering. Tympanic temperature dropped significantly by a maximum of 1.6 ± 0.3°C at 52 ± 16 minutes after ice-cold saline was started. The procedure was well tolerated, however, hypothermia was not maintained after the infusion of ice-cold saline.

#### **7. Hypothermia and thrombolysis**

Theoretically, the combination of hypothermia with pharmacological thrombolysis to restore blood flow and provide neuroprotection is a very promising strategy. However, many serine proteases are affected by temperature, and the activity of tPA may be reduced in hypothermia.[54] In vitro analysis shows that cooling to 30°C to 33°C decreases tPA activity by 2% to 4%.[55] Moreover, it has been reported that the response to tPA may be related to body temperature at stroke presentation.[56] Investigators studied 111 acute stroke patients given tPA and found that patients presenting with a higher body temperature were more likely to have a favorable outcome compared with patients presenting with lower body temperatures. The authors suggested that this surprising finding might be explained by the benefit of im proved clot lysis by tPA at higher temperatures compared with the potential neuroprotective benefit of lower body temperature.

A recent analysis of 5586 patients with acute ischemic stroke (1980 patients received tPA) determined that tPA treatment effect was not associated with baseline temperature.[57] Point estimates showed benefit of tPA treatment across 35.5°C to 37.5°C but showed a negative trend >37.5°C. Temperature profiles did not influence tPA effectiveness over 72 hours after stroke.

#### **8. Hypothermia in the treatment of large MCA strokes**

56 Therapeutic Hypothermia in Brain Injury

to what the COOL AID study demonstrated previously.[46]

received tPA with hypothermia and those treated with tPA alone.[51]

medical complications. No adverse events were attributed to caffeinol.

**7. Hypothermia and thrombolysis** 

A follow-up randomized, controlled study of endovascular cooling in awake patients after stroke (ICTuS-L), studied hypothermia with thrombolysis in patients presenting with acute ischemic stroke < 6 h from symptom onset.[50] Twenty eight patients were randomized to receive hypothermia and 30 to normothermia. There were no differences in outcome or incidence of adverse events comparing patients who were treated with tPA and hypothermia with those who were not cooled. For safety concerns, endovascular hypothermia with placement of the femoral cooling catheter was not begun until 30 to 180 minutes after completion of the tPA infusion, delaying cooling. Pneumonia was more frequent after hypothermia, although the occurrence of pneumonia did not significantly affect outcome at 90 days. The study used meperidine, oral buspirone, and surface skin warming to prevent shivering in awake patients. This study demonstrated the feasibility and preliminary safety of combining endovascular hypothermia after stroke with intravenous thrombolysis, similarly

The experience in the use of hypothermia with thrombolysis is limited in stroke patients. In the first COOL-AID study that used surface cooling, 4 of 10 patients received intra-arterial thrombolysis, and 2 received IV therapy.[46] In the second study, 3 of 18 patients were treated with intra-arterial therapy, and 10 received IV thrombolysis.[47] One patient who was treated with hypothermia and intra-arterial thrombolysis experienced retroperitoneal hemorrhage.[47] In the ICTuS-L trial, the rate of ICH was similar among patients who

Hypothermia has also been studied with other neuroprotective agents in the treatment of acute ischemic stroke. Twenty patients with acute ischemic stroke were treated with caffeinol (caffeine 8-9 mg/kg + ethanol 0.4 g/kg intravenously x 2 hours, started by 4 hours after symptom onset) and hypothermia (started by 5 hours and continued for 24 hours (33- 35º C), followed by 12 hours of rewarming).[52] IV tPA was given to 16 patients within 3 hours of symptom onset. Meperidine and buspirone were used to suppress shivering. Cooling was successfully achieved in 16 patients via endovascular and surface approaches. All patients reached target temperature, on average within 2 hours and 30 minutes from induction and 6 hours and 21 minutes from symptom onset. Three patients died: one from symptomatic hemorrhage, one from malignant cerebral edema, and one from unrelated

A small study evaluated the use of ice-cold saline for the induction of mild hypothermia in 10 patients with acute ischemic stroke.[53] Ice-cold saline at 4°C (25 mL/kg body weight) was administered one time to induce mild hypothermia. Patients received buspirone and meperidine to prevent and treat shivering. Tympanic temperature dropped significantly by a maximum of 1.6 ± 0.3°C at 52 ± 16 minutes after ice-cold saline was started. The procedure was well tolerated, however, hypothermia was not maintained after the infusion of ice-cold saline.

Theoretically, the combination of hypothermia with pharmacological thrombolysis to restore blood flow and provide neuroprotection is a very promising strategy. However, Hypothermia has also been evaluated in the treatment of cerebral edema after large MCA infarctions. Schwab and collaborators induced moderate hypothermia in 25 patients with large MCA strokes.[58] Hypothermia was induced within 14 ± 7 hours after stroke onset by external cooling with cooling blankets, cold infusions, and cold washing. Hypothermia at 33°C body-core temperature was maintained for 48 to 72 hours, and intracranial pressure (ICP), cerebral perfusion pressure, and brain temperature were continuously monitored. Elevated ICP values were significantly reduced during hypothermia. Herniation caused by a secondary rise in ICP after rewarming was the cause of death in most patients. The most frequent complication of moderate hypothermia was pneumonia in 10 of the 25 patients [40%). Authors concluded that moderate hypothermia can help to control critically elevated ICP values in severe space-occupying edema after MCA stroke. This and a similar study by the same group were pivotal in demonstrating that hypothermia was safe and effective in the treatment of increased ICP after malignant MCA infarction.[59]

A prospective study performed by the same group, induced hypothermia in 50 patients with cooling blankets as well as alcohol and ice bags within 22 ± 9 hours after stroke onset.[59] Hypothermia was maintained for 24 to 72 hours and passive rewarming performed over a mean duration of 17 hours. Time required for cooling to < 33°C varied from 3.5 to 11 hours. The most frequent complications of hypothermic therapy were thrombocytopenia (70%). Faster rewarming (< 16 hours) was associated with rebound increased ICP, and most deaths occurred during the rewarming period. Further data in MCA infarct patients suggests that controlled rewarming rates of ≤ 0.1 per hour allow for improved control of ICP when compared with patients in whom rewarming is achieved in an uncontrolled fashion.[60]

Georgiadis and collaborators compared hypothermia with hemicraniectomy in the treatment of more than 2/3 of the MCA infarction.[61] Seventeen patients underwent hemicraniectomy and 19 were treated with moderate hypothermia (33°C), which was induced with cooling blankets and endovascular devices. Hypothermia was induced for 71 ± 21 hours (range, 24 - 116 hours), whereas duration of rewarming varied between 25 and 34 hours. Prolongation of hypothermia >72 hours was always related to raised ICP during rewarming attempts. Mortality was 12% in the hemicraniectomy group and 47% in the hypothermia group; one patient treated with hypothermia died as a result of cooling complications (sepsis) and three patients died of ICP crises that occurred during rewarming.

Therapeutic Hypothermia in Acute Stroke 59

 **Authors Study Number of** 

Kammersgaa

Single center,

nonrandomized,

open label.

Keller (44)

Single center,

6 63.5 h Surface 48-96 h Intubated Midazolam, fentanyl

6 28±17 h Endovascular 48-72 h Intubated Midazolam, fentanyl

and atracurium.

33°C 3±1 h Bradycardia 50%

Induction and maintenance of

hypothermia with intravenous

cooling was feasible.

Pneumonia 100%

Hypotension 100%

Thromb 33%

Bradycardia 50%

Hypothermia was well tolerated

after thrombolysis.

Arrythmia 30%

Hypotension 30%

33°C 3.5±

1.5 h

and atracurium.

nonrandomized,

open label.

Georgiadis

Single center,

nonrandomized,

(45)

(2001)

Krieger (46)

Single center,

10 6 h Surface 12-72 h Intubated Propofol and

atracurium.

nonrandomized,

open label,

parallel control

(COOL AID)

Multicenter,

18 12 h Endovascular 24 h Non-

intubated Air warming blanket, buspirone and

33°C 77±

Pneumonia 11%

Endovascular hypothermia in

awake patients was well

Arrythmia 11%

Retroperitoneal

tolerated.

hematoma 5%

33°C 7 h DVT 22%

Bradycardia 22%

Endovascular hypothermia in

awake patients was well

Hypokalemia 22%

tolerated.

Groin hematoma

11%

Arrythmia 11%

33-35°C 8 h Pneumonia 20% Hypothermia was combined with

caffeinol and tPA in nonintubated

patients.

Hypothermia was well tolerated

after thrombolysis. 24-h

assessments were affected by

sedation in the hypothermia

group.

33°C 7 h Pneumonia 25%

DVT 14%

44 min

meperidine.

intubated Air warming blanket, buspirone and

meperidine.

randomized,

open label.

(COOL AID)

Multicenter,

18 12 h Endovascular 12-24 h Non-

open label,

nonrandomized.

(ICTuS)

Martin-Schild (52)

Single center,

18 5 h Surface and

24 h Non-

intubated Air warming blanket, buspirone and

meperidine.

intubated Air warming blanket, buspirone and

meperidine.

endovascular

28 6 h Endovascular 24 h Non-

nonrandomized,

(2009)

Hemmen

(50)

(2010)

open label.

Multicenter,

randomized,

double-blinded.

(ICTuS-L)

Lyden (48)

(2005)

(2001)

open label.

(2000)

rd (43) (2000)

**Ischemic Stroke** 

(47)

(2004)

De Georgia

**Patients** 

**Stroke** 

**Time from** 

**Cooling** 

**Cooling** 

**Patient Anti-shivering Target** 

**Temp** 

**Target** 

**Temp** 

intubated Meperidine 35.5°C 6 h Infection 18% Awake patients tolerated surface hypothermia.

33°C NA NA Hypothermia decreased CMRO2

and CBF.

**Time to** 

**Complications Comment** 

**Technique** 

17 12 h Surface 6 h Non-

**Time** 

Another small prospective study with 25 patients compared hypothermia with hemicraniectomy and hemicraniectomy alone in the treatment of patients with large MCA strokes.[62] Hemicraniectomy was performed within 15 +/- 6 h after the ischemic event, followed by hypothermia. There were no severe side effects of hypothermia. Patients treated with hemicraniectomy plus moderate hypothermia had a tendency to better outcome after 6 months when compared to patients treated with hemicraniectomy alone.

## **9. Human studies of hypothermia in hemorrhagic stroke**

ICH accounts for approximately 10% of strokes and the 30-day mortality rate is approximately 52%.[63] After the acute phase of ICH, high morbidity and mortality are essentially caused by the evolution of a peri-hemorrhagic, space-occupying edema associated with gradually increasing ICP.[64] Although the natural course of edema formation is still not fully understood, edema mostly increases during the first week and reaches its maximum during the second week after bleeding onset.[65, 66] Animal studies have suggested that hypothermia may have a neuroprotective role after ICH in reducing edema formation by various mechanisms.[67, 68]

One of the first experiences with hypothermia in the treatment of ICH was reported by Howell and collaborators in 1956.[69] Hypothermia between 30°C to 32°C was induced in eight patients with spontaneous ICH. Although signs of herniation improved in all patients, six patients died from systemic complications, most commonly aspiration. Anecdotally, hypothermia was induced with ice bags, alcohol, and even opening the windows in the middle of the Canadian winter.

Kollmar and collaborators treated twelve patients with supratentorial large ICH (> 25 mL) with hypothermia (35°C) for 10 days.[5] In the hypothermia group, edema volume remained stable during 14 days, whereas edema significantly increased in the control group. However, pneumonia was more frequent in the hypothermia group. Based on these results, the same investigators planned the Cooling in Intracerebral Hemorrhage (CINCH) trial. [70] This is a prospective multicenter trial that WILL enroll 50 patients with large ICH and randomly assign them to mild hypothermia versus conventional medical management.


Georgiadis and collaborators compared hypothermia with hemicraniectomy in the treatment of more than 2/3 of the MCA infarction.[61] Seventeen patients underwent hemicraniectomy and 19 were treated with moderate hypothermia (33°C), which was induced with cooling blankets and endovascular devices. Hypothermia was induced for 71 ± 21 hours (range, 24 - 116 hours), whereas duration of rewarming varied between 25 and 34 hours. Prolongation of hypothermia >72 hours was always related to raised ICP during rewarming attempts. Mortality was 12% in the hemicraniectomy group and 47% in the hypothermia group; one patient treated with hypothermia died as a result of cooling complications (sepsis) and three patients died of ICP crises that occurred during rewarming.

Another small prospective study with 25 patients compared hypothermia with hemicraniectomy and hemicraniectomy alone in the treatment of patients with large MCA strokes.[62] Hemicraniectomy was performed within 15 +/- 6 h after the ischemic event, followed by hypothermia. There were no severe side effects of hypothermia. Patients treated with hemicraniectomy plus moderate hypothermia had a tendency to better outcome after 6

ICH accounts for approximately 10% of strokes and the 30-day mortality rate is approximately 52%.[63] After the acute phase of ICH, high morbidity and mortality are essentially caused by the evolution of a peri-hemorrhagic, space-occupying edema associated with gradually increasing ICP.[64] Although the natural course of edema formation is still not fully understood, edema mostly increases during the first week and reaches its maximum during the second week after bleeding onset.[65, 66] Animal studies have suggested that hypothermia may have a neuroprotective role after ICH in reducing

One of the first experiences with hypothermia in the treatment of ICH was reported by Howell and collaborators in 1956.[69] Hypothermia between 30°C to 32°C was induced in eight patients with spontaneous ICH. Although signs of herniation improved in all patients, six patients died from systemic complications, most commonly aspiration. Anecdotally, hypothermia was induced with ice bags, alcohol, and even opening the windows in the

Kollmar and collaborators treated twelve patients with supratentorial large ICH (> 25 mL) with hypothermia (35°C) for 10 days.[5] In the hypothermia group, edema volume remained stable during 14 days, whereas edema significantly increased in the control group. However, pneumonia was more frequent in the hypothermia group. Based on these results, the same investigators planned the Cooling in Intracerebral Hemorrhage (CINCH) trial. [70] This is a prospective multicenter trial that WILL enroll 50 patients with large ICH and randomly assign them to mild hypothermia versus conventional

months when compared to patients treated with hemicraniectomy alone.

**9. Human studies of hypothermia in hemorrhagic stroke** 

edema formation by various mechanisms.[67, 68]

middle of the Canadian winter.

medical management.


Therapeutic Hypothermia in Acute Stroke 61

Hypothermia has also been evaluated in the management of subarachnoid hemorrhage (SAH). Gasser and collaborators treated 21 patients with poor grade SAH and cerebral edema with long-term hypothermia (>72 hrs).[71] Nine patients were treated for <72 hrs and 12 for >72 hrs. Functional independence at 3 months was achieved in 48% of patients, but the outcome did not differ with the group of patients treated without hypothermia. The

Induced therapeutic hypothermia is an intensive care procedure that has to be performed under continuous monitoring. Since most patients who are cooled are critically ill, they may be more prone to develop complications. These complications appear to be associated with de degree of hypothermia, with the risk of side effects being correlated with prolonged hypothermia and lower temperatures. In general, hypothermia is well tolerated, but complications may include: 1) cardiac: arrhythmias, bradycardia, reduced ventricular contractility, and hypotension; 2) immunologic: immunosuppression; 3) hematologic: thrombocytopenia and mild coagulopathy; and 4) metabolic: shivering, hyperglycemia, hypokalemia, ileus, and cold-induced diuresis. The most common complication in reported studies is pneumonia, followed by asymptomatic bradycardia, cardiac arrhythmias and

Pneumonia appears to occur more frequently in intubated patients who undergo cooling. Endovascular cooling with use of warm blankets to reduce shivering and prevent intubation

The most dangerous phase of induced hypothermia is the rewarming period. Particular care is required in stroke patients with intracranial mass effect and elevated ICP. Overly rapid rewarming can lead to a systemic inflammatory response syndrome; with systemic vasodilatation, hypotension, and reflex ICP elevation.[14] As a general rule, hypothermia patients with increased ICP should undergo active controlled rewarming (or "decooling") at a rate of 0.1°C per hour. Faster rates of 0.25°C to 0.33°C per hour can be tolerated in patients without ICP issues.[72-74] This high ICP rebound has especially been observed in patients

One common complication of hypothermia that usually is overlooked is sedation. It has been demonstrated that patients who undergo hypothermia are more likely to receive sedation than those who are not treated with hypothermia.[76] Sedation in hypothermia patients may linger longer in the system, confounding neurological examination and prognostication.[77] This becomes a relevant issue in stroke patients who require daily

Despite the many potential neuroprotective effects of hypothermia seen in animal stroke models and the benefit of hypothermia observed in humans following cardiac arrest, there is

is an alternative to surface cooling and may reduce the rate of pneumonia.

most common form of complication was infection in both groups.

**10. Complications of hypothermia** 

thrombocytopenia (table).[14]

with malignant MCA infarctions.[75]

**11. Conclusion and recommendations** 

neurological assessments.

**Table 1.** Main studies of the use of hypothermia in the treatment of acute stroke.

#### 60 Therapeutic Hypothermia in Brain Injury

Hypothermia has also been evaluated in the management of subarachnoid hemorrhage (SAH). Gasser and collaborators treated 21 patients with poor grade SAH and cerebral edema with long-term hypothermia (>72 hrs).[71] Nine patients were treated for <72 hrs and 12 for >72 hrs. Functional independence at 3 months was achieved in 48% of patients, but the outcome did not differ with the group of patients treated without hypothermia. The most common form of complication was infection in both groups.
