Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping

Jan Sedlacik; Åsmund Kjørstad; Zsuzsanna Nagy; Jan-Hendrik Buhk; Christoph R Behem; Constantin J Trepte; Jens Fiehler; Fabian Temme

doi:10.1089/ther.2017.0031

Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping

Standard

Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping. / Sedlacik, Jan; Kjørstad, Åsmund; Nagy, Zsuzsanna; Buhk, Jan-Hendrik; Behem, Christoph R; Trepte, Constantin J ; Fiehler, Jens; Temme, Fabian.

In: THER HYPOTHERMIA TEM, Vol. 8, No. 1, 03.2018, p. 45-52.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Sedlacik, J, Kjørstad, Å, Nagy, Z, Buhk, J-H, Behem, CR, Trepte, CJ , Fiehler, J & Temme, F 2018, 'Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping', THER HYPOTHERMIA TEM, vol. 8, no. 1, pp. 45-52. https://doi.org/10.1089/ther.2017.0031

APA

Sedlacik, J., Kjørstad, Å., Nagy, Z., Buhk, J-H., Behem, C. R., Trepte, C. J., Fiehler, J., & Temme, F. (2018). Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping. THER HYPOTHERMIA TEM, 8(1), 45-52. https://doi.org/10.1089/ther.2017.0031

Vancouver

Sedlacik J, Kjørstad Å, Nagy Z, Buhk J-H, Behem CR, Trepte CJ et al. Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping. THER HYPOTHERMIA TEM. 2018 Mar;8(1):45-52. https://doi.org/10.1089/ther.2017.0031

Bibtex

@article{bc477b6a53a9459c83840b3089c43279,

title = "Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping",

abstract = "Early, prehospital cooling seeks to reduce and control the body temperature as early as possible to protect the brain and improve patient outcome in cardiac arrest, stroke, and traumatic brain injury. In this study, we investigate the feasibility of localized cooling of the porcine brain by using a novel high-flow cold air protocol, which utilizes the close proximity between the nasal cavity and the brain. Five adult pigs were anesthetized and temperature change was mapped before, during, and after cooling by using the proton resonance frequency method on a 3 T Siemens Magnetom Skyra system. Cooling was performed by inserting a tube blowing high-flow (250 L/min) cold air (-10°C) through the nasal cavity for 5-20 minutes. The brain temperature change was measured by using an MRI phase mapping technique utilizing the temperature-dependent proton resonance frequency change. MRI maps showed significant temperature reduction of the porcine brain. On average, a mean whole-brain cooling effect of -0.33°C ± 0.30°C was found after 5 minutes of cooling. The anterior part of the brain was directly exposed to the cold and showed a significantly larger temperature drop (-0.83°C ± 0.51°C) than the posterior part (-0.03°C ± 0.21°C). However, a large variability of the temperature drop was observed between the animals. This variability may be caused by not well-controlled factors confounding the MRI temperature mapping, for example, subject movement, or cooling effectiveness, for example, core temperature or nasal patency. The results indicate that the proposed high-flow cold air protocol allows for localized cooling of the frontal porcine brain, which may be clinically relevant for traumatic injuries of the frontal brain where systemic cooling is unfavorable.",

keywords = "Journal Article",

author = "Jan Sedlacik and {\AA}smund Kj{\o}rstad and Zsuzsanna Nagy and Jan-Hendrik Buhk and Behem, {Christoph R} and Trepte, {Constantin J} and Jens Fiehler and Fabian Temme",

year = "2018",

month = mar,

doi = "10.1089/ther.2017.0031",

language = "English",

volume = "8",

pages = "45--52",

journal = "THER HYPOTHERMIA TEM",

issn = "2153-7658",

publisher = "Mary Ann Liebert Inc.",

number = "1",

}

RIS

TY - JOUR

T1 - Feasibility Study of a Novel High-Flow Cold Air Cooling Protocol of the Porcine Brain Using MRI Temperature Mapping

AU - Sedlacik, Jan

AU - Kjørstad, Åsmund

AU - Nagy, Zsuzsanna

AU - Buhk, Jan-Hendrik

AU - Behem, Christoph R

AU - Trepte, Constantin J

AU - Fiehler, Jens

AU - Temme, Fabian

PY - 2018/3

Y1 - 2018/3

N2 - Early, prehospital cooling seeks to reduce and control the body temperature as early as possible to protect the brain and improve patient outcome in cardiac arrest, stroke, and traumatic brain injury. In this study, we investigate the feasibility of localized cooling of the porcine brain by using a novel high-flow cold air protocol, which utilizes the close proximity between the nasal cavity and the brain. Five adult pigs were anesthetized and temperature change was mapped before, during, and after cooling by using the proton resonance frequency method on a 3 T Siemens Magnetom Skyra system. Cooling was performed by inserting a tube blowing high-flow (250 L/min) cold air (-10°C) through the nasal cavity for 5-20 minutes. The brain temperature change was measured by using an MRI phase mapping technique utilizing the temperature-dependent proton resonance frequency change. MRI maps showed significant temperature reduction of the porcine brain. On average, a mean whole-brain cooling effect of -0.33°C ± 0.30°C was found after 5 minutes of cooling. The anterior part of the brain was directly exposed to the cold and showed a significantly larger temperature drop (-0.83°C ± 0.51°C) than the posterior part (-0.03°C ± 0.21°C). However, a large variability of the temperature drop was observed between the animals. This variability may be caused by not well-controlled factors confounding the MRI temperature mapping, for example, subject movement, or cooling effectiveness, for example, core temperature or nasal patency. The results indicate that the proposed high-flow cold air protocol allows for localized cooling of the frontal porcine brain, which may be clinically relevant for traumatic injuries of the frontal brain where systemic cooling is unfavorable.

AB - Early, prehospital cooling seeks to reduce and control the body temperature as early as possible to protect the brain and improve patient outcome in cardiac arrest, stroke, and traumatic brain injury. In this study, we investigate the feasibility of localized cooling of the porcine brain by using a novel high-flow cold air protocol, which utilizes the close proximity between the nasal cavity and the brain. Five adult pigs were anesthetized and temperature change was mapped before, during, and after cooling by using the proton resonance frequency method on a 3 T Siemens Magnetom Skyra system. Cooling was performed by inserting a tube blowing high-flow (250 L/min) cold air (-10°C) through the nasal cavity for 5-20 minutes. The brain temperature change was measured by using an MRI phase mapping technique utilizing the temperature-dependent proton resonance frequency change. MRI maps showed significant temperature reduction of the porcine brain. On average, a mean whole-brain cooling effect of -0.33°C ± 0.30°C was found after 5 minutes of cooling. The anterior part of the brain was directly exposed to the cold and showed a significantly larger temperature drop (-0.83°C ± 0.51°C) than the posterior part (-0.03°C ± 0.21°C). However, a large variability of the temperature drop was observed between the animals. This variability may be caused by not well-controlled factors confounding the MRI temperature mapping, for example, subject movement, or cooling effectiveness, for example, core temperature or nasal patency. The results indicate that the proposed high-flow cold air protocol allows for localized cooling of the frontal porcine brain, which may be clinically relevant for traumatic injuries of the frontal brain where systemic cooling is unfavorable.

KW - Journal Article

U2 - 10.1089/ther.2017.0031

DO - 10.1089/ther.2017.0031

M3 - SCORING: Journal article

C2 - 29099343

VL - 8

SP - 45

EP - 52

JO - THER HYPOTHERMIA TEM

JF - THER HYPOTHERMIA TEM

SN - 2153-7658

IS - 1

ER -