Corrigendum: Repeatability and Reproducibility of in-vivo Brain Temperature Measurements

Background: Magnetic resonance spectroscopic imaging (MRSI) is a neuroimaging technique that may be useful for non-invasive mapping of brain temperature (i.e., thermometry) over a large brain volume. To date, intra-subject reproducibility of MRSI-based brain temperature (MRSI-t) has not been investigated. The objective of this repeated measures MRSI-t study was to establish intra-subject reproducibility and repeatability of brain temperature, as well as typical brain temperature range.Methods: Healthy participants aged 23–46 years (N = 18; 7 females) were scanned at two time points ~12-weeks apart. Volumetric MRSI data were processed by reconstructing metabolite and water images using parametric spectral analysis. Brain temperature was derived using the frequency difference between water and creatine (TCRE) for 47 regions of interest (ROIs) delineated by the modified Automated Anatomical Labeling (AAL) atlas. Reproducibility was measured using the coefficient of variation for repeated measures (COVrep), and repeatability was determined using the standard error of measurement (SEM). For each region, the upper and lower bounds of Minimal Detectable Change (MDC) were established to characterize the typical range of TCRE values.Results: The mean global brain temperature over all subjects was 37.2°C with spatial variations across ROIs. There was a significant main effect for time [F(1, 1,591) = 37.0, p < 0.0001] and for brain region [F(46, 1,591) = 2.66, p < 0.0001]. The time*brain region interaction was not significant [F(46, 1,591) = 0.80, p = 0.83]. Participants' TCRE was stable for each ROI across both time points, with ROIs' COVrep ranging from 0.81 to 3.08% (mean COVrep = 1.92%); majority of ROIs had a COVrep <2.0%.Conclusions: Brain temperature measurements were highly consistent between both time points, indicating high reproducibility and repeatability of MRSI-t. MRSI-t may be a promising diagnostic, prognostic, and therapeutic tool for non-invasively monitoring brain temperature changes in health and disease. However, further studies of healthy participants with larger sample size(s) and numerous repeated acquisitions are imperative for establishing a reference range of typical brain TCRE, as well as the threshold above which TCRE is likely pathological.

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In vivo brain temperature measurements based on fiber optic Bragg grating

10.1117/12.2265607 ◽

2017 ◽

Cited By ~ 1

Author(s):

Mohammad I. Zibaii ◽

Hamid Latifi ◽

Fatemeh Karami ◽

Abdolaziz Ronaghi ◽

Sara Chavoshi Nejad ◽

...

Keyword(s):

Fiber Optic ◽

Brain Temperature ◽

Temperature Measurements ◽

Bragg Grating

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IN VIVO TEMPERATURE MEASUREMENTS DURING WHOLE-BODY EXPOSURE OF MACACA MULATTA TO RESONANT AND NONRESONANT FREQUENCIES

Microwaves and Thermoregulation ◽

10.1016/b978-0-12-044020-7.50010-6 ◽

1983 ◽

pp. 95-107 ◽

Cited By ~ 6

Author(s):

Jerome H. Krupp

Keyword(s):

Macaca Mulatta ◽

Temperature Measurements ◽

Whole Body

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An In Vivo Assessment of Regional Brain Temperature during Whole-Body Cooling for Neonatal Encephalopathy

The Journal of Pediatrics ◽

10.1016/j.jpeds.2020.01.019 ◽

2020 ◽

Vol 220 ◽

pp. 73-79.e3

Author(s):

Tai-Wei Wu ◽

Jessica L. Wisnowski ◽

Robert F. Geisler ◽

Aaron Reitman ◽

Eugenia Ho ◽

...

Keyword(s):

Brain Temperature ◽

Whole Body ◽

Neonatal Encephalopathy ◽

Regional Brain ◽

Body Cooling ◽

Whole Body Cooling ◽

In Vivo Assessment

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In vivo imaging with a water immersion objective affects brain temperature, blood flow and oxygenation

eLife ◽

10.7554/elife.47324 ◽

2019 ◽

Vol 8 ◽

Cited By ~ 11

Author(s):

Morgane Roche ◽

Emmanuelle Chaigneau ◽

Ravi L Rungta ◽

Davide Boido ◽

Bruno Weber ◽

...

Keyword(s):

Blood Flow ◽

Brain Temperature ◽

Water Immersion ◽

Phosphorescence Lifetime ◽

Cranial Window ◽

Hemoglobin Saturation ◽

Tissue Po2 ◽

Physiological Values ◽

Water Immersion Objective

Previously, we reported the first oxygen partial pressure (Po2) measurements in the brain of awake mice, by performing two-photon phosphorescence lifetime microscopy at micrometer resolution (Lyons et al., 2016). However, this study disregarded that imaging through a cranial window lowers brain temperature, an effect capable of affecting cerebral blood flow, the properties of the oxygen sensors and thus Po2 measurements. Here, we show that in awake mice chronically implanted with a glass window over a craniotomy or a thinned-skull surface, the postsurgical decrease of brain temperature recovers within a few days. However, upon imaging with a water immersion objective at room temperature, brain temperature decreases by ~2–3°C, causing drops in resting capillary blood flow, capillary Po2, hemoglobin saturation, and tissue Po2. These adverse effects are corrected by heating the immersion objective or avoided by imaging through a dry air objective, thereby revealing the physiological values of brain oxygenation.

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Noninvasive Measurements of Human Brain Temperature Using Volume-Localized Proton Magnetic Resonance Spectroscopy

Journal of Cerebral Blood Flow & Metabolism ◽

10.1097/00004647-199704000-00001 ◽

1997 ◽

Vol 17 (4) ◽

pp. 363-369 ◽

Cited By ~ 71

Author(s):

Ron Corbett ◽

Abbot Laptook ◽

Paul Weatherall

Keyword(s):

Magnetic Resonance ◽

Frontal Lobe ◽

Mr Spectroscopy ◽

Brain Temperature ◽

Human Subjects ◽

Normal Subjects ◽

Whole Body ◽

Resonance Spectroscopy ◽

Noninvasive Measurements

Elucidation of the role of cerebral hyperthermia as a secondary factor that worsens outcome after brain injury, and the therapeutic application of modest brain hypothermia would benefit from noninvasive measurements of absolute brain temperature. The present study was performed to evaluate the feasibility of using 1H magnetic resonance (MR) spectroscopy to measure absolute brain temperature in human subjects on a clinical imaging spectroscopy system operating at a field strength of 1.5 T. In vivo calibration results were obtained from swine brain during whole-body heating and cooling, with concurrent measurements of brain temperature via implanted probes. Plots of the frequency differences between the in vivo MR peaks of water and N-acetyl-aspartate and related compounds (NAX), or water and choline and other trimethylamines versus brain temperature were linear over the temperature range studied (28–40°C). These relationships were used to estimate brain temperature from 1H MR spectra obtained from 10 adult human volunteers from 4 cm3-volumes selected from the frontal lobe and thalamus. Oral and forehead temperatures were monitored concurrently with MR data collection to verify normothermia in all the subjects studied. Temperatures determined using N-acetyl-aspartate or choline as the chemical shift reference did not differ significantly, and therefore results from these estimates were averaged. The brain temperature (mean ± SD) measured from the frontal lobe (37.2 = 0.6°C) and thalamus (37.7 ± 0.6°C) were significantly different from each other (paired t-test, p = 0.035). We conclude that 1H MR spectroscopy provides a viable noninvasive means of measuring regional brain temperatures in normal subjects and is a promising approach for measuring temperatures in brain-injured subjects.

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