
Effects of isoflurane anesthesia on resting‐state fMRI signals and functional connectivity within primary somatosensory cortex of monkeys
Author(s) -
Wu TungLin,
Mishra Arabinda,
Wang Feng,
Yang PaiFeng,
Gore John C.,
Chen Li Min
Publication year - 2016
Publication title -
brain and behavior
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.915
H-Index - 41
ISSN - 2162-3279
DOI - 10.1002/brb3.591
Subject(s) - isoflurane , somatosensory system , neuroscience , resting state fmri , functional connectivity , functional magnetic resonance imaging , psychology , medicine , anesthesia
Correlated low‐frequency fluctuations of resting‐state functional magnetic resonance imaging (rsf MRI ) signals have been widely used for inferring intrinsic brain functional connectivity ( FC ). In animal studies, accurate estimate of anesthetic effects on rsf MRI signals is demanded for reliable interpretations of FC changes. We have previously shown that inter‐regional FC can reliably delineate local millimeter‐scale circuits within digit representations of primary somatosensory cortex (S1) subregions (areas 3a, 3b, and 1) in monkeys under isoflurane anesthesia. The goals of this study are to determine (1) the general effects of isoflurane on rsf MRI signals in the S1 circuit and (2) whether the effects are functional‐ and regional‐ dependent, by quantifying the relationships between isoflurane levels, power and inter‐regional correlation coefficients in digit and face regions of distinct S1 subregions. Methods Functional MRI data were collected from male adult squirrel monkeys at three different isoflurane levels (1.25%, 0.875%, and 0.5%). All scans were acquired on a 9.4T magnet with a 3‐cm‐diameter surface transmit‐receive coil centered over the S1 cortex. Power and seed‐based inter‐regional functional connectivity analyses were subsequently performed. Results As anesthesia level increased, we observed (1) diminishing amplitudes of signal fluctuations, (2) reduced power of fluctuations in the low‐frequency band used for connectivity measurements, (3) decreased inter‐voxel connectivity around seed regions, and (4) weakened inter‐regional FC across all pairs of regions of interest (digit‐to‐digit). The low‐frequency power measures derived from rsf MRI signals from control muscle regions, however, did not exhibit any isoflurane level‐related changes. Within the isoflurane dosage range we tested, the inter‐regional functional connectivity differences were still detectable, and the effects of isoflurane did not differ across region‐of‐interest ( ROI ) pairs. Conclusion Our data demonstrate that isoflurane induced similar dose‐dependent suppressive effects on the power of rsf MRI signals and local fine‐scale FC across functionally related but distinct S1 subregions.