ABSTRACT
Objective:To explore the central mechanism of overactive bladder (OAB) using the resting-state functional magnetic resonance imaging (rs-fMRI). Methods:From October, 2019 to January, 2021, 13 patients with OAB aged (46.9 ±13.4) years were enrolled. Under urodynamic monitoring, rs-fMRI scans were performed in these subjects under empty bladder and strong desire to void. Matlab 2016, SPM 12 and DPABI software were used to process and analyze these obtained image data, six brain regions related to bladder control: right superior frontal gyrus (X = 3, Y=24, Z = 48), right anterior cingulate gyrus (X = 12, Y = 33, Z = 3), left postcentral gyrus (X = -18, Y = -26, Z = 48), right supplementary motor area (X = 3, Y = -12, Z = 63), left insular (X = -42, Y = -12, Z = -3) and right insular (X = 3, Y = -12, Z = 63),were extracted as the regions of interest to analyze the functional connection with the whole brain. Results:The functional connection of the right superior frontal gyrus with the right middle frontal gyrus increased, while the connection with the right cuneus decreased. The connection of the right anterior cingulate gyrus with the right superior temporal gyrus increased, while the connection with the left posterior cingulate gyrus decreased. The connection of the left postcentral gyrus with the right cuneus decreased. The functional connection of the right supplementary motor area with the left cuneus, the connection of the right insular with the medial superior frontal gyrus, and the connection of the left insular with the inferior parietal lobule increased. Conclusion:The functional connections between the brain areas related to continence and other brain regions involved in bladder control changes in patients with OAB. These changes may be one of the potential pathogenic mechanisms of OAB.
ABSTRACT
Objective:To identify the small-world network property of brain functional network provoked by a strong desire to void in healthy women. Methods:From 2017 to 2018, 21 healthy women were enrolled, and scanned with resting-state functional magnetic resonance imaging under the empty bladder and strong desire to void, respectively. Brain connection matrix was established with Pearson's correlation analysis, and the differences in topologic properties between the two conditions were identified with paired t-test and Bonferroni correction. The small-world parameters, named clustering coefficient (Cp), characteristic path length (Lp), global efficiency (Eglob), local efficiency (Eloc) and nodal efficiency (Enodal) were calculated. Results:There were two women dropped down because of head moving. For the other 19 women, the brain connection presented a small-world network property under the both conditions. Compared with the empty bladder, Cp, Lp, and Eloc decreased, and Eglob increased under the strong desire to void (P < 0.05); while Enodal increased in left inferior frontal gyrus and superior frontal gyrus; right cingulate gyrus, middle occipital gyrus and middle temporal gyrus; and bilateral gyrus rectus and inferior parietal lobes; and decreased in bilateral fusiform gyrus, calcarine fissure and surrounding, and lingual gyrus (P < 0.05). Conclusion:Brain functional network presents a small-world network property under both empty bladder and a strong desire to void. The regulation of lower urinary tract function involves the coordination of multiple brain regions.