Department of Psychiatry, Brigham and Women's Hospital, Harvard Medical School, Boston, MA, USA.
Department of Radiology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA, USA.
Mol Psychiatry. 2024 Nov;29(11):3623-3634. doi: 10.1038/s41380-024-02597-3. Epub 2024 Jun 3.
Recent studies show that accelerated cortical gray matter (GM) volume reduction seen in anatomical MRI can help distinguish between individuals at clinical high risk (CHR) for psychosis who will develop psychosis and those who will not. This reduction is suggested to represent atypical developmental or degenerative changes accompanying an accumulation of microstructural changes, such as decreased spine density and dendritic arborization. Detecting the microstructural sources of these changes before they accumulate into volume loss is crucial. Our study aimed to detect these microstructural GM alterations using diffusion MRI (dMRI). We tested for baseline and longitudinal group differences in anatomical and dMRI data from 160 individuals at CHR and 96 healthy controls (HC) acquired in a single imaging site. Of the CHR individuals, 33 developed psychosis (CHR-P), while 127 did not (CHR-NP). Among all participants, longitudinal data was available for 45 HCs, 17 CHR-P, and 66 CHR-NP. Eight cortical lobes were examined for GM volume and GM microstructure. A novel dMRI measure, interstitial free water (iFW), was used to quantify GM microstructure by eliminating cerebrospinal fluid contribution. Additionally, we assessed whether these measures differentiated the CHR-P from the CHR-NP. In addition, for completeness, we also investigated changes in cortical thickness and in white matter (WM) microstructure. At baseline the CHR group had significantly higher iFW than HC in the prefrontal, temporal, parietal, and occipital lobes, while volume was reduced only in the temporal lobe. Neither iFW nor volume differentiated between the CHR-P and CHR-NP groups at baseline. However, in many brain areas, the CHR-P group demonstrated significantly accelerated changes (iFW increase and volume reduction) with time than the CHR-NP group. Cortical thickness provided similar results as volume, and there were no significant changes in WM microstructure. Our results demonstrate that microstructural GM changes in individuals at CHR have a wider extent than volumetric changes or microstructural WM changes, and they predate the acceleration of brain changes that occur around psychosis onset. Microstructural GM changes, as reflected by the increased iFW, are thus an early pathology at the prodromal stage of psychosis that may be useful for a better mechanistic understanding of psychosis development.
最近的研究表明,在解剖 MRI 中观察到的皮质灰质(GM)体积加速减少,可以帮助区分处于精神病临床高风险(CHR)的个体,这些个体将发展为精神病,而那些不会发展为精神病。这种减少被认为代表了伴随微观结构变化积累的非典型发育或退行性变化,例如密度降低和树突分支减少。在这些变化累积为体积损失之前,检测微观结构的来源至关重要。我们的研究旨在使用扩散 MRI(dMRI)检测这些 GM 的微观结构变化。我们测试了 160 名 CHR 个体和 96 名健康对照者(HC)的解剖和 dMRI 数据的基线和纵向组差异,这些数据是在单一成像部位获得的。在 CHR 个体中,33 人发展为精神病(CHR-P),而 127 人未发展为精神病(CHR-NP)。在所有参与者中,有 45 名 HC、17 名 CHR-P 和 66 名 CHR-NP 具有纵向数据。检查了 8 个大脑皮质叶的 GM 体积和 GM 微观结构。一种新的 dMRI 测量方法,间质自由水(iFW),通过消除脑脊液的贡献来量化 GM 微观结构。此外,我们评估了这些测量方法是否可以区分 CHR-P 和 CHR-NP。此外,为了完整性,我们还研究了皮质厚度和白质(WM)微观结构的变化。在基线时,与 HC 相比,CHR 组在额、颞、顶和枕叶的 iFW 明显更高,而体积仅在颞叶减少。在基线时,iFW 和体积都不能区分 CHR-P 和 CHR-NP 组。然而,在许多大脑区域,CHR-P 组随时间的变化明显快于 CHR-NP 组(iFW 增加和体积减少)。皮质厚度提供了与体积相似的结果,WM 微观结构没有明显变化。我们的研究结果表明,处于 CHR 的个体的 GM 微观结构变化比体积变化或微观结构 WM 变化更广泛,并且这些变化早于精神病发作前后大脑变化的加速。因此,反映在增加的 iFW 中的 GM 微观结构变化是精神病前驱期的早期病理学,可能有助于更好地理解精神病的发展机制。
