Waisman Center, University of Wisconsin-Madison, 1500 Highland Avenue, Madison, WI, 53705, USA.
Neuroscience Training Program, University of Wisconsin-Madison, Madison, WI, USA.
Mol Autism. 2022 Dec 19;13(1):48. doi: 10.1186/s13229-022-00524-3.
Elevated or reduced responses to sensory stimuli, known as sensory features, are common in autistic individuals and often impact quality of life. Little is known about the neurobiological basis of sensory features in autistic children. However, the brainstem may offer critical insights as it has been associated with both basic sensory processing and core features of autism.
Diffusion-weighted imaging (DWI) and parent-report of sensory features were acquired from 133 children (61 autistic children with and 72 non-autistic children, 6-11 years-old). Leveraging novel DWI processing techniques, we investigated the relationship between sensory features and white matter microstructure properties (free-water-elimination-corrected fractional anisotropy [FA] and mean diffusivity [MD]) in precisely delineated brainstem white matter tracts. Follow-up analyses assessed relationships between microstructure and sensory response patterns/modalities and analyzed whole brain white matter using voxel-based analysis.
Results revealed distinct relationships between brainstem microstructure and sensory features in autistic children compared to non-autistic children. In autistic children, more prominent sensory features were generally associated with lower MD. Further, in autistic children, sensory hyporesponsiveness and tactile responsivity were strongly associated with white matter microstructure in nearly all brainstem tracts. Follow-up voxel-based analyses confirmed that these relationships were more prominent in the brainstem/cerebellum, with additional sensory-brain findings in the autistic group in the white matter of the primary motor and somatosensory cortices, the occipital lobe, the inferior parietal lobe, and the thalamic projections.
All participants communicated via spoken language and acclimated to the sensory environment of an MRI session, which should be considered when assessing the generalizability of this work to the whole of the autism spectrum.
These findings suggest unique brainstem white matter contributions to sensory features in autistic children compared to non-autistic children. The brainstem correlates of sensory features underscore the potential reflex-like nature of behavioral responses to sensory stimuli in autism and have implications for how we conceptualize and address sensory features in autistic populations.
在自闭症患者中,对感觉刺激的反应升高或降低(即感觉特征)较为常见,且常影响生活质量。目前对于自闭症儿童感觉特征的神经生物学基础知之甚少。然而,脑干可能为我们提供关键的见解,因为它与基本感觉处理以及自闭症的核心特征均有关联。
对 133 名儿童(61 名自闭症儿童和 72 名非自闭症儿童,年龄 6-11 岁)进行弥散张量成像(DWI)和家长报告的感觉特征评估。利用新颖的 DWI 处理技术,我们在精确勾画的脑干白质束中研究了感觉特征与白质微观结构特性(自由水消除校正的各向异性分数[FA]和平均扩散系数[MD])之间的关系。后续分析评估了微观结构与感觉反应模式/模态之间的关系,并使用基于体素的分析方法对全脑白质进行了分析。
结果表明,与非自闭症儿童相比,自闭症儿童的脑干微观结构与感觉特征之间存在明显的关系。在自闭症儿童中,更明显的感觉特征通常与 MD 降低相关。此外,在自闭症儿童中,感觉反应迟钝和触觉反应与几乎所有脑干束中的白质微观结构密切相关。后续的基于体素的分析证实,这些关系在脑干/小脑中更为显著,而自闭症组的额外感觉脑发现存在于初级运动和躯体感觉皮层、枕叶、下顶叶以及丘脑投射的白质中。
所有参与者均通过口语进行交流并适应了 MRI 检查的感觉环境,在评估这项工作对自闭症谱系的普遍性时应考虑到这一点。
这些发现表明,与非自闭症儿童相比,自闭症儿童的脑干白质对感觉特征有独特的贡献。感觉特征的脑干相关性强调了自闭症患者对感觉刺激的行为反应具有潜在的反射性质,对我们如何概念化和解决自闭症人群中的感觉特征具有影响。
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