超越常规:寻找神经退行性疾病机制的多因素计算模型。

IF 5.8 1区 医学 Q1 PSYCHIATRY Translational Psychiatry Pub Date : 2024-09-23 DOI:10.1038/s41398-024-03073-w
Ahmed Faraz Khan, Yasser Iturria-Medina
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引用次数: 0

摘要

从阿尔茨海默病到肌萎缩侧索硬化症,人们对神经退行性疾病的分子级联仍然知之甚少。神经退行性疾病的临床表现几乎与每位患者的症状异质性和混合病理学相混淆。虽然潜在的生理改变可能在症状出现前几十年就已经开始、扩散和传播,但活体大脑的复杂性和不可接近性限制了对患者整个生命周期的直接观察。因此,亟需强有力的计算方法,通过区分致病过程和后果性改变,以及个体间变异和个体内进展,来支持神经退行性变因果机制的研究。最近,基于活体神经成像和生物样本标记的数据驱动型大脑时空建模取得了令人鼓舞的进展。这些方法包括比较各种生物标志物时间演变的疾病进展模型、连接相互作用的生物过程的因果模型、再现病理空间扩散的网络传播模型,以及涵盖细胞到网络规模现象的生物物理模型。在这篇综述中,我们讨论了整合横断面、纵向和多模态数据(主要来自大型神经影像观察研究)的各种计算方法,以了解(i) 生理改变的时间顺序,(i) 它们与大脑分子和细胞结构的空间关系,(iii) 生物过程之间的机理相互作用,以及 (iv) 微观因素的宏观效应。我们考虑了计算模型在多大程度上可以评估机理假设,探讨了改进治疗选择等应用,并讨论了以模型为基础的见解如何为神经退行性疾病的病理生物学重新定义奠定基础。
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Beyond the usual suspects: multi-factorial computational models in the search for neurodegenerative disease mechanisms.

From Alzheimer's disease to amyotrophic lateral sclerosis, the molecular cascades underlying neurodegenerative disorders remain poorly understood. The clinical view of neurodegeneration is confounded by symptomatic heterogeneity and mixed pathology in almost every patient. While the underlying physiological alterations originate, proliferate, and propagate potentially decades before symptomatic onset, the complexity and inaccessibility of the living brain limit direct observation over a patient's lifespan. Consequently, there is a critical need for robust computational methods to support the search for causal mechanisms of neurodegeneration by distinguishing pathogenic processes from consequential alterations, and inter-individual variability from intra-individual progression. Recently, promising advances have been made by data-driven spatiotemporal modeling of the brain, based on in vivo neuroimaging and biospecimen markers. These methods include disease progression models comparing the temporal evolution of various biomarkers, causal models linking interacting biological processes, network propagation models reproducing the spatial spreading of pathology, and biophysical models spanning cellular- to network-scale phenomena. In this review, we discuss various computational approaches for integrating cross-sectional, longitudinal, and multi-modal data, primarily from large observational neuroimaging studies, to understand (i) the temporal ordering of physiological alterations, i(i) their spatial relationships to the brain's molecular and cellular architecture, (iii) mechanistic interactions between biological processes, and (iv) the macroscopic effects of microscopic factors. We consider the extents to which computational models can evaluate mechanistic hypotheses, explore applications such as improving treatment selection, and discuss how model-informed insights can lay the groundwork for a pathobiological redefinition of neurodegenerative disorders.

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来源期刊
CiteScore
11.50
自引率
2.90%
发文量
484
审稿时长
23 weeks
期刊介绍: Psychiatry has suffered tremendously by the limited translational pipeline. Nobel laureate Julius Axelrod''s discovery in 1961 of monoamine reuptake by pre-synaptic neurons still forms the basis of contemporary antidepressant treatment. There is a grievous gap between the explosion of knowledge in neuroscience and conceptually novel treatments for our patients. Translational Psychiatry bridges this gap by fostering and highlighting the pathway from discovery to clinical applications, healthcare and global health. We view translation broadly as the full spectrum of work that marks the pathway from discovery to global health, inclusive. The steps of translation that are within the scope of Translational Psychiatry include (i) fundamental discovery, (ii) bench to bedside, (iii) bedside to clinical applications (clinical trials), (iv) translation to policy and health care guidelines, (v) assessment of health policy and usage, and (vi) global health. All areas of medical research, including — but not restricted to — molecular biology, genetics, pharmacology, imaging and epidemiology are welcome as they contribute to enhance the field of translational psychiatry.
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