Multimodal layer modelling reveals in vivo pathology in amyotrophic lateral sclerosis.
Northall A., Doehler J., Weber M., Tellez I., Petri S., Prudlo J., Vielhaber S., Schreiber S., Kuehn E.
Amyotrophic lateral sclerosis (ALS) is a rapidly progressing neurodegenerative disease characterised by the loss of motor control. Current understanding of ALS pathology is largely based on post-mortem investigations at advanced disease stages. A systematic in-vivo description of the microstructural changes that characterise early-stage ALS, and their subsequent development, is so far lacking. Recent advances in ultra-high field (7 T) MRI data modelling allow us to investigate cortical layers in-vivo. Given the layer-specific and topographic signature of pathology in ALS, we combined submillimeter structural 7T-MRI data (qT1, QSM), functional localisers of body parts (upper limb, lower limb, face) and automated layer modelling to systematically describe pathology in the primary motor cortex (M1), in 12 living ALS-patients with reference to 12 age-, gender-, handedness- and education-matched controls. Longitudinal sampling was performed for a subset of patients. We calculated multimodal pathology maps for each layer (superficial layer, layer 5a, layer 5b, layer 6) of M1 to identify hotspots of demyelination, iron and calcium accumulation in different cortical fields. We show preserved mean cortical thickness and layer architectures of M1, despite significantly increased iron in layer 6 and significantly increased calcium in layer 5a and superficial layer, in patients compared to controls. The behaviorally first-affected cortical field shows significantly increased iron in L6 compared to other fields, while calcium accumulation is atopographic and significantly increased in the low-myelin borders between cortical fields compared to the fields themselves. A subset of patients with longitudinal data shows that the low-myelin borders are particularly disrupted, and that calcium hotspots but to a lesser extent iron hotspots precede demyelination. Finally, we highlight that a very-slow progressing patient (P4) shows a distinct pathology profile compared to the other patients. Our data shows that layer-specific markers of in-vivo pathology can be identified in ALS-patients with a single 7T-MRI measurement after first diagnosis, and that such data provide critical insights into the individual disease state. Our data highlight the non-topographic architecture of ALS disease spread, and the role of calcium rather than iron accumulation in predicting future demyelination. We also highlight a potentially important role of low-myelin borders, that are known to connect to multiple areas within the M1 architecture, in disease spread. Importantly, the distinct pathology profile of a very-slow progressing patient (P4) highlights a distinction between disease duration and pathology progression. Our findings demonstrate the importance of in-vivo histology for the diagnosis and prognosis of neurodegenerative diseases such as ALS.