Hereditary primary lateral sclerosis and progressive nonfluent aphasia.

OBJECTIVE: To report a kindred with an association between hereditary primary lateral sclerosis (PLS) and progressive nonfluent aphasia. PATIENTS AND METHODS: Six members from a kindred with 15 affected individuals spanning three generations, suffered from spasticity without muscle atrophy or fasciculation, starting in the lower limbs and spreading to the upper limbs and bulbar musculature, followed by effortful speech, nonfluent language and dementia, in 5 deceased members. Disease onset was during the sixth decade of life, or later. Cerebellar ataxia was the inaugural manifestation in two patients, and parkinsonism, in another. RESULTS: Neuropathological examination in two patients demonstrated degeneration of lateral corticospinal tracts in the spinal cord, without loss of spinal, brainstem, or cerebral motor neurons. Greater loss of corticospinal fibers at sacral and lumbar, rather than at cervical or medullary levels was demonstrated, supporting a central axonal dying-back pathogenic mechanism. Marked reduction of myelin and nerve fibers in the frontal lobes was also present. Argyrophilic grain disease and primary age-related tauopathy were found in one case each, and considered incidental findings. Genetic testing, including exome sequencing aimed at PLS, ataxia, hereditary spastic paraplegia, and frontotemporal lobe dementia, triplet-repeated primed polymerase chain reaction aimed at dominant spinocerebellar ataxias, and massive sequencing of the human genome, yielded negative results. CONCLUSION: A central distal axonopathy affecting the corticospinal tract, exerted a pathogenic role in the dominantly inherited PLS-progressive nonfluent aphasia association, described herein. Further molecular studies are needed to identify the causative mutation in this disease.

Electrophysiology and optical coherence tomography to evaluate Parkinson disease severity.

PURPOSE: To evaluate correlations between visual evoked potentials (VEP), pattern electroretinogram (PERG), and macular and retinal nerve fiber layer (RNFL) thickness measured by optical coherence tomography (OCT) and the severity of Parkinson disease (PD). METHODS: Forty-six PD patients and 33 age and sex-matched healthy controls were enrolled, and underwent VEP, PERG, and OCT measurements of macular and RNFL thicknesses, and evaluation of PD severity using the Hoehn and Yahr scale to measure PD symptom progression, the Schwab and England Activities of Daily Living Scale (SE-ADL) to evaluate patient quality of life (QOL), and disease duration. Logistical regression was performed to analyze which measures, if any, could predict PD symptom progression or effect on QOL. RESULTS: Visual functional parameters (best corrected visual acuity, mean deviation of visual field, PERG positive (P) component at 50 ms -P50- and negative (N) component at 95 ms -N95- component amplitude, and PERG P50 component latency) and structural parameters (OCT measurements of RNFL and retinal thickness) were decreased in PD patients compared with healthy controls. OCT measurements were significantly negatively correlated with the Hoehn and Yahr scale, and significantly positively correlated with the SE-ADL scale. Based on logistical regression analysis, fovea thickness provided by OCT equipment predicted PD severity, and QOL and amplitude of the PERG N95 component predicted a lower SE-ADL score. CONCLUSIONS: Patients with greater damage in the RNFL tend to have lower QOL and more severe PD symptoms. Foveal thicknesses and the PERG N95 component provide good biomarkers for predicting QOL and disease severity.

Distribution of retinal layer atrophy in patients with Parkinson disease and association with disease severity and duration.

PURPOSE: To evaluate the thickness of the 10 retinal layers in the paramacular area of Parkinson disease patients using a new segmentation technology of optical coherence tomography (OCT) to examine whether the thickness of specific layers predicts neurodegeneration or Parkinson disease severity. DESIGN: Observational prospective study. METHODS: Parkinson disease patients (n = 129) and age-matched healthy subjects (n = 129) were enrolled. The Spectralis OCT system was used to automatically segment all retinal layers in a parafoveal scan using the new segmentation application prototype. Mean thickness of each layer was calculated and compared between Parkinson disease patients and healthy subjects, and between Parkinson disease patients with disease durations of less than or at least 10 years. A correlation analysis was performed to evaluate the association between retinal layer thickness, duration of disease, and Parkinson disease severity. Logistic regression analysis was performed to determine the most sensitive layer for predicting axonal atrophy. RESULTS: Parkinson disease patients showed statistically significant reduced thickness in the retinal nerve fiber, ganglion cell, inner plexiform, and outer plexiform layers and increased thickness in the inner nuclear layer compared with healthy subjects (P < .05). The inner retinal layers were more affected in Parkinson disease patients with long disease duration. The ganglion cell layer thickness was inversely correlated with disease duration and Parkinson disease severity, and was predictive of axonal damage in Parkinson disease patients. CONCLUSIONS: The segmentation application of the Spectralis OCT revealed retinal layer atrophy in Parkinson disease patients, especially in the inner layers of patients with long disease duration. Ganglion cell layer reduction was associated with increased axonal damage.