Cerebellar Disorders and Ataxias: Acquired Disorders

Disorders of the cerebellum or its connections can result in ataxia characterized by imbalance and incoordination of gait, limbs, speech, and eye movements. The pathologic changes may be confined to the cerebellum or simultaneously affect other parts of the central nervous system or peripheral nervous system. Ataxias are generally classified as acquired, inherited, or sporadic. The differential diagnosis is broad and daunting. However, a detailed history and examination can rapidly narrow the list. Key information includes age at onset; rate of disease progression; family history; presence of pure cerebellar syndrome or other neurologic signs; other systemic features; and imaging findings.

Cerebellar Disorders and Ataxias: Inherited Disorders

Disorders of the cerebellum or its circuitry can result in ataxia. These disorders may be acquired or inherited. Inherited ataxias may be autosomal recessive (eg. Friedrich ataxia), autosomal dominant (eg, spinal cerebellar atrophy) or X linked (eg, fragile X–associated ataxia syndrome). Chapter 73 (“Cerebellar Disorders and Ataxias: Acquired Disorders”) reviews the clinical approach to patients with ataxia and discusses acquired forms of ataxia. This chapter reviews clinical approaches, diagnostic details, and treatment of inherited ataxias.

A case of red nucleus and hillock syndrome

Th. Dosuzkov in Revue v neurologii i psychiatrii, 1928, no. In addition to the presence of semi-paresis, sensory disturbances, pain, intentional tremor, the author indicates cerebellar disorders on the same side, changes in local setting reflexes on both sides, and on the part of the psyche, euphoria and mild dementia.

Identification of the Prodromal Symptoms and Pre-Ataxic Stage in Cerebellar Disorders: The Next Challenge

Cerebellar ataxias (CAs) manifest with a combination of motor incoordination, cognitive, affective and recently identified social symptoms. Novel therapies aim to stop the progression of the subgroup of the degenerative ataxias, or even to cure the disease with a functional and anatomical restoration of the cerebellar circuitry in the near future. The goal of stopping the progression of the disease is particularly relevant if applied at a very early stage of the disease, when the cerebellar reserve is only slightly impaired. Therefore, the search of the prodromal phase or pre-ataxic stage of CAs represents a very important challenge for the scientific community. The identification of pre-manifest individuals and the recruitment of individuals at risk has become a key-challenge to address neuroprotective therapies. The feasibility is high due to the recent progress in the biological and morphological biomarkers of CAs.

Hypoparathyroidism and Fahr’s syndrome: case series

Hypoparathyroidism (HP) is a rare metabolic disorder and causes hypocalcemia because parathyroid hormone secretion is inadequate to mobilize calcium from bone and reabsorb calcium from kidney and gut. Anterior neck surgery is the most common cause of acquired HP and autoimmune HP is the next most common form in adults. The duration, severity, and rate of development of hypocalcemia determine the clinical presentation. A variety of organs can be affected by calcification, more frequently kidneys, but also joints, eyes, skin, vasculature, and other organ systems and, although rarely seen, intracerebral calcifications. Case series: We report four cases of bilateral basal ganglia calcifications (BGC) also known as Fahr’s syndrome related to hypoparathyroidism. Discussion: Fahr’s syndrome is characterized by bilateral symmetrical calcification of areas of the brain that control movements including basal ganglia, thalamus, and others; it is a rare inherited or sporadic neurological disorder with a prevalence of less than 1/1.000.000. Main symptoms related to bilateral BGC include extra-pyramidal and cerebellar disorders, cognitive impairment, epileptic seizures, and psychiatric changes. BGC has been established as a possible outcome of HP. Its prevalence, demonstrated in the HP cohorts, varied significantly from 12 up to 74%. Currently, computed tomography (CT) is the most valuable method for diagnosis. The treatment include symptomatic support and identification of causes, but there is no specific treatment limiting the progression of calcification in the basal ganglia. Especially in HP, an early treatment can prevent calcification and neurophysiological disorders.

Time-dependent diffusion MRI probes cerebellar microstructural alterations in a mouse model of Down syndrome

The cerebellum is a complex system with distinct cortical laminar organization. Alterations in cerebellar microstructure are common and associated with many factors such as genetics, cancer and ageing. Diffusion MRI (dMRI) provides a non-invasive tool to map the brain structural organization, and the recently proposed diffusion-time (td)-dependent dMRI further improves its capability to probe the cellular and axonal/dendritic microstructures by measuring water diffusion at multiple spatial scales. The td-dependent diffusion profile in the cerebellum and its utility in detecting cerebellar disorders, however, are not yet elucidated. Here, we first deciphered the spatial correspondence between dMRI contrast and cerebellar layers, based on which the cerebellar layer-specific td-dependent dMRI patterns were characterized in both euploid and Ts65Dn mice, a mouse model of Down syndrome. Using oscillating gradient dMRI, which accesses diffusion at short td’s by modulating the oscillating frequency, we detected subtle changes in the apparent diffusivity coefficient of the cerebellar internal granular layer and Purkinje cell layer of Ts65Dn mice that were not detectable by conventional pulsed gradient dMRI. The detection sensitivity of oscillating gradient dMRI increased with the oscillating frequency at both the neonatal and adult stages. The td-dependence, quantified by ΔADC map, was reduced in Ts65Dn mice, likely associated with the reduced granule cell density and abnormal dendritic arborization of Purkinje cells as revealed from histological evidence. Our study demonstrates superior sensitivity of short-td diffusion using oscillating gradient dMRI to detect cerebellar microstructural changes in Down syndrome, suggesting the potential application of this technique in cerebellar disorders.