Distinct Hippocampal Subfields Atrophy in Older People With Vascular Brain Injuries.

BACKGROUND AND PURPOSE: Many neurological or psychiatric diseases affect the hippocampus during aging. The study of hippocampal regional vulnerability may provide important insights into the pathophysiological mechanisms underlying these processes; however, little is known about the specific impact of vascular brain damage on hippocampal subfields atrophy. METHODS: To analyze the effect of vascular injuries independently of other pathological conditions, we studied a population-based cohort of nondemented older adults, after the exclusion of people who were diagnosed with neurodegenerative diseases during the 14-year clinical follow-up period. Using an automated segmentation pipeline, 1.5T-magnetic resonance imaging at inclusion and 4 years later were assessed to measure both white matter hyperintensities and hippocampal subfields volume. Annualized rates of white matter hyperintensity progression and annualized rates of hippocampal subfields atrophy were then estimated in each participant. RESULTS: We included 249 participants in our analyses (58% women, mean age 71.8, median Mini-Mental State Evaluation 29). The volume of the subiculum at baseline was the only hippocampal subfield volume associated with total, deep/subcortical, and periventricular white matter hyperintensity volumes, independently of demographic variables and vascular risk factors (ß=-0.17, P=0.011; ß=-0.25, P=0.020 and ß=-0.14, P=0.029, respectively). In longitudinal measures, the annualized rate of subiculum atrophy was significantly higher in people with the highest rate of deep/subcortical white matter hyperintensity progression, independently of confounding factors (ß=-0.32, P=0.014). CONCLUSIONS: These cross-sectional and longitudinal findings highlight the links between vascular brain injuries and a differential vulnerability of the subiculum within the hippocampal loop, unbiased of the effect of neurodegenerative diseases, and particularly when vascular injuries affect deep/subcortical structures.

Clinical Neurology in Practice: The Tongue (part 2).

BACKGROUND: The tongue is an essential organ for the development of certain crucial functions such as swallowing and speech. The examination of the tongue can be very useful in neurology, as the various types of lingual alterations can lead to certain specific diagnoses, the tongue being a kind of 'mirror' of some neurological function. REVIEW SUMMARY: To discuss the elements of clinical examination of the tongue in relation to neurological disorders. After reviewing the different superficial lesions of the tongue, we deal with various movement disorders of the tongue (fasciculations/myokimia, orolingual tremor, choreic movements of the tongue, dystonia of the tongue, lingual myoclonus, and psychogenic movements), disorders of taste and lingual sensitivity and lingual pain. CONCLUSIONS: Examination of the tongue should not be limited to studying its motility and trophicity. It is equally important to check the sensory function and understand how to interpret abnormal movements involving the tongue. This study also aimed to demonstrate the importance of nonmotor tongue function in neurological practice.

Clinical Neurology in Practice: The Tongue (Part 1).

BACKGROUND: The tongue is an essential organ for the development of certain crucial functions, such as swallowing and language. The examination of the tongue can be very useful in neurology, as the various types of lingual alterations can lead to certain specific diagnoses, the tongue being a kind of "mirror" of some neurological function. REVIEW SUMMARY: In this study, we reviewed the literature on anatomy, physiology, and the various aspects of the examination of the tongue. CONCLUSIONS: Examination of the tongue should be an integral part of the clinical examination of the cranial nerves. This study aimed to demonstrate the importance of tongue motor and non-motor functions in neurological practice.

Acute peripheral neuropathy following animal envenomation: A case report and systematic review.

Animal envenomation in humans is usually accidental or for defensive purposes. Depending on the venom composition and administration, different reactions can be observed. After reporting the first case of acute polyradiculitis in a 57-year-old healthy male after red lionfish envenomation, we propose to analyze rare similar cases of acute neuritis after animal envenomation published in the medical literature. Including our case, we found 54 patients who developed acute peripheral neuropathy after having been stung or bitten by various animals, mainly hymenoptera (in half of the cases) but also jellyfishes, snakes, corals or nonhooked arthropods. We observed two distinct patterns of peripheral neuropathy: more than half of them were polyneuropathy while the others were focal neuropathy. The prognosis was favorable in most cases. The pathophysiological mechanism associated with these rare complications remain unknown, although some hypotheses may be proposed. A direct action of certain components of the venom, such as phospholipase-A2, could explain the focal forms of peripheral neuropathy trough toxic reactions and/or vasculitis processes. The more diffuse clinical situations could be due to an allergy-triggered immune-mediated reaction (possibly linked to a molecular mimicry mechanism between venom proteins and some myelin proteins of the peripheral nervous system), or to the action of some venom components on membrane ionic channels particularly at the node of Ranvier. Even if acute peripheral neuropathies are rare after envenomation, they may occur after envenomation from various animals, and their usually favorable prognoses should be known by neurologists.

Differential annualized rates of hippocampal subfields atrophy in aging and future Alzheimer's clinical syndrome.

Several studies have investigated the differential vulnerability of hippocampal subfields during aging and Alzheimer's disease (AD). Results were often contradictory, mainly because these works were based on concatenations of cross-sectional measures in cohorts with different ages or stages of AD, in the absence of a longitudinal design. Here, we investigated 327 participants from a population-based cohort of nondemented older adults with a 14-year clinical follow-up. MRI at baseline and 4 years later were assessed to measure the annualized rates of hippocampal subfields atrophy in each participant using an automatic segmentation pipeline with subsequent quality control. On the one hand, CA4 dentate gyrus was significantly more affected than the other subfields in the whole population (CA1-3: -0.68%/year; subiculum: -0.99%/year; and CA4-DG: -1.39%/year; p < 0.0001). On the other hand, the annualized rate of CA1-3 atrophy was associated with an increased risk of developing Alzheimer's clinical syndrome over time, independently of age, gender, educational level, and ApoE4 genotype (HR = 2.0; CI 95% 1.4-3.0). These results illustrate the natural history of hippocampal subfields atrophy during aging and AD by showing that the dentate gyrus is the most vulnerable subfield to the effects of aging while the cornu-ammonis is the primary target of AD pathophysiological processes, years before symptom onset.

Papilledema and Peripheral Neuropathies.

INTRODUCTION: Papilledema is a common sign in ophthalmology and is typically associated with increased intracranial pressure (ICP) in neurological diseases. Since the beginning of the 20th century, some cases of papilledema have been reported in association with acute or chronic inflammatory neuropathies. CASE REPORT: We describe a 42-year-old man with acute-onset inflammatory polyradiculoneuropathy and bilateral papilledema. CONCLUSIONS: Based on a personal case report and from an extensive review of the medical literature, we identify 2 distinct patterns. First, radiculoneuropathy may be a consequence of intracranial pressure (peripheral nerve involvement corresponding to a "false localizing sign"). Second, papilledema may occur after the onset of inflammatory neuropathy. For such cases, the pathophysiological mechanism remains unknown (eg, reactional inflammatory processes or actions of unknown autoantibodies) and requires further elucidation.