Lancet neurology
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Review Case Reports
Comorbidities, treatment, and pathophysiology in restless legs syndrome.
Restless legs syndrome, also known as Willis-Ekbom disease, is a common neurological condition whose manifestation is affected by complex environmental and genetic interactions. Restless legs syndrome can occur on its own, mostly at a young age, or with comorbidities such as cardiovascular disease, diabetes, and arterial hypertension, making it a difficult condition to properly diagnose. ⋯ Clinical studies on pregabalin, gabapentin enacarbil, oxycodone-naloxone, and iron preparations have provided new treatment options, but most patients still report inadequate long-term management of symptoms. Studies of the hypoxic pathway activation and iron deficiency have provided valuable information about the pathophysiology of restless legs syndrome that should now be translated into new, more effective treatments for restless legs syndrome.
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Neurological disorders are now the leading source of disability globally, and ageing is increasing the burden of neurodegenerative disorders, including Parkinson's disease. We aimed to determine the global burden of Parkinson's disease between 1990 and 2016 to identify trends and to enable appropriate public health, medical, and scientific responses. ⋯ Bill & Melinda Gates Foundation.
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The glymphatic (glial-lymphatic) pathway is a fluid-clearance pathway identified in the rodent brain in 2012. This pathway subserves the flow of CSF into the brain along arterial perivascular spaces and subsequently into the brain interstitium, facilitated by aquaporin 4 (AQP4) water channels. The pathway then directs flow towards the venous perivascular and perineuronal spaces, ultimately clearing solutes from the neuropil into meningeal and cervical lymphatic drainage vessels. In rodents, the glymphatic pathway is predominantly active during sleep, when the clearance of harmful metabolites such as amyloid β (Aβ) increases two-fold relative to the waking state. Glymphatic dysfunction, probably related to perturbed AQP4 expression, has been shown in animal models of traumatic brain injury, Alzheimer's disease, and stroke. The recent characterisations of the glymphatic and meningeal lymphatic systems in rodents and in humans call for revaluation of the anatomical routes for CSF-interstitial fluid flow and the physiological role that these pathways play in CNS health. ⋯ Several features of the glymphatic and meningeal lymphatic systems have been shown to be present in humans. MRI scans with intrathecally administered contrast agent show that CSF flows along pathways that closely resemble the glymphatic system outlined in rodents. Furthermore, PET studies have revealed that Aβ accumulates in the healthy brain after a single night of sleep deprivation, suggesting that the human glymphatic pathway might also be primarily active during sleep. Other PET studies have shown that CSF clearance of Aβ and tau tracers is reduced in patients with Alzheimer's disease compared with healthy controls. The observed reduction in CSF clearance was associated with increasing grey-matter concentrations of Aβ in the human brain, consistent with findings in mice showing that decreased glymphatic function leads to Aβ accumulation. Altered AQP4 expression is also evident in brain tissue from patients with Alzheimer's disease or normal pressure hydrocephalus; glymphatic MRI scans of patients with normal pressure hydrocephalus show reduced CSF tracer entry and clearance. WHERE NEXT?: Research is needed to confirm whether specific factors driving glymphatic flow in rodents also apply to humans. Longitudinal imaging studies evaluating human CSF dynamics will determine whether a causal link exists between reduced brain solute clearance and the development of neurodegenerative diseases. Assessment of glymphatic function after stroke or traumatic brain injury could identify whether this function correlates with neurological recovery. New insights into how behaviour and genetics modify glymphatic function, and how this function decompensates in disease, should lead to the development of new preventive and diagnostic tools and novel therapeutic targets.
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Nutrition is an important lifestyle factor that can modify the risk of future cognitive impairment and dementia. Some, but not conclusive, evidence (mostly from observational studies and infrequently from clinical trials) exists of a protective association between certain nutrients (eg, folate, flavonoids, vitamin D, and certain lipids) or food groups (eg, seafood, vegetables, and fruits, and potentially moderate alcohol and caffeine consumption) and cognitive outcomes in older people. For some nutrients and food groups, protection might be greater in individuals with either deficiencies in certain nutrients or a genetic predisposition to cognitive impairment. ⋯ At present, evidence of an association between nutrition and cognitive outcomes is somehow stronger for healthy dietary patterns, such as the Mediterranean-type diet, than for individual nutrients and food groups, possibly because of the cumulative beneficial effects of the many ingredients in these diets. Multidomain interventions (including a nutrition component) might also hold some promise for the prevention of cognitive impairment and dementia, but their effectiveness is still uncertain. Use of advanced technologies for nutrition assessment (eg, metabolomics and innovative methods of dietary intake assessment) and recently identified biomarkers of nutrition and neurobiological outcomes will be important to achieve this goal.