Mercury is present in neurons and oligodendrocytes in regions of the brain affected by Parkinson’s disease and co-localises with Lewy bodies

Objective Environmental toxicants are suspected to play a part in the pathogenesis of idiopathic Parkinson’s disease (PD) and may underlie its increasing incidence. Mercury exposure in humans is common and is increasing due to accelerating levels of atmospheric mercury, and mercury damages cells via oxidative stress, cell membrane damage, and autoimmunity, mechanisms suspected in the pathogenesis of PD. We therefore compared the cellular distribution of mercury in the tissues of people with and without PD who had evidence of previous mercury exposure by mercury being present in their locus ceruleus neurons. Materials and methods Paraffin sections from the brain and general organs of two people with PD, two people without PD with a history of mercury exposure, and ten people without PD or known mercury exposure, were stained for inorganic mercury using autometallography, combined with immunostaining for a-synuclein and glial cells. All had mercury-containing neurons in locus ceruleus neurons. Laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) was used to confirm the presence of mercury and to look for other potentially toxic elements. Autometallography-stained locus ceruleus paraffin sections were examined to compare the frequency of previous mercury exposure between 20 PD and 40 non-PD individuals. Results In PD brains, autometallography-detected mercury was seen in neurons affected by the disease, such as those in the substantia nigra, motor cortex, striatum, thalamus, and cerebellum. Mercury was seen in oligodendrocytes in white and grey matter. Mercury often co-localised with Lewy bodies and neurites. A more restricted distribution of brain mercury was seen in people without PD (both with or without known mercury exposure), with no mercury present in the substantia nigra, striatum, or thalamus. The presence of autometallography-detected mercury in PD was confirmed with LA-ICP-MS, which demonstrated other potentially toxic metals in the locus ceruleus and high iron levels in white matter. Autometallography-detected mercury was found in locus ceruleus neurons in a similar proportion of PD (65%) and non-PD (63%) individuals. Conclusions In people with PD, mercury was found in neurons and oligodendrocytes in regions of the brain that are affected by the disease, and often co-localised with aggregated a-synuclein. Mercury in the motor cortex, thalamus and striatum could result in bradykinesia and rigidity, and mercury in the cerebellum could cause tremor. People without PD had a restricted uptake of mercury into the brain. The similar frequency of mercury in the locus ceruleus of people with and without PD suggests these two groups have had comparable previous mercury exposures but that PD brains have a greater predisposition to take up circulating mercury. While this post mortem study does not provide a direct link between mercury and idiopathic PD, it adds to the body of evidence that metal toxicants such as mercury play a role in the disease. A precautionary approach would be to reduce rising mercury levels in the atmosphere by limiting the burning of fossil fuels, which may be contributing to the increasing incidence of PD.

Parkinson’s Disease and Gut Microbiota

<b><i>Background:</i></b> Parkinson’s disease (PD) is caused by abnormal aggregation of α-synuclein fibrils, called the Lewy bodies, in the central nervous system. Accumulating knowledge points to the notion that α-synuclein fibrils start from the dorsal vagal nucleus and ascend to the locus ceruleus and the substantia nigra (SN). Even in healthy elderly subjects without motor or cognitive impairment, α-synuclein fibrils are frequently observed in the brain and sometimes in the intestinal neural plexus. Enteroendocrine cells have a direct synapse to the vagal afferents, and the vagal nucleus has synaptic pathways to the SN and the striatum. Intestinal bacteria are likely to be involved in the formation of intestinal α-synuclein fibrils. <b><i>Summary:</i></b> A nonparametric meta-analysis of intestinal microbiota in PD in 5 countries, as well as scrutinization of the other reports from the other countries, indicates that mucin-degrading <i>Akkermansia</i> is increased in PD and that short-chain fatty acid (SCFA)-producing bacteria are decreased in PD. Both dysbiosis should increase the intestinal permeability, which subsequently facilitates exposure of the intestinal neural plexus to toxins like lipopolysaccharide and pesticide, which should lead to abnormal aggregation of α-synuclein fibrils. Decreased SCFA also downregulates regulatory T cells and fails to suppress neuronal inflammation. <b><i>Key Messages:</i></b> Therapeutic intervention may be able to be established against these mechanisms. Additional biochemical, cellular, and animal studies are required to further dissect the direct association between intestinal microbiota and PD.

Deep brain stimulation for treatment of Parkinson’s disease

Introduction: Parkinson’s disease (PD) is a degenerative and chronic disorder that affects the central nervous system. It occurs due to the degeneration of neurons in the ventral layer of the compact part of the substance nigra and the locus ceruleus, for reasons still unknown. As a result, there is a decrease in dopamine, causing the classic manifestations of the disease, mainly motor. Deep Cerebral Stimulation (ECP) is a therapeutic modality that emerged in the 1980s and has achieved quite satisfactory results in the treatment of PD, especially in more advanced cases and / or refractory to drug treatment. Objectives: To analyze the effectiveness of ECP for the treatment of PD. Methodology: This study consists of an integrative review through the selection of eight articles published randomly between 2017 and 2021 on the platforms PubMed and Google Scholar, using the descriptors “Parkinson’s Disease” and “Deep Brain Stimulation” in the English and Portuguese languages. Results: It is seen that the symptoms of PD are related to the reduction of activation of areas such as motor cortex, substance nigra and globe palidum. In this sense, ECP uses the application of constant or intermittent electrical current, of low intensity and high frequency. Such a stimulus is capable of inhibiting the activity of the subthalamic nucleus or pale globe, among other regions, resulting in significant improvement of symptoms. On the other hand, some recent studies have identified a risk, albeit low, of post-procedure movement limitations, deaths from infections and increased suicides. Conclusion: There was an improvement in physical symptoms, as well as a significant decrease in the frequency of dementia, depression and psychological problems, with the ECP being a safe and effective procedure for the treatment of PD.

On the Emergence of Tremor in Prodromal Parkinson’s Disease

Clinical, neuropathological and neuroimaging research suggests that pathological changes in Parkinson’s disease (PD) start many years before the emergence of motor signs. Since disease-modifying treatments are likely to be most effective when initiated early in the disease process, there has been significant interest in characterizing prodromal PD. Some people with PD describe autonomic symptoms at the time of diagnosis suggesting that autonomic dysfunction is a common feature of prodromal PD. Furthermore, subtle motor signs may be present and emerge prior to the time of diagnosis. We present a series of patients who, in the prodromal phase of PD, experienced the emergence of tremor initially only while yawning or straining at stool and discuss how early involvement of autonomic brainstem nuclei could lead to these previously unreported phenomena. The hypothalamic paraventricular nucleus (PVN) plays a central role in autonomic control including bowel/bladder function, cardiovascular homeostasis and yawning and innervates multiple brainstem nuclei involved in autonomic functions (including brainstem reticular formation, locus ceruleus, dorsal raphe nucleus and motor nucleus of the vagus). The PVN is affected in PD and evidence from related phenomena suggest that the PVN could increase tremor either by increasing downstream cholinergic activity on brainstem nuclei such as the reticular formation or by stimulating the locus ceruleus to activate the cerebellothalamocortical network via the ventrolateral nucleus of the thalamus. Aberrant cholinergic/noradrenergic transmission between these brainstem nuclei early in PD couldlead to tremor before the emergence of other parkinsonian signs, representing an early clinical clue to prodromal PD.

Concurrent brain structural and functional alterations in patients with migraine without aura: an fMRI study

Objectives To explore the possible concurrent brain functional and structural alterations in patients with migraine without aura (MwoA) patients compared to healthy subjects (HS). Methods Seventy-two MwoA patients and forty-six HS were recruited. 3D-T1 and resting state fMRI data were collected during the interictal period for MwoA and HS. Voxel-based morphometry (VBM) for structure analysis and regional homogeneity (Reho) for fMRI analysis were applied. The VBM and Reho maps were overlapped to determine a possible brain region with concurrent functional and structural alteration in MwoA patients. Further analysis of resting state functional connectivity (FC) alteration was applied with this brain region as the seed. Results Compared with HS, MwoA patients showed decreased volume in the bilateral superior and inferior colliculus, periaqueductal gray matter (PAG), locus ceruleus, median raphe nuclei (MRN) and dorsal pons medulla junction. MwoA patients showed decreased Reho values in the middle occipital gyrus and inferior occipital gyrus, and increased Reho values in the MRN. Only a region in the MRN showed both structural and functional alteration in MwoA patients. Pearson correlation analysis showed that there was no association between volume or Reho values of the MRN and headache frequency, headache intensity, disease duration, self-rating anxiety scale or self-rating depression scale in MwoA patients. Resting state functional connectivity (FC) with the MRN as the seed showed that MwoA patients had increased FC between the MRN and PAG. Conclusions MRN are involved in the pathophysiology of migraine during the interictal period. This study may help to better understand the migraine symptoms. Trial registration NCT01152632. Registered 27 June 2010.

Concurrent Brain Structural and Functional Alterations in Patients with Migraine without Aura: An fMRI Study

Objectives: To explore the possible concurrent brain functional and structural alterations in patients with migraine without aura (MwoA) patients compared to healthy subjects (HS). Methods: Seventy-two MwoA patients and forty-six HS were recruited. 3D-T1 and resting state fMRI data were collected during the interictal period for MwoA and HS. Voxel-based morphometry (VBM) for structure analysis and regional homogeneity (Reho) for fMRI analysis were applied. The VBM and Reho maps were overlapped to determine a possible brain region with concurrent functional and structural alteration in MwoA patients. Further analysis of resting state functional connectivity (FC) alteration was applied with this brain region as the seed.Results: Compared with HS, MwoA patients showed decreased volume in the bilateral superior and inferior colliculus, periaqueductal gray matter (PAG), locus ceruleus, median raphe nuclei (MRN) and dorsal pons medulla junction. MwoA patients showed decreased Reho values in the middle occipital gyrus and inferior occipital gyrus, and increased Reho values in the MRN. Only a region in the MRN showed both structural and functional alteration in MwoA patients. Pearson correlation analysis showed that there was no association between volume or Reho values of the MRN and headache frequency, headache intensity, disease duration, self-rating anxiety scale or self-rating depression scale in MwoA patients. Resting state functional connectivity (FC) with the MRN as the seed showed that MwoA patients had increased FC between the MRN and PAG.Conclusions: MRN are involved in the pathophysiology of migraine during the interictal period. This study may help to better understand the migraine symptoms.Trial registration: NCT01152632. Registered 27 June 2010.