BACKGROUND: Chronic kidney disease (CKD) is one of the most common diseases in adult age and it is typical of older adults. Recent data suggest that almost half of the elders have CKD. It is now clear that CKD is accompanied, in the early stages, by cognitive impairment, together with depression and subtle abnormalities in motor control (such as gait and balance alterations). SUMMARY: Several data suggest a link between brain dopamine and kidney diseases. Metabolic syndrome and diabetes can affect dopamine neuron survival (leading to Parkinson’s Disease). Several uremic toxins in CKD (uric acid, indoxyl sulphate) and trace elements accumulating in CKD (aluminium, manganese) can also modify the dopaminergic system. Hormones produced by the kidney such as vitamin D are neuroprotective for dopamine neurons. Dopaminergic drugs are useful for the treatment of a common sleep disorder in CKD, the restless legs syndrome. However, experiments on animal models of CKD show conflicting results regarding a modification of dopamine neurons. KEY MESSAGES: Several observations suggest a limited relevance of the dopaminergic system in CKD-related cognitive impairment. However, a common sleep disturbance in CKD, the restless leg syndrome, improves with dopaminergic drugs. Therefore, it remains to be established the role of the dopamine system in subtle motor dysfunction observed in CKD, such as tremors, gait alterations, and central sleep apnea.
Background and Aims The glymphatic system is a network of extracellular spaces between neurons, glial cells, and capillaries that promotes the elimination of soluble molecules from the brain. Its dysfunction is probably relevant for neurodegenerative diseases such as Alzheimer's disease (AD). It is widely accepted that cognitive impairment accompanies chronic kidney disease (CKD). CKD is also a risk factor for dementia. However, the role of the glymphatic system in this process is unknown. A recent method to study the glymphatic system in human subjects has been proposed based on Diffusion Tensor Imaging (DTI) data and water diffusion calculation along with perivascular spaces. This approach is based on calculating a diffusion index named ALPS and showed that the glymphatic flow is reduced in MCI. Method To analyze the role of glymphatic system in CKD patients, we took advantage of the Alzheimer's Disease Neuroimaging Initiative (ADNI). ADNI is a longitudinal multicenter study helping researchers to monitor Alzheimer's disease and Mild Cognitive Impairment (MCI) progression. This database has a cohort of control patients and MCI patients, among which several patients with CKD stage II-III were identifiable from the creatinine values. Patients with Alzheimer's disease were excluded for this study. Among the control and MCI patients, we identified 12 CKD patients and pair-matched 12 non-CKD patients comparable for age, gender, and MoCA score. Magnetic resonance data with DTI sequences were retrieved for all patients, and the glymphatic system was characterized by the ALPS index. Tensor values were calculated using the FSL software; the diffusion values were calculated on tensor images using the ImageJ software. Differences in ALPS between CKD and non-CKD patients with and without MCI were tested. Results Analysis of DTI data confirmed that control patients without CKD had lower ALPS values when MCI was present compared to the non-MCI patients, suggesting a reduction of water diffusion in the glymphatic system. However, the presence of CKD had a different effect: in the absence of MCI, CKD did not modify ALPS values compared to non-CKD patients. At variance, in patients with MCI, CKD resulted in a significant increase of water diffusion in the glymphatic system compared to the controls. Conclusion In this preliminary study, MCI and CKD exerted opposite effects on the diffusion of water within the glymphatic system: MCI was accompanied by a reduction of water diffusion whereas CKD by an increased diffusion in the glymphatic spaces. It is possible that small modification of water balance in CKD may be responsible for the increased diffusion of water in glymphatics in CKD. Further studies are needed to verify whether this unexpected phenomenon may modify cognitive function with a mechanism rather different from Alzheimer's disease.
Background and Aims Chronic kidney disease (CKD) is a systemic condition because it modifies all organs' function due to an imbalance in plasma volume, electrolytes, hormones, and proteins. Indeed, at the nervous system level, mild cognitive impairment (MCI), sleep disorders and depression often accompany CKD. MCI partially explains the low quality of life of CKD patients, comparable to that of metastatic cancer patients. Mild Cognitive Impairment (MCI) has a high prevalence in this cohort (27-62%). Nevertheless, scattered literature data suggest that CKD patients can also have poor motor control, evidenced by a higher risk of falls, postural instability, reduced gait speed. In this cohort, few data are available regarding the motor circuits called central pattern generators, which control physiological tremor. Specifically, uraemic encephalopathy accentuates physiological tremor, which is regulated by central and peripheral oscillators. Overall, subtle changes in motor control often accompany other forms of MCI. Therefore, this study aimed at evaluating the effects of chronic kidney disease on cognitive and motor functions using up-to-date technologies to record physiological tremor and innovative data analysis. Method This retrospective case-control study enrolled 313 patients (139 controls, 79 CKD patients stage III-IV, 35 kidney transplant (Tx), 60 dialysis (HD) patients). These groups were comparable for age and weight. Creatininemia, azotemia, LDL, HDL, hemoglobin, and proteinuria were used for correlative analyses. We evaluated the chronotype using the Morningness-Eveningness Questionnaire (MEQ) and the degree of sleepiness using the Epworth Sleepiness Scale (ESS). Cognitive impairment was assessed by the Montreal Cognitive Assessment test (MoCA). Cognitive domains of the MoCA score were projected onto brain regions using CerebroViz library in R and a new transformation matrix derived from fMRI literature data. UMAP algorithm was used to identify patients' subgroups. The physiological tremor was recorded on patients maintaining the dominant arm extended using the smartphone App Phyphox. The tremor frequency spectrum was extracted by Fourier analysis. Results The sleepiness score (ESS) was significantly increased in HD (ESS = 5±0.4) compared to the healthy controls (ESS= 4±0.41) whereas was not significantly modified in CKD patients (3.24± 0.32). The chronotype was also not significantly different among the various groups. The mean score of the MoCA test was significantly lower in CKD, Tx, and HD groups (CKD MoCA =24.5±0.3; Tx MoCA =25.4±0.6; HD MoCA =24.6±0.7) than controls (MoCA score=28±0.1). A different pattern of impairment in the cognitive domains of MoCA was evidenced in the various groups using the CerebroViz projection and UMAP tools. MoCA score was inversely correlated with proteinuria (Pearson coefficient=-0.47; p<0.05). The higher frequencies of the physiological tremor (11-13 Hz) were significantly more represented in Tx patients compared to controls (p<0.05). Conversely, the lower frequencies (1-4 Hz) were significantly less represented in the HD group compared to controls (p<0.05). The peak frequency was inversely correlated with age in all patients (Pearson coefficient= -0.45; p<0.05) and inversely associated with azotemia levels, particularly in HD patients (Pearson coefficient=0.43; p<0.05). Conclusion Our results suggest that CKD patients present altered cognitive and motor control patterns, linked in part to the proteinuria level, suggesting a pathogenetic role of endothelial dysfunction. The characteristic motor, sleepiness and cognitive patterns of HD patients might be due to the arteriovenous fistula or the other peculiarities of these patients. These results might help identify new early markers of brain dysfunction in these patients, with the possibility of delaying or reversing cognitive decay.
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