In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease

In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease

Parkinson&#8217;s disease (PD) is associated with brain mitochondrial dysfunction. High-energy phosphates (HEPs), which rely on mitochondrial functioning, may be considered potential biomarkers for PD. Phosphorus magnetic resonance spectroscopy (<sup>31</sup>P-MRS) is a suitable tool...

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Main Authors: Gabriele Dossi, Letizia Squarcina, Mario Rango
Format: Article
Language:English
Published: MDPI AG 2019-12-01
Series:Metabolites
Subjects:
brain energetics
parkinson’s disease
pink1 mutation
mitochondria
<sup>31</sup>p-mrs
phosphorus
Online Access:https://www.mdpi.com/2218-1989/10/1/19
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spelling doaj-2b9976e6c3024ced884e647737f3147a2020-11-25T02:55:46ZengMDPI AGMetabolites2218-19892019-12-011011910.3390/metabo10010019metabo10010019In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s DiseaseGabriele Dossi0Letizia Squarcina1Mario Rango2Excellence Center for advanced MR techniques and Neurology unit, Fondazione IRCCS Cà Granda Maggiore Policlinico Hospital, Via Sforza 35, 20122 Milan, ItalyExcellence Center for advanced MR techniques and Neurology unit, Fondazione IRCCS Cà Granda Maggiore Policlinico Hospital, Via Sforza 35, 20122 Milan, ItalyExcellence Center for advanced MR techniques and Neurology unit, Fondazione IRCCS Cà Granda Maggiore Policlinico Hospital, Via Sforza 35, 20122 Milan, ItalyParkinson&#8217;s disease (PD) is associated with brain mitochondrial dysfunction. High-energy phosphates (HEPs), which rely on mitochondrial functioning, may be considered potential biomarkers for PD. Phosphorus magnetic resonance spectroscopy (<sup>31</sup>P-MRS) is a suitable tool to explore in vivo cerebral energetics. We considered 10 <sup>31</sup>P-MRS studies in order to highlight the main findings about brain energetic compounds in patients affected by idiopathic PD and genetic PD. The studies investigated several brain areas such as frontal lobes, occipital lobes, temporoparietal cortex, visual cortex, midbrain, and basal ganglia. Resting-state studies reported contrasting results showing decreased as well as normal or increased HEPs levels in PD patients. Functional studies revealed abnormal PCr + &#946;ATP levels in PD subjects during the recovery phase and abnormal values at rest, during activation and recovery in one PD subject with PINK1 gene mutation suggesting that mitochondrial machinery is more impaired in PD patients with PINK1 gene mutation. PD is characterized by energetics impairment both in idiopathic PD as well as in genetic PD, suggesting that mitochondrial dysfunction underlies the disease. Studies are still sparse and sometimes contrasting, maybe due to different methodological approaches. Further studies are needed to better assess the role of mitochondria in the PD development.https://www.mdpi.com/2218-1989/10/1/19brain energeticsparkinson’s diseasepink1 mutationmitochondria<sup>31</sup>p-mrsphosphorus
collection DOAJ
language English
format Article
sources DOAJ
author Gabriele Dossi
Letizia Squarcina
Mario Rango
spellingShingle Gabriele Dossi
Letizia Squarcina
Mario Rango
In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease
Metabolites
brain energetics
parkinson’s disease
pink1 mutation
mitochondria
<sup>31</sup>p-mrs
phosphorus
author_facet Gabriele Dossi
Letizia Squarcina
Mario Rango
author_sort Gabriele Dossi
title In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease
title_short In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease
title_full In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease
title_fullStr In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease
title_full_unstemmed In Vivo Mitochondrial Function in Idiopathic and Genetic Parkinson’s Disease
title_sort in vivo mitochondrial function in idiopathic and genetic parkinson’s disease
publisher MDPI AG
series Metabolites
issn 2218-1989
publishDate 2019-12-01
description Parkinson&#8217;s disease (PD) is associated with brain mitochondrial dysfunction. High-energy phosphates (HEPs), which rely on mitochondrial functioning, may be considered potential biomarkers for PD. Phosphorus magnetic resonance spectroscopy (<sup>31</sup>P-MRS) is a suitable tool to explore in vivo cerebral energetics. We considered 10 <sup>31</sup>P-MRS studies in order to highlight the main findings about brain energetic compounds in patients affected by idiopathic PD and genetic PD. The studies investigated several brain areas such as frontal lobes, occipital lobes, temporoparietal cortex, visual cortex, midbrain, and basal ganglia. Resting-state studies reported contrasting results showing decreased as well as normal or increased HEPs levels in PD patients. Functional studies revealed abnormal PCr + &#946;ATP levels in PD subjects during the recovery phase and abnormal values at rest, during activation and recovery in one PD subject with PINK1 gene mutation suggesting that mitochondrial machinery is more impaired in PD patients with PINK1 gene mutation. PD is characterized by energetics impairment both in idiopathic PD as well as in genetic PD, suggesting that mitochondrial dysfunction underlies the disease. Studies are still sparse and sometimes contrasting, maybe due to different methodological approaches. Further studies are needed to better assess the role of mitochondria in the PD development.
topic brain energetics
parkinson’s disease
pink1 mutation
mitochondria
<sup>31</sup>p-mrs
phosphorus
url https://www.mdpi.com/2218-1989/10/1/19
work_keys_str_mv AT gabrieledossi invivomitochondrialfunctioninidiopathicandgeneticparkinsonsdisease
AT letiziasquarcina invivomitochondrialfunctioninidiopathicandgeneticparkinsonsdisease
AT mariorango invivomitochondrialfunctioninidiopathicandgeneticparkinsonsdisease
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