Fujita Health University Discovers Hidden Energy Metabolism Shift in Parkinson’s Disease Linked to Weight Loss

Researchers at Fujita Health University in Japan have uncovered a groundbreaking insight into Parkinson’s disease (PD), revealing a hidden shift in energy metabolism that explains the mysterious weight loss experienced by many patients. Published in the prestigious Journal of Neurology, Neurosurgery & Psychiatry on November 30, 2025, this study demonstrates that PD triggers a selective reduction in body fat mass while preserving muscle, driven by a metabolic reprogramming from carbohydrate-based energy production to reliance on fats and amino acids. This discovery not only deepens our understanding of PD as a systemic disorder but also opens doors to targeted interventions for managing non-motor symptoms.

The study, led by Professor Hirohisa Watanabe and his team from the Department of Neurology at Fujita Health University School of Medicine, analyzed 91 PD patients and 47 age- and sex-matched healthy controls. Using advanced bioelectrical impedance analysis and plasma metabolomics, they pinpointed alterations in key energy pathways, challenging previous assumptions that weight loss in PD stems primarily from reduced appetite or swallowing difficulties.

Understanding Weight Loss in Parkinson’s Disease

Weight loss affects 52% to 65% of individuals with Parkinson’s disease, with patients often shedding 3 to 6 kilograms on average over the course of their illness. This phenomenon correlates with accelerated disease progression, increased mortality risk, and diminished quality of life. Unlike typical age-related sarcopenia, where both fat and muscle diminish, PD-related weight loss predominantly involves fat depletion—a pattern confirmed in the Fujita study where body fat mass was significantly lower in PD patients (p < 0.001) compared to controls, while skeletal muscle mass remained stable (p = 0.476).

Clinicians have long attributed this to factors like dysphagia, gastrointestinal dysmotility, depression, or levodopa-induced nausea. However, the Fujita research shifts focus to intrinsic metabolic dysregulation, positioning PD as a disorder extending beyond the brain to systemic energy homeostasis. In Japan, where PD prevalence mirrors global rates of about 200 per 100,000 in those over 65, such findings hold particular relevance for aging populations and neurology departments in universities like Fujita Health.

This metabolic perspective aligns with epidemiological data showing that early weight loss predicts poorer motor outcomes and higher Hoehn and Yahr (HY) stages. For higher education professionals tracking neurodegenerative research, it underscores the value of interdisciplinary collaborations between neurology, endocrinology, and data science—fields prominently represented in the study team.

Methodology Behind the Discovery

The Fujita Health University team enrolled consecutive PD patients from July 2021 to October 2023 at their Toyoake hospital, diagnosing per Movement Disorder Society criteria (mean HY stage 2.7). Body composition was precisely measured using InBody 770 bioelectrical impedance analysis, capturing fat mass, muscle mass, and body mass index (BMI). Fasting plasma samples underwent ultra-high-performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS) to profile metabolites including short- and medium-chain fatty acids, Krebs cycle intermediates, ketone bodies, and phospholipids.

Statistical rigor included Wilcoxon rank-sum tests, Spearman correlations with false discovery rate (FDR) correction (q < 0.05), and subgroup analyses by BMI (low vs. normal) and HY stages. Nutritional status via Mini Nutritional Assessment was covaried, ensuring findings reflected true metabolic shifts rather than malnutrition alone. This meticulous approach exemplifies the high-caliber research emanating from Japanese medical universities, attracting global attention.

Body Composition Changes: Fat Loss Without Muscle Wasting

PD patients exhibited lower body weight (p = 0.003), BMI (p = 0.001), and fat mass (p < 0.001) versus controls. Sarcopenia prevalence was low at 8.8%, comparable to aging norms. Advanced HY stages (4-5) showed even greater fat deficits, highlighting progression-linked vulnerability.

These results refute muscle-centric views, emphasizing fat as the primary target. For researchers in higher education, this validates bioimpedance as a non-invasive tool for longitudinal PD monitoring.

The Core Metabolic Shift Revealed

At the heart of the discovery is a reprogrammed energy production: diminished glycolytic flux and Krebs cycle activity, evidenced by reduced lactic acid (p = 0.015), succinic acid (p = 0.002), and lactate/pyruvate ratio (p = 0.004). Compensatorily, ketone bodies surged—acetoacetic acid (p = 0.039) and 3-hydroxybutyric acid (p = 0.013)—alongside amino acid catabolites like 2-hydroxybutyric acid (p = 0.045) and 2-oxobutyric acid (p = 0.001), plus acetic acid (p = 0.010).

This shift mirrors mitochondrial impairment, a PD hallmark where dopaminergic neurons' high energy demands falter. Normally, glucose undergoes glycolysis to pyruvate, entering mitochondria for Krebs cycle ATP generation. In PD, blocked at these steps, the body activates β-oxidation of fats into ketones and amino acid breakdown for acetyl-CoA alternatives.

Correlation matrices revealed ketone-amino acid clustering (rs > 0.4), opposing glycolytic markers—painting a clear "emergency fuel switch."

Photo by kuaileqie RE on Unsplash

Key Metabolites and Their Roles

• Lactic acid and succinic acid: Downregulated, signaling glycolytic and Krebs bottlenecks; lactate/pyruvate drop indicates inefficient NADH handling.
• Ketone bodies (acetoacetate, 3-hydroxybutyrate): Elevated, especially in low-BMI PD (p < 0.01); negatively correlate with BMI (rs = -0.372, q = 0.005) and fat mass, quantifying fat mobilization.
• 2-Oxobutyric and 2-hydroxybutyric acids: Markers of methionine/threonine catabolism, fueling gluconeogenesis under carb scarcity.
• Phosphatidylcholine (40:2): Upregulated (fold 1.647), rising with HY stage (rs = 0.320, q = 0.045), hinting at membrane remodeling or lipid peroxidation.

These profiles, robust post-FDR, position metabolites as biomarkers for metabolic risk in PD.

Connections to Mitochondrial Dysfunction

Mitochondrial defects underpin PD pathogenesis, from α-synuclein aggregation to dopamine neuron loss. Complex I inhibition reduces ATP, prompting metabolic rerouting—echoed here by Krebs suppression. Prior studies link PD mutations (PINK1, Parkin) to mitophagy failure, amplifying energy crises peripherally.

Fujita's prior 2024 uric acid research complements this, showing purine salvage deficits tied to oxidation. Together, they frame PD as a bioenergetic collapse, relevant for university labs probing mitotherapeutics.

Fujita Health University’s Research Legacy

Fujita Health University, a leader in Japanese higher education, hosts a prolific neurology team under Prof. Watanabe, specializing in PD biomarkers and progression. Collaborations span endocrinology (Prof. Atsushi Suzuki) and data science (Prof. Junichiro Yoshimoto), fostering holistic insights.

This publication elevates Fujita's profile, mirroring Japan's PD research surge amid aging demographics. Aspiring researchers can explore opportunities via higher education research jobs or Japan university positions.

Therapeutic Horizons and Interventions

• Nutritional strategies: High-carb diets to bolster glycolysis; monitor ketones for early alerts.
• Mitochondrial boosters: CoQ10, uric acid precursors (inosine, per prior Fujita trial).
• Ketogenesis modulators: PPAR agonists to balance fat use without excess loss.
• Personalized monitoring: Metabolite panels alongside HY scores.

Prof. Watanabe notes: “Being thin signals an invisible energy crisis; stabilizing metabolism could preserve function.”

Clinical and Research Implications

For clinicians, integrate body comp scans routinely; low fat flags metabolic risk. In academia, this spurs trials on energy substrates. Japan's MEXT-funded neuroscience hubs like Fujita drive such advances, benefiting global PD care.

Explore academic career advice for neurology paths or professor jobs in Japan.

Photo by julien Tromeur on Unsplash

Future Directions in PD Metabolism Research

Longitudinal studies will track metabolite trajectories; animal models validate causality. AI-driven analyses (per Yoshimoto's expertise) predict progression. International collaborations could test interventions, positioning universities like Fujita at the forefront.

Empowering Patients and Researchers

Patients: Consult neurologists on BMI/metabolite checks; balanced diets with carbs may help. Researchers: Join PD consortia via research assistant jobs.

In summary, Fujita's findings illuminate PD's energy crisis, promising better management. Stay informed through Rate My Professor, higher ed jobs, and career advice.