A Systematic Review of Machine Learning Based Gait Characteristics in
Parkinson’s Disease

Pooja       Sharma; SK       Pahuja; Karan       Veer
Abstract

Objective: Parkinson’s disease is a pervasive neuro disorder that affects people's quality of life throughout the world. The unsatisfactory results of clinical rating scales open the door for more research. PD treatment using current biomarkers seems a difficult task. So automatic evaluation at an early stage may enhance the quality and time period of life.
Methods: Grading of Recommendations Assessment, Development, and Evaluation (GRADE) and population, Intervention, Comparison, and Outcome (PICO) search methodology schemes are followed to search the data and eligible studies for this survey. Approximate 1500 articles were extracted using related search strings. After the stepwise mapping and elimination of studies, 94 papers are found suitable for the present review.
Results: After the quality assessment of extracted studies, nine inhibitors are identified to analyze people's gait with Parkinson’s disease, where four are critical. This review also differentiates the various machine learning classification techniques with their PD analysis characteristics in previous studies. The extracted research gaps are described as future perspectives. Results can help practitioners understand the PD gait as a valuable biomarker for detection, quantification, and classification.
Conclusion: Due to less cost and easy recording of gait, gait-based techniques are becoming popular in PD detection. By encapsulating the gait-based studies, it gives an in-depth knowledge of PD, different measures that affect gait detection and classification.
Keywords: Gait, machine learning tools, parkinson’s disease, classifiers assessment GRADE, PICO.
Graphical Abstract

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Cite As
Mini-Reviews in Medicinal Chemistry

A Systematic Review of Machine Learning Based Gait Characteristics in Parkinson’s Disease

Abstract

Graphical Abstract
