Parkinson's disease is a neurodegenerative disorder that manifests through symptoms such as tremor, slow movements, limb rigidity and gait and balance problems. As such, nearly all diagnostic testing revolves around how a patient moves and requires the patient to walk for extensive distances and amounts of time. The discomfort caused to patients by this kind of testing is unacceptable, according to an international team of researchers based in Saudi Arabia and Sweden.
They proposed a new kind of computational analysis based on less physically-demanding testing in IEEE/CAA Journal of Automatica Sinica, a joint publication of the Institute of Electrical and Electronics Engineers (IEEE) and the Chinese Association of Automation (CAA).
"Apart from gait and balance data, the measurement of computer keystroke time series that contain information of the hold time occurring between pressing and releasing a key has been proposed for detecting early stages of Parkinson's disease," said Tuan D. Pham, paper author and professor of biomedical engineering in the Center for Medical Image Science and Visualization at Linköping University in Sweden.
"Being similar to the motivation for determining the minimum number of strides for the analysis of gait dynamics, our study was interested in answering the question if there are methods that can process very short time series and achieve good results for differentiating healthy controls from subjects with early Parkinson's disease."
The disease itself is not fatal, but complications from Parkinson's disease can be serious. It affects about 10 million people across the globe, and it can take years for the disease to progress to a symptomatic state--making early detection a top priority for researchers.
In this experiment, subjects press one or two buttons on a device such as an iPhone as fast as possible for a short period of time. Pham and the team took these data and analyzed them through fuzzy recurrence plots, which take multiple short-time series data points and translate them into a two-dimensional grey-scale images of texture. In the image, related points appear as a dense grey, with more disparate data points becoming fuzzier. The algorithm used for the fuzzy recurrence plots learns how the data points connect and can help provide difference and similarities in subject groups such as people with early Parkinson's disease and those without.
"While having a very short length, the time series is augmented with a relatively large number of feature dimensions," Pham said. "The results obtained from the fuzzy recurrence plots are encouraging for the collection of practical data recorded from participants and their usage for the classification task."
The team plans to further study the use of fuzzy recurrence plots and improve the algorithm to better determine a subject's disease state. They also plan to extend the research to study gait dynamics of patients with Parkinson's disease, Huntington's disease and amyotrophic lateral sclerosis, also known as Lou Gehrig's disease.
Other contributors include Karin Wärdell, Anders Eklund and Göran Salerud, all with the Department of Biomedical Engineering at Linköping University. Eklund is also affiliated with the University's Department of Computer and Information Science and Center for Medical Image Science and Visualization.
Fulltext of the paper is available: http://www.
IEEE/CAA Journal of Automatica Sinica aims to publish high-quality, high-interest, far-reaching research achievements globally, and provide an international forum for the presentation of original ideas and recent results related to all aspects of automation. Researchers (including globally highly cited scholars) from institutions all over the world, such as MIT, Yale University, Stanford University, University of Cambridge, Princeton University, select to share their research with a large audience through JAS.
IEEE/CAA Journal of Automatica Sinica is indexed in SCIE, EI, Scopus, etc. The latest CiteScore is 5.31, ranked among top 9% (22/232) in the category of "Control and Systems Engineering", and top 10% (27/269, 20/189) both in the categories of "Information System" and "Artificial Intelligence". JAS has been in the 1st quantile (Q1) in all three categories it belongs to.
Why publish with us: Fast and high quality peer review; Simple and effective online submission system; Widest possible global dissemination of your research; Indexed in SCIE, EI, IEEE, Scopus, Inspec. JAS papers can be found at http://ieeexplore.