Marcos Lacasa's thesis at the UOC analizes how machine learning, a type of artificial intelligence, can provide a better understanding of the disease and improve diagnosis. (Image: Andrea Piacquadio, Pexels)
Juan F. Samaniego
As well as improving diagnosis, other lines of research are also looking for biological markers and developing treatments
Myalgic encephalomyelitis involves a wide range of symptoms that combine to produce a debilitating feeling of extreme, chronic fatigue that can be difficult to explain
Between 17 and 24 million people worldwide suffer from chronic fatigue syndrome, a deeply debilitating and difficult-to-diagnose condition. Also known as myalgic encephalomyelitis, according to the World Health Organization, this condition causes a wide range of symptoms that combine to produce a debilitating, difficult-to-explain feeling of extreme, chronic fatigue, including difficulty sleeping and feeling unwell after exertion. Some patients may have serious problems carrying out their usual activities or concentrating, and may even become bedridden.
"With such a wide range of symptoms that can worsen over time, the difficulty in making a diagnosis lies in the lack of diagnostic tests and biomarkers to define the affected patient," said Marcos Lacasa, a researcher currently working on his PhD thesis on the Universitat Oberta de Catalunya's (UOC) doctoral programme in Bioinformatics. "Diagnosis depends on the history and the doctor. An early diagnosis can have a big impact on the course of the disease."
In his latest paper, co-authored with his thesis supervisors Jordi Casas, from the UOC's Applied Data Science Lab, and José Alegre, from the Vall d'Hebron Institute of Research (VHIR), alongside Ferran Prados, also a researcher at the Applied Data Science Lab, Lacasa analyses how machine learning, a type of artificial intelligence (AI), can provide a better understanding of the disease and improve diagnosis. The paper has been published in Nature's open access Scientific Reports journal.
AI and synthetic patients
In the absence of clear biomarkers, there are currently no tests to diagnose whether someone has chronic fatigue syndrome or not. Although a great deal of research has been done in this area (the same group of researchers suggest in another recent article that patients' oxygen consumption levels should be used as a reference), diagnoses are primarily made on the basis of questionnaires that assess a person's perception of their fatigue. These questionnaires, such as the 36-Item Short Form Health Survey (SF-36), are well-defined and standardized. However, early diagnosis is still difficult.
"What we have shown is that we can simulate a patient's condition in different areas based on their answers to a questionnaire. In other words, we could provide non-specialists with a machine learning application that could even predict a patient's performance on a stress test based on about forty questions," said Lacasa. "This would act as a warning of symptoms that could be associated with myalgic encephalomyelitis and would expedite the referral of the patient to the nearest specialized unit. In short, it would make early diagnosis more feasible."
The main challenge with this approach is having enough quality data to train the AI algorithm, so that it can then predict answers. "The application can provide AI-generated answers. A patient would not have to fill in six different questionnaires for us to know their overall condition. By filling in just one, the AI would fill in the rest," added Lacasa.
The solution proposed in the paper is to create what the researchers call synthetic patients. This approach allows data from a single general questionnaire to be used to fill in specialized questionnaires, or even to replace missing data. "We can carry out scientific studies using data that are quote-unquote made up by AI, but retain statistical characteristics as if they were real patients. The main advantage is that these synthetic data can be shared without fear of compromising private data of any kind."
In search of a treatment for chronic fatigue syndrome
The model proposed by the UOC and VHIR researchers has advantages, but also limitations. "Misuse of the synthetic data would invalidate the analyses. Likewise, it's still necessary to have real input data, such as those provided by the SF-36 questionnaire," said Lacasa. The advantages lie in having a tool that can provide high-fidelity synthetic data for research and educational purposes, free from legal, privacy, security and intellectual property restrictions.
In addition to improving diagnosis through questionnaires, other parallel lines of research into chronic fatigue syndrome are also being pursued. The search for biological markers that can be used to develop effective diagnostic tests is high on the list of priorities, along with the development of treatments. There is currently no cure. Instead, treatments are aimed at relieving symptoms through sleep hygiene, dietary changes, exercise, therapies and medications that target the predominant symptoms.
"What we would need is more funding to do genetic sequencing on patients with myalgic encephalomyelitis. Then we could do a genomic analysis and find out whether there is a protein that causes the disease. This would make it much easier to design an effective drug to alleviate the symptoms," Lacasa concluded.
This research contributes to Sustainable Development Goal (SDG) 3: Ensure healthy lives and promote well-being for all at all ages.
LACASA, M., PRADOS, F., ALEGRE, J. & CASAS-ROMA, J. A synthetic data generation system for myalgic encephalomyelitis/chronic fatigue syndrome questionnaires. In: Scientific Reports [online]. 2023. Vol. 13, Issue 14256. Available at: https://doi.org/10.1038/s41598-023-40364-6
LACASA, M., LAUNOIS, P., PRADOS, P., ALEGRE, J. & CASAS-ROMA, J. Unsupervised cluster analysis reveals distinct subtypes of ME/CFS patients based on peak oxygen consumption and SF-36 scores. In: Clinical Therapeutics [online]. 2023. Available at: https://doi.org/10.1016/j.clinthera.2023.09.007
Sònia Armengou Casanovas
+34 619 413 823
The UOC's research and innovation (R&I) is helping overcome pressing challenges faced by global societies in the 21st century by studying interactions between technology and human & social sciences with a specific focus on the network society, e-learning and e-health.
Over 500 researchers and more than 50 research groups work in the UOC's seven faculties, its eLearning Research programme and its two research centres: the Internet Interdisciplinary Institute (IN3) and the eHealth Center (eHC).
Open knowledge and the goals of the United Nations 2030 Agenda for Sustainable Development serve as strategic pillars for the UOC's teaching, research and innovation. More information: research.uoc.edu.
PhD student at the UOC
Lecturer in the IT, Multimedia and Telecommunications Department
Director of the Master's Degree in Multimedia Applications
Expert in: IT security; privacy in graphs and social networks; graph mining; data mining.
Knowledge area: IT security, artificial intelligence and data mining.
Ferran Prados Carrasco
Expert in: Neuroimaging analysis, the development of biomarkers and the translation of technological breakthroughs into clinical practice in the context of neurodegenerative diseases.
Knowledge area: Neuroimaging, data science, biomarkers, neurodegenerative diseases