Author Interviews, Exercise - Fitness, Karolinski Institute, PLoS / 26.09.2016

MedicalResearch.com Interview with: Maléne Lindholm, PhD Karolinska Institutet Dept. of Physiology & Pharmacology Stockholm Sweden MedicalResearch.com: What is the background for this study? Response: It is well known that exercise training provides marked health benefits and can prevent and treat a broad set of diseases. Therefore, a deeper understanding and characterization of the molecular processes behind training adaptation is essential for human health. This study aimed at exploring the effects of endurance training on the human skeletal muscle transcriptome (activity of all genes) and investigate the possible presence of a muscle memory of training. To do this, the healthy volunteers in this study first trained only one leg, 4 times per week for 3 months. After 9 months of detraining, the subjects then came back and trained both legs in the same way as during the first training period, thus one leg was then previously well-trained and one previously untrained. This meant that each individual was their own control, as both legs have the same genome, experience the same stress, diet etc. Only the training status differed. (more…)
Author Interviews, Duke / 14.01.2015

Nenad Bursac PhD Rooney Family Associate Professor of Biomedical Engineering Associate Professor of Medicine Duke UniversityMedicalResearch.com Interview with: Nenad Bursac PhD Rooney Family Associate Professor of Biomedical Engineering Associate Professor of Medicine Duke University     Medical Research: What is the background for this study? What are the main findings? Dr. Bursac: Researchers have tried for a long time to coax human muscle cells (obtained from needle biopsies) into contracting muscle fibers in a dish in order to be able to study human muscle physiology ex vivo. We are the first group that succeeded by carefully optimizing culture conditions including methods to expand and then culture cells in three-dimensional hydrogel matrices under passive tension. By doing so, we made first human muscle model that in response to electrical stimulation generates classical muscle contractile responses (twitch and tetanus). We have also shown that these engineered muscles (that we call "myobundles") contract in response to acetylcholine as it naturally happens when neurons in our body activate muscle. We demonstrated reproducibility and robustness of the approach by generating functional myobundles with similar properties from 10 independent donor muscle samples. We further went to show that myobundles have intact signaling characteristic of native muscle and respond to diverse set of drugs as human muscles do in clinics. (more…)