Ross, M. D., Malone, E. M., Simpson, R., Cranston, I., Ingram, L., Wright, G. P., …Florida-James, G. D. (2017). Lower Resting and Exercise-Induced Circulating Angiogenic Progenitors and Angiogenic T-Cells in Older Men. American journal of physiology. Heart and circulatory physiology, doi:10.1152/ajpheart.00592.2017. ISSN 0363-6135
Ageing is associated with a dysfunctional endothelial phenotype, as well as reduced angiogenic capabilities. Exercise exerts beneficial effects on the cardiovascular system, p...
Pegington, M., Adams, J. E., Bundred, N. J., Campbell, A., Howell, A., Howell, S. J., …Harvey, M. (2017). Recruitment to the “breast - activity and healthy eating after diagnosis” (B-AHEAD) randomized controlled trial. Integrative Cancer Therapies. 1-7doi:10.1177/1534735416687850. ISSN 1534-7354
Excess weight at breast cancer diagnosis and weight gain during treatment are linked to increased breast cancer specific and all-cause mortality. The Breast—Activity and Healt...
Ross, M., Tormey, P., Ingram, L., Simpson, R., Malone, E., & Florida-James, G. (2016). A 10 km time trial running bout acutely increases the number of angiogenic T cells in the peripheral blood compartment of healthy males: Acute exercise mobilizes angiogenic T cells. Experimental Physiology, 101(10), (1253-1264). doi:10.1113/ep085771. ISSN 0958-0670
What is the central question of the study?
Are CD31+ angiogenic T (TANG) cells preferentially mobilized in response to acute exercise?
What is the main finding an...