Publications

Journal Articles

  1. & Heart rate dynamics during cardio-pulmonary exercise testing are associated with glycemic control in individuals with type 1 diabetes. PLOS ONE 13(4), e0194750
  2. & Interstitial Glucose and Physical Exercise in Type 1 Diabetes: Integrative Physiology, Technology, and the Gap In-Between. Nutrients 10(1), 93
  3. & Workplace delivery of a dietitian-led cardiovascular disease and type 2 diabetes prevention programme: A qualitative study of participants’ experiences in the context of Basic Needs Theory. Nutrition Bulletin 42(4), 309-320.
  4. & Role of cardiorespiratory fitness in lifetime cardiovascular risk prediction models: a cross-sectional analysis. The Lancet 390, S40
  5. & The effects of a single whole body cryotherapy exposure on physiological, performance and perceptual responses of professional academy soccer players following repeated sprint exercise. Journal of Strength and Conditioning Research 31(2), 415-421.
  6. & Cardiorespiratory fitness testing and cardiovascular disease risk in male steelworkers. Occupational Medicine 67(1), 38-43.
  7. & Atypical blood glucose response to continuous and interval exercise in a person with type 1 diabetes: a case report. Journal of Medical Case Reports 11(1)
  8. & Poor glycaemic control is associated with reduced exercise performance and oxygen economy during cardio-pulmonary exercise testing in people with type 1 diabetes. Diabetology & Metabolic Syndrome 9(1)
  9. Improved end-stage high intensity performance but similar glycaemic responses after waxy barley starch ingestion compared to dextrose in type 1 diabetes.. J Sports Med Phys Fitness. 56(11), 1392-1400.
  10. Similar magnitude of post-exercise hyperglycemia despite manipulating resistance exercise intensity in type 1 diabetes individuals. Scandinavian Journal of Medicine & Science in Sports 26(4), 404-412.
  11. & Algorithm that delivers an individualized rapid-acting insulin dose after morning resistance exercise counters post-exercise hyperglycaemia in people with Type 1 diabetes. Diabetic Medicine 33(4), 506-510.
  12. & Similar risk of exercise-related hypoglycaemia for insulin degludec to that for insulin glargine in patients with type 1 diabetes: a randomized cross-over trial. Diabetes, Obesity and Metabolism 18(2), 196-199.
  13. Type 1 diabetes and physical activity: An assessment of knowledge and needs in healthcare practitioners. Journal of Diabetes Nursing 20(8), 271-277.
  14. & Insulin therapy and dietary adjustments to normalize glycemia and prevent nocturnal hypoglycemia after evening exercise in type 1 diabetes: a randomized controlled trial. BMJ Open Diabetes Research & Care 3(1), e000085-e000085.
  15. Cardiorespiratory fitness is a stronger indicator of cardiometabolic risk factors and risk prediction than self-reported physical activity levels. Diabetes and Vascular Disease Research 12(6), 428-435.
  16. & Impact of single and multiple sets of resistance exercise in type 1 diabetes. Scandinavian Journal of Medicine & Science in Sports 25(1), e99-e109.
  17. & Simulated games activity vs continuous running exercise: A novel comparison of the glycemic and metabolic responses in T1DM patients. Scandinavian Journal of Medicine & Science in Sports 25(2), 216-222.
  18. A Low–Glycemic Index Meal and Bedtime Snack Prevents Postprandial Hyperglycemia and Associated Rises in Inflammatory Markers, Providing Protection From Early but Not Late Nocturnal Hypoglycemia Following Evening Exercise in Type 1 Diabetes. Diabetes Care 37(7), 1845-1853.
  19. & Metabolic Implications when Employing Heavy Pre- and Post-Exercise Rapid-Acting Insulin Reductions to Prevent Hypoglycaemia in Type 1 Diabetes Patients: A Randomised Clinical Trial. PLoS ONE 9(5), e97143
  20. Reductions in resistance exercise-induced hyperglycaemic episodes are associated with circulating interleukin-6 in Type 1 diabetes. Diabetic Medicine 31(8), 1009-1013.
  21. Comparison of the metabolic responses to ingestion of hydrothermally processed high-amylopectin content maize, uncooked maize starch or dextrose in healthy individuals. British Journal of Nutrition 111(07), 1231-1238.
  22. & Large Pre- and Postexercise Rapid-Acting Insulin Reductions Preserve Glycemia and Prevent Early- but Not Late-Onset Hypoglycemia in Patients With Type 1 Diabetes. Diabetes Care 36(8), 2217-2224.
  23. & Isomaltulose Improves Glycemia and Maintains Run Performance in Type 1 Diabetes. Medicine & Science in Sports & Exercise 44(5), 800-808.
  24. Pre-exercise Insulin and Carbohydrate Strategies in the Exercising T1DM Individual.
  25. Effects of short-term therapy with glibenclamide and repaglinide on incretin hormones and oxidative damage associated with postprandial hyperglycaemia in subjects with type 2 diabetes mellitus. Diabetes Research and Clinical Practice
  26. A combined insulin reduction and carbohydrate feeding strategy 30 min before running best preserves blood glucose concentration after exercise through improved fuel oxidation in type 1 diabetes mellitus. Journal of Sports Sciences
  27. Effect of Postactivation Potentiation on Swimming Starts in International Sprint Swimmers. Journal of Strength and Conditioning Research
  28. & Isomaltulose Improves Postexercise Glycemia by Reducing CHO Oxidation in T1DM. Medicine & Science in Sports & Exercise 43(2), 204-210.
  29. Impact of pre-exercise rapid-acting insulin reductions on ketogenesis following running in Type 1 diabetes. Diabetic Medicine
  30. Relationships Between Force–Time Characteristics of the Isometric Midthigh Pull and Dynamic Performance in Professional Rugby League Players. Journal of Strength and Conditioning Research 25(11)
  31. Heart rate prescribed walking training improves cardiorespiratory fitness but not glycaemic control in people with type 2 diabetes. Journal of Sports Sciences
  32. Blood glucose responses to reductions in pre-exercise rapid-acting insulin for 24 h after running in individuals with type 1 diabetes. Journal of Sports Sciences
  33. Exercise-induced hyperglycaemia in the absence of diabetes. Diabetic Medicine
  34. & Plasma catecholamine and nephrine responses following 7 weeks of sprint cycle training. Amino Acids 38(5), 1351-1359.
  35. & Plasma catecholamine and nephrine responses to brief intermittent maximal intensity exercise. Amino Acids 36(2), 209-217.