Poor glycaemic control is associated with reduced exercise performance and oxygen economy during cardio-pulmonary exercise testing in people with type 1 diabetes

Adults (aged 18–45 years, both inclusive) with T1D eligible for the study had a body mass index (BMI) of 18–27 kg/m², glycated haemoglobin (HbA_1c) level ≤ 9.5% (80 mmol/mol) and were performing regular physical cardiorespiratory exercise during the last 3 months before screening. Exclusion criteria included cancer, cardiac diseases, supine blood pressure outside the range 90–140 mmHg for systolic blood pressure or 50–90 mmHg for diastolic blood pressure, recurrent severe hyperglycaemia or hypoglycaemia unawareness and smoking [17]. Sixty-four people with T1D were included for analyses (Table 1). Data were extracted from a clinical trial (NCT01704417) [17].

After the assessment of eligibility, patients were asked to fill in the International Physical Activity Questionnaire (IPAQ) to assess physical activity (MET min/week). Patients characteristics, medical history and medications were documented in a case report form (CRF). Afterwards, HbA1c was measured via a venous blood sample collected from the antecubital vein (Automated Glycohemoglobin Analyzer HLC-723G8, Tosoh Europe N.V, Belgium). Immediately before and after CPX testing, venous blood was collected to analyse blood glucose concentration to ensure euglycaemia during CPX testing (Super GL Glucose Analyzer, Dr. Müller Gerätebau GmbH, Germany). If pre-exercise venous blood glucose concentration was below 4.4 mmol/l carbohydrates were given (15–30 g) and if blood glucose concentration was above 13.9 mmol/l a small bolus correction dose was administered. No hypo- (< 3.9 mmol/l) or severe hyperglycaemia (> 19.4 mmol/l) occurred before or during CPX testing. The timing of bolus insulin injection was not exactly pre-defined, but participants were told to avoid the peak action of bolus insulin during CPX testing (this means avoiding bolus insulin injections less than 120 min prior to the start of CPX testing). Participants performed a CPX test until volitional exhaustion on a cycle ergometer (Ergospirometer PowerCube^®-Ergo, Ganshorn Medizin Electronic, GER). Participants sat quietly on the cycle ergometer for 3 min (0 W) before they started the warm-up period of 3 min cycling at a workload of 30 W for females and 40 W for males. Then, the workload was increased by 30 W for females and 40 W for males every 3 min until maximum volitional exhaustion. Finally, a cool-down period was performed for 1 min.

Pulmonary gas exchange variables were collected continuously by breath-by-breath measurement and then averaged over 10 s. VO_2peak was defined as the 1 min average in oxygen (O₂) consumption during the highest work rate. Heart rate and blood pressure were measured continuously via a 12-lead electrocardiogram and an automatic sphygmomanometer (Ergospirometer PowerCube^®-Ergo, Ganshorn Medizin Electronic, GER).

The non-invasive anaerobic threshold was defined by the HRTP [18]. HRTP was demarcated as the intersection of two regression lines of the heart rate to performance curve between post-warm-up and maximum power output (P_max), determined from the second-degree polynomial representation satisfying the condition of least error squares [14]. Additionally, the second ventilatory threshold (VT₂) was determined by means of the ventilation/carbon dioxide (VE/VCO₂) slope [19] to control for the accuracy of HRTP.

Data (10 s average) were expressed as absolute values and relative to maximum physiological variables and P_max. Data were tested for distribution via Shapiro-Wilks normality test and non-normal distributed data were log transformed. Stepwise linear regression was used to explore relationships between glycaemic control (HbA_1c) and CPX obtained cardio-respiratory data and performance markers with p ≤ 0.05. Data were adjusted for sex, age, BMI, blood glucose concentration at the start of CPX testing and duration of diabetes. Post hoc power analysis for the primary outcome [stepwise linear regression: dependent variable HbA_1c levels, independent variables time to exhaustion (Time_max) and oxygen economy at HRTP] resulted in a power (1-beta error probability) of 0.96.

Participants were divided into quartiles (Q) based on HbA_1c levels, and respective sub-maximal and maximal CPX derived cardio-respiratory data and performance markers were analysed by one-way analysis of variance (ANOVA) followed by a fishers least significant difference multiple comparison post hoc test (LSD). Multiple regression analysis was performed to explore relationships between changes in Time_max and independent variables, VO_2peak and oxygen uptake at the heart rate turn point (VO_2HRTP), body mass adjusted values of P_max and power output at the heart rate turn point (P_HRTP) as well as oxygen economy at P_max [VO_2peak/P_max (ml/min/W)] and at HRTP [VO_2HRTP/P_HRTP (ml/min/W)]. All statistics were performed with a standard software package of SPSS software version 22 (IBM Corporation, USA) and Prism Software version 7.0 (GraphPad, USA).

Maximum physiological parameters were found at HR_max of 185 ± 11 b/min, VO_2peak 37 ± 5 ml/kg/min, respiratory exchange ratio (RER) 1.22 ± 0.09 and P_max 231 ± 47 W. No significant differences were found between the HRTP and the VT₂ as well as for the comparison of pre- and post-exercise blood glucose concentration as given in Table 2.

As shown in Fig. 1, sex-, age-, BMI-, blood glucose concentration at the start of CPX testing- and duration of diabetes-adjusted stepwise linear regression model revealed that HbA_1c was related to Time_max and oxygen consumption at the power output elicited at the sub-maximal threshold of the heart rate turn point (VO_2HRTP/P_HRTP) (r = 0.47, R² = 0.22, p = 0.03).

Grouping participants based on quartiles of glycaemic control resulted in HbA_1c levels of 6.7 ± 0.5% (49 ± 6 mmol/mol) for quartile I, 7.6 ± 0.1% (60 ± 1 mmol/mol) for quartile II, 8.0 ± 0.1% (63 ± 1 mmol/mol) for quartile III and 9.1 ± 0.6% (76 ± 7 mmol/mol) for quartile IV (p < 0.01). No significant differences were found for physical activity (p = 0.68), resting HR (p = 0.42), systolic blood pressure (p = 0.18) and diastolic blood pressure (p = 0.83) between groups.

Significant differences were found at Time_max between QI vs. QIV (mean difference 2.5 ± 1.0 min, p = 0.02) and at VO_2HRTP/P_HRTP between QI vs. QII (− 1.5 ± 0.6 ml/min/W, p = 0.02) and QI vs QIV (− 1.6 ± 0.71 ml/min/W, p = 0.01) (Fig. 2).

White bar = QI (HbA_1c 6. ± 0.5%; 4 ± 6 mmol/mol), bright-grey bar = QII (HbA_1c 7. ± 0.1%; 60 ± 1 mmol/mol), dark-grey bar = QIII (HbA_1c 8. ± 0.1%; 6 ± 1 mmol/mol) and black bar = QIV (HbA_1c 9.1 ± 0.6%; 7 ± 7 mmol/mol). Values are given as mean and SD. “*” represents p ≤ 0.05.

Multiple regression analysis revealed that changes in VO_2peak, VO_2HRTP, P_max, P_HRTP, VO_2HRTP /P_HRTP as well as VO_2peak/P_max constitute independent predictors of Time_max (r = 0.74, p < 0.01) and those variables could explain 55% of the alteration in Time_max.