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Estimating the impact of changes in HbA1c, body weight and insulin injection regimen on health related quality-of-life: a time trade off study

Abstract

Background

There are limited data on the potential short-term benefits associated with reductions in HbA1c levels, and understanding any immediate improvements in health related quality-of-life (HRQoL) through better glycaemic control may help inform diabetes management decisions. This time-trade-off (TTO) study investigated the short-term impact on HRQoL associated with three different aspects of diabetes management; HbA1c change, body weight change, and the complexity of treatment regimen.

Methods

The study was designed in three stages: Stage 1) Qualitative telephone interviews with people with type 2 diabetes (T2D) in Denmark who had experienced a decrease in their HbA1c level. Stage 2) A validation survey with people with T2D in Denmark to obtain quantifiable knowledge on the short-term effects of a change in HbA1c levels. Stage 3) TTO survey using health states based on results from stage 2. Respondents were either adults with T2D (Sweden) or from the general public (UK and Denmark) and were separately asked to evaluate seven health states through an internet-based survey.

Results

Results from 4060 respondents were available for the TTO analysis (UK n = 1777; Denmark n = 1799, Sweden n = 484). ‘Well-controlled diabetes’ was associated with utilities of 0.85–0.91 and ‘not well-controlled diabetes’ with utilities of 0.71–0.80 in all countries. Difference in utilities per HbA1c percentage point was smallest in Sweden and largest in Denmark (between 0.025–0.034 per HbA1c percentage point respectively). The treatment management health state associated with the lowest disutility was the once-daily insulin regimen. The disutility associated with per kg of weight change ranged from 0.0041–0.0073.

Conclusions

Changes in HbA1c levels, insulin regimen and body weight are all likely to affect HRQoL for patients with T2D. A change in HbA1c is likely to have a short-term impact in addition to the effect on the development of long term diabetes complications. A treatment which has a simple regimen with fewer injections, and/or the need for less planning, and that causes weight loss or less weight gain, compared with other treatments, will have a positive impact on HRQoL.

Background

The long-term effects of changes in 3-month average plasma glucose, reflected in the HbA1c level, are well documented for patients with diabetes [15]. Since therapeutic interventions reduce HbA1c levels, there may also be some immediate improvements in health related quality-of-life (HRQoL) related to the improved glycaemic control e.g. reduction in symptoms such as feeling tired or thirsty. Understanding these possible relationships could help inform management decisions.

The majority of health economic evaluations for diabetes are based on the association between glycaemic control and the risk of developing long-term complications, especially the risk for cardiovascular complications. There are very few data on health utility values for short-term improvements in symptoms associated with improved glycaemic control independent of long-term complications [6].

Time trade off (TTO) is an accepted method to elicit health related utility values for different health states. The preference for one health state compared with another can be quantified as the difference in elicited utility values between the two health states, for example, different weight effects or different treatment regimens. While some attributes may be relatively simple to convey in a health state description, such as weight change or the number of injections per day, the short-term effects of different levels of glycaemic control in health state descriptions may be harder to describe in a concise and accurate manner for the general non-diabetic population. Conveying the short-term effects of different levels of glycaemic control in health state descriptions requires knowledge of the symptoms and changes in symptoms that might be associated with changes in HbA1c levels.

The aim of this TTO study was to investigate the short-term impact on HRQoL associated with three different aspects of diabetes management; HbA1c change, body weight change, and the complexity of treatment regimen, using a methodology that allows comparison between their associated health states.

Methods

The study was designed in three stages with the overall objective to understand how changes in body weight, multiple daily insulin injection treatment regimens and HbA1c affect HRQoL on a daily basis. The first two stages aimed to describe appropriate health states for further investigation via the TTO methodology used in stage 3.

Prior to commencing the study, diabetologists with experience with the TTO methodology were identified and invited to form an expert steering group (ESG) to advise at all stages of the study.

The first stage involved qualitative telephone interviews with people with type 2 diabetes (T2D) who had experienced a decrease in their HbA1c level. This was conducted to gain a preliminary understanding of the short-term effects and experiences associated with a drop in HbA1c, as well as confirmation of results from previous studies about weight and regimen preferences [7]. The outcome of this was guidance for developing the subsequent validation survey in stage 2. The validation survey aimed to provide clear and quantifiable knowledge, from a larger number of patients with diabetes, on the short-term effects of a change in HbA1c levels. The output from this stage was description of two health states; one associated with a high HbA1c level and one associated with a low HbA1c level. Following review by the ESG, the resulting data were used to obtain a description of symptoms to be included in the TTO survey (stage 3).

Stage 1 – telephone interviews

Qualitative telephone interviews were undertaken in Denmark in May 2014 to explore the experience of individuals with T2D experiencing a decrease in HbA1c. Respondents were recruited for telephone interviews in collaboration with Steno Diabetes Center (Gentofte, Denmark). In addition to identifying individuals who had achieved a decrease in HbA1c, simple questions about body weight change and treatment regimens were included e.g. “Have you lost weight?” and “What is your current treatment regimen?” An interview guide ensured consistency in approach. All respondents gave informed consent to participate.

Stage 2 – validation survey

The validation survey was conducted in Denmark in June 2014 using an online panel of individuals with T2D who had previously agreed to participate in internet-based surveys. In an attempt to gain a representative sample of the general T2D population various channels, including telephone interviews, face-to-face interviews and web banners, were used for recruitment. For inclusion in the validation survey respondents were required to be adults diagnosed with T2D, receiving medication, and knowing their current HbA1c level. Respondents were offered a nominal remuneration of less than 1€ to compensate for their time.

Questions focused on the respondent’s last measured HbA1c (current level) and how often they experienced specific symptoms using ranking on a 5-point scale (always, often, sometimes, rarely, never). The selected symptoms were based on the results of the stage 1 telephone interviews and included; tiredness/lack of energy; fatigue/extreme tiredness; headache; excessive thirst; dry mouth; frequent urination during the day or night; blurred vision; slow healing of wounds; poor memory; mood swings; difficulty concentrating. Psychological impact of poor glycaemic control was also measured using the validated Problem Areas in Diabetes 5-item scale (PAID-5) [8]. This overall methodology has been used to define health states in a previous diabetes study [9].

In order to identify any changes in symptoms associated with a change in HbA1c, respondents were also asked to recall prior HbA1c levels (previous level) either at the time of diagnosis (treatment initiation with oral antidiabetic agent (OAD)); at the time when they started on insulin (basal-only insulin) or, at the time when they progressed to bolus insulin (basal–bolus regimen) and to recall how often they experienced the various symptoms at this time. HbA1c levels were recorded in intervals of 0.5 % from <6 % and up to ≥12 %. Respondents reporting an HbA1c level above 12 % were assigned the value of 13 % for analytical purposes. The difference between the highest and lowest reported HbA1c levels for those respondents reporting the greatest change were compared, as well as the frequencies of symptoms associated with the highest and lowest HbA1c levels. Physical and psychological symptoms were further investigated by dividing respondents into three groups according to HbA1c change: >2 %-points, 1-2 %-points, <1 %-point. The difference in symptom frequency scores from the time with a high self-reported HbA1c to the time of a low self-reported HbA1c was calculated to give an impression of whether the symptom was experienced more often with the high HbA1c level than with the low HbA1c level. These comparisons were undertaken using descriptive statistics and regression analysis.

Stage 3 – TTO survey

The health states used in the TTO survey were developed based on the results of the telephone interviews and validation survey, and following review and consultation with the ESG. Each symptom was evaluated for relevance for inclusion in health state descriptions on the basis of a significant association between the HbA1c level and the symptom frequency. A test health state was used to familiarise the respondents with the TTO exercise, as outlined in Additional file 1: Table S1. These results were not used in the final analysis.

For change in HbA1c, two health states were developed; ‘not well-controlled diabetes’ ‘and ‘well-controlled diabetes’. The ‘not well-controlled diabetes’ state reflected the symptoms of the group having experienced the highest HbA1c levels (average 11.6 %). The ‘well-controlled diabetes’ state reflected the symptoms of all the groups having experienced any change in HbA1c with a lowest average HbA1c level of 7.4 %. Both health states are outlined in Table 1.

Table 1 HbA1c health states derived from the validation survey

For change in insulin regimen, health states were developed for ‘well-controlled diabetes’ with differences in respect of regimen and the need for daily planning of injection times, dose adjustment or monitoring of calorie intake. These covered injection once-daily, injection twice-daily, injection twice-daily including daily planning, and injection four-times-daily including daily planning (Table 2). For change in body weight, health states were developed for ‘well-controlled diabetes’ with different weight gains or losses; 5 kg gain, 2 kg gain, 5 kg loss and 2 kg loss (Table 3).

Table 2 Insulin regimen health states
Table 3 Change in body weight health states

Respondents were asked to evaluate seven health states (as shown in Table 4), using TTO methodology as previously described [1012]. To make the trade-offs as realistic as possible, time horizons were based on each respondent’s projected life expectancy obtained using the country, age and gender of the respondent and the most recent World Health Organization data [13]. A starting utility value of 0.6 was used; utility values for each respondent were determined to a precision of 0.05. To identify the point of indifference (i.e. when both health state options were equally acceptable), the respondents were asked the TTO question repeatedly (up to 6 times), whilst varying the number of years living in full health (as illustrated in Additional file 1: Figure S1). An example TTO question, as it appeared on the screen, is shown in Additional file 1: Figure S2.

Table 4 Health states for each respondent

Data were collected in Sweden, Denmark and the United Kingdom (UK) through an internet-based survey. In Sweden, respondents were adults diagnosed with, and receiving medication for, T2D. In the UK and Denmark, respondents were members of the general public. These differences in sample collection are due to specific requirements from the individual countries’ health technology assessment authorities. All respondents had previously agreed to participate in internet-based surveys and various channels were used for recruitment to attempt to gain a representative internet panel. Only individuals aged ≥18 years were approached and took part at their discretion; anonymity was preserved throughout. As with the validation survey, respondents were offered a nominal remuneration of less than 1€ to compensate for their time. The functionality of the questionnaire was validated in a pilot study. In addition to questions related to the TTO exercise, respondents provided data on demographics and employment status. Respondents with diagnosed diabetes were also asked to provide further information regarding the duration of their diabetes and their current medication regimen.

Respondents who chose not to trade any lifetime (i.e. preferred to live in the health state described rather than in full health in all TTO questions, illustrated in Additional file 1: Figure S1), or were willing to trade a very high proportion of their remaining lifetime to be restored to full health (i.e. preferred to live in full health in all TTO questions, illustrated in Additional file 1: Figure S1, were carefully investigated. Such respondents were excluded if they refused to trade time on ethical or religious grounds, or if they did not understand the questions. However, those who believed the health state manageable or who stated desire to live as long as possible due to obligations (e.g. caregivers) were retained.

Statistical analysis

All statistical analyses were performed using SAS® (version 9.4) statistical software. A utility value was assigned to each health state based on each individual response, derived from the midpoint of the indifference interval. The average utility value was calculated for each health state, and utility differences for the relevant health states were calculated.

As the response distribution was unknown but suspected to be non-normal, non-parametric bootstrapping was used to simulate standard errors and confidence intervals (CIs) for the mean TTO values. This method estimates the parameter’s distribution by repeatedly resampling the original data set with replacement [1416]. A total of 10,000 iterations were performed. The difference between utility values for health states was deemed to be significantly different from zero if the confidence intervals obtained by bootstrapping around this difference remained above zero.

In the main analysis those with the 2.5 % lowest and the 2.5 % highest utility differences were excluded. This objective cut-off was chosen as a way to increase stability of the results without having to apply different subjective cut-off points for each of the three health states. Sensitivity analyses were also undertaken applying different cut-off criteria.

Estimation of HRQoL impact per HbA1c point

The results of the validation study suggested that the greater the reduction in HbA1c, the greater the effect on symptom frequency in the health states. A significant association was seen between changes in HbA1c levels and changes in all physical and the majority of the psychological short-term symptoms included in the TTO health states.

To allow interim utility values to be derived, an assumption was made that utility changes were linear between the ‘not-well controlled’ and ‘well controlled’ health states, defined by a 4.2 % difference in HbA1c (11.6 %–7.4 %). Therefore the utility difference between health states for each individual was divided by 4.2 to calculate the average increase in utility per HbA1c percentage-point change.

As the 4.2 % difference was derived from self-reported HbA1c levels stated in interval categories (with censoring at each end), sensitivity analyses were also performed using various different cut-off criteria and applying uncertainty in the HbA1c difference between the two health states.

Estimation of HRQoL impact from insulin regimen features

The impact on HRQoL of different insulin regimens was derived by calculating the difference in utility between the insulin regimen health states and well controlled diabetes. The resulting difference in values thus reflects the effect of the changed feature in treatment regimen description alone, with no confounding influence from the estimated disutility associated with having diabetes.

Estimation of HRQoL impact of body weight changes

The impact on HRQoL due to body weight changes was derived by calculating the difference in utility between each of the two weight-related health states presented to each respondent. Each respondent evaluated two of four different health states for body weight; one implying weight loss of either 2 kg or 5 kg and another implying weight gain of either 2 kg or 5 kg.

Subsequently, an average utility per kilogram weight change was calculated and in the same way, the utility per change in BMI units was also derived.

Results

Stage 1 – telephone interviews

In total, eight individuals with T2D who had experienced a drop in HbA1c completed telephone interviews (88 % male and average age of 72 years). Results of the telephone interviews confirmed that even though patients aspire to lose weight, most were not willing to change their lifestyle to obtain weight loss. Examples of short-term symptoms that might be associated with high HbA1c levels such as thirst, dryness of the mouth, increased urination (both volume and frequency), tiredness (ranging from little to extreme) and psychological issues were identified for inclusion in the validation survey.

Stage 2 – validation survey

A total 268 out of 298 respondents could recall both their current and previous HbA1c levels. The majority of respondents were male (72 %), with average age of 66.5 (7.7) years and average 11 years (6.9) duration of diabetes. The average current HbA1c level was 7.5 %. The average change in HbA1c was 2.0 %-points. Respondents who had experienced a change in HbA1c of >2 %-points had an average high HbA1c of 11.6 %. The average lowest HbA1c for all respondents having experienced a change was 7.4 %; thus giving a difference of 4.2 %-point (11.6 %–7.4 %) between these two groups.

The association between changes in the frequency of experiencing symptoms and change in HbA1c levels was significant for the majority of symptoms, as outlined in Table 5 and detailed in Additional file 1: Figure S3–S8.

Table 5 Results from the validation survey for the association between change in HbA1c levels and change in frequency of short-terms symptoms

Stage 3 – TTO survey

Total number of respondents was 2159 in the UK, 2420 in Denmark and 723 in Sweden. Of these, valid responses were available from 1777 respondents in the UK, 1799 respondents in Denmark and 484 respondents in Sweden. Responses were excluded from 1242 respondents, either because they were only partly complete (n = 702), respondents refused to trade on ethical or religious grounds (n = 316), or if respondents failed a test question (i.e. those who preferred living a shorter time with diabetes than living for longer in full health) (n = 224). The profile of respondents included in the final sample is given in Table 6.

Table 6 Final sample respondents’ profile

HbA1c health states

The results for the utility values of the two HbA1c health states are presented in Fig. 1. As expected, ‘well-controlled diabetes’ was associated with higher utility than ‘not well-controlled diabetes’ in all countries with the difference being significantly different from zero (UK 0.139, 95 % CI 0.132, 0.147; Denmark 0.141, 95 % CI 0.134, 0.149; Sweden 0.106, 95 % CI 0.094, 0.119). In Sweden, however, respondents evaluated both health states with higher utility compared to the respondents in the UK and Denmark. The difference between the values for both health states was also smaller in Sweden. The difference in utilities per HbA1c percentage point (Table 7) was smallest in Sweden and largest in Denmark (utility difference between 0.025–0.034 per HbA1c percentage point respectively).

Fig. 1
figure 1

Utilities for well-controlled and not well-controlled diabetes health states. The error bar denotes the 95 % confidence interval derived from bootstrapping

Table 7 Utility results for the UK, Denmark and Sweden

Sensitivity analysis showed that the results were not overly sensitive and that the cut-off values used were appropriate (Table 8).

Table 8 Sensitivity analyses of HbA1c difference between health states “well-controlled” and “not well-controlled” diabetes using different cut-off criteria

Insulin regimen health states

Results for the different insulin regimens compared to the health state ‘well controlled diabetes’ are shown in Fig. 2. In all three countries, the health state associated with the lowest disutility (the best health state) was the once-daily insulin regimen. Regimens with additional injections and/or patients having to plan around injections and meal-times increased the disutility. The health state with the highest disutility (the worst health state) was the basal–bolus health state with four daily injections and the associated planning. In Denmark, the difference between the once-daily insulin regimen health state and ‘well controlled diabetes’ was not significantly different from zero (−0.01, 95 % CI −0.012, −0.003).

Fig. 2
figure 2

Disutility associated with insulin regimen compared to well-controlled diabetes. Error bars denote 95 % confidence intervals

Selected differences between the four different regimen health states (Table 7) suggested that one additional injection (without planning) was valued in the range of 0.015–0.021. Additional planning with a twice daily injection regimen reduced the utility value by between 0.022–0.026. Furthermore, the difference between a basal–bolus regimen of four injections and once-daily planned regimen was valued between 0.070–0.109. The basal–bolus regimen had the greatest negative impact on HRQoL compared with the other regimens.

Body weight health states

Figure 3 illustrates the utilities assigned to the four body weight health states. As expected, results in all three countries suggested that respondents would prefer to lose rather than gain weight. Gaining 5 kg was valued in the range of 0.80–0.84 whereas gaining 2 kg was valued in the range of 0.84–0.88. The ranges for losing 5 kg and losing 2 kg were similar (0.87–0.92 and 0.88–0.92 respectively).

Fig. 3
figure 3

Utilities for weight gain or loss health states. Error bars denote 95 % confidence intervals

The consolidated results by country are detailed in Table 7.

Discussion

This study aimed to quantify the short-term HRQoL impact associated with change in three different aspects of diabetes management; HbA1c level, weight change, and the complexity of treatment regimen using TTO methodology. TTO produces valuations based on decisions made under conditions of certainty and is an accepted method for preference valuations of health states by various health-technology assessment bodies (e.g. National Institute for Health and Care Excellence in the UK). In this TTO study, the trade-offs were individually based on the respondents’ age and life-expectancy, which may increase the relevance of the methodology and avoid some of the disadvantages of the fixed 10- or 30-year horizon used in other studies [11, 17].

Our results for HbA1c showed a significant association between change in HbA1c and frequency of experiencing hyperglycaemia related symptoms (frequent urination and excessive thirst). As expected, well-controlled diabetes was associated with higher utility than not well-controlled diabetes.

The difference between the two health states was significantly different from zero for each of the three countries; the population with diabetes from Sweden valued both health states higher (better) than the general populations from the UK and Denmark. Similar results have been observed in other studies [6] and suggest that people with experience of a disease give less value to its associated impacts on HRQoL than those who do not have the disease. The population with diabetes were also older on average (63.8) than the general populations from UK (43.5) and Denmark (45.5) which may have also influenced perceptions of HRQoL. There were also small differences between the values for the UK and Denmark which may have many causes, for example differences in each health care system and the way diabetes is viewed by society. Only two previous studies have analysed the relationship between HbA1c levels and short term effects on HRQoL in T2D [18, 19]. Peyrot et al. [18] investigated the relationship between HbA1c levels and HRQoL measured by the EQ-5D in adults with T2D and showed that a change in HbA1c of −1.20 % was associated with an improvement in health utility of 0.03 (95 % CI 0.00, 0.07); our results are very similar with a 1 % change in HbA1c being associated with an improvement in health utility of 0.025 in those respondents with T2D. The study by Koopmanschap [19] also found an association between HbA1c and health utility in T2D although no direct estimate was reported in this study. A recent study by McQueen et al. [6] also found similar utility values (1 % increase in HbA1c was associated with a disutility of −0.03 [95 % confidence interval [CI]-0.049, −0.006]) for association between HbA1c and health utility in T1D.

Several studies have shown that a complex treatment regimen can negatively impact adherence [2022]. We aimed to substantiate data on the potential effects of complex insulin injection regimens in this study by looking at how these can affect HRQoL. Our results confirm that regimen has an impact on HRQoL and again, the respondents with diabetes in Sweden gave a higher value to each health state than the respondents from the general population in the UK and Denmark. The basal–bolus regimen had the greatest impact on HRQoL; the difference between a basal–bolus regimen of four injections and a once-daily planned regimen was 0.102 (0.007–0.109). Our results are similar to those reported recently in a TTO study designed to assess the HRQoL impact of flexible basal insulin doses [23]. The result showed that in the general population time-flexible basal insulin injections were associated with 0.016 and 0.013 higher utility compared with a fixed time of injection for basal-only and basal–bolus regimens, respectively. Once-daily injections also had higher utility compared with twice-daily injections for basal (0.039 and 0.042) and basal–bolus (0.022 and 0.021) regimens, for the general population and for those with diabetes, respectively.

Diabetes medications differ with respect to anticipated changes in body weight and we were interested to see how weight gain and weight loss may affect HRQoL. Our results suggest that the utility value per kg of body weight is largest when comparing weight gain of 5 kg with weight loss of 2 kg. The impact is higher than the combination of weight loss of 5 kg compared to weight gain of 2 kg implying that avoiding weight gain is more important than weight loss. These results are in alignment with other similar studies [2426]. A recent study that aimed to estimate utility values for hypothetical health states associated with differences in weight and quality of life in Canadians with T2D showed for every decrease of 1 kg/m [2] BMI there was an associated increase in utility of 0.0171 (95 % CI: 0.0103, 0.0238) [26]. Our study showed a utility of 0.021 for each BMI unit lost in those respondents with T2D.

The key limitation of the methodology is the assumption that utility values change linearly as HbA1c and weight changes. This assumption allows the calculation of interim utility values and was made based on consultation with the clinical experts. Further limitations include those associated with internet-based surveys. Web-based methodology means that help cannot be offered if respondents have queries and with a lack of supervision, there is also a risk that some respondents may not spend adequate time considering their answers. We sought to minimise this through the survey design, ensuring a 10-s delay before proceeding to the next question. Additionally, the use of an internet-based survey may pose a selection bias, since only literate respondents with internet access can participate. However, the literacy rates and proportion of internet users in the three countries is high [27]. The potential for a long recall period in the study could also affect the accuracy of respondent reporting of symptoms. Lastly, by offering incentives to participate there is a risk of bias, however, the remuneration offered was small (<€1).

Conclusion

Based on reported preference for different health states, these results suggest that changes in HbA1c levels, insulin regimen and body weight are all likely to affect HRQoL for patients with diabetes. Furthermore, a change in HbA1c is likely to affect some aspects of daily living in addition to the effect on the development of long term diabetes complications. These results suggest that a treatment which has a simple regimen with fewer injections, and/or the need for less planning, and that causes weight loss or less weight gain, compared with other treatments, will have a positive impact on HRQoL.

References

  1. Group UPDSU. Intensive blood-glucose control with sulphonylureas or insulin compared with conventional treatment and risk of complications in patients with type 2 diabetes (UKPDS 33). Lancet. 1998;352(9131):837–53.

    Article  Google Scholar 

  2. UPDSU Group. Effect of intensive blood-glucose control with metformin on complications in overweight patients with type 2 diabetes (UKPDS 34). Lancet. 1998;352(9131):854–65.

    Article  Google Scholar 

  3. Stratton IM, Adler AI, Neil HAW, Matthews DR, Manley SE, Cull CA, et al. Association of glycaemia with macrovascular and microvascular complications of type 2 diabetes (UKPDS 35): prospective observational study. Br Med J. 2000;321(7258):405–12.

  4. Group TDCaCTR. The effect of intensive treatment of diabetes on the development and progression of long-term complications in insulin-dependent diabetes mellitus. N Engl J Med. 1993;329(14):977–86.

    Article  Google Scholar 

  5. Group UPDS. Quality of life in type 2 diabetic patients is affected by complications but not by intensive policies to improve blood glucose or blood pressure control (UKPDS 37). Diabetes Care. 1999;22(7):1125–36.

    Article  Google Scholar 

  6. McQueen RB, Ellis SL, Maahs DM, Anderson HD, Nair KV, Libby AM, et al. Association between glycated hemoglobin and health utility for Type 1 diabetes. Patient. 2014;7(2):197–205.

  7. Bøgelund M, Vilsbøll T, Faber J, Henriksen JE, Gjesing RP, Lammert M. Patient preferences for diabetes management among people with type 2 diabetes in Denmark-a discrete choice experiment. Curr Med Res Opin. 2011;27(11):2175–83.

    Article  PubMed  Google Scholar 

  8. McGuire B, Morrison T, Hermanns N, Skovlund S, Eldrup E, Gagliardino J, et al. Short-form measures of diabetes-related emotional distress: the Problem Areas in Diabetes Scale (PAID)-5 and PAID-1. Diabetologia. 2010;53(1):66–9.

  9. Harris SB, Khunti K, Landin-Olsson M, Galbo-Jørgensen CB, Bøgelund M, Chubb B, et al. Descriptions of health states associated with increasing severity and frequency of hypoglycemia: a patient-level perspective. Patient Prefer Adherence. 2013;7:925–36.

  10. Torrance GW, Furlong W, Feeny D. Health utility estimation. Expert Rev Pharmacoecon Outcomes Res. 2002;2(2)99–108.

  11. Dolan P, Gudex C, Kind P, Williams A. The time trade‐off method: Results from a general population study. Health Econ. 1996;5(2):141–54.

    Article  CAS  PubMed  Google Scholar 

  12. Robinson A, Dolan P, Williams A. Valuing health status using VAS and TTO: what lies behind the numbers? Soc Sci Med. 1997;45(8):1289–97.

    Article  CAS  PubMed  Google Scholar 

  13. World Health Organization. Life tables for WHO member states. Geneva: WHO; 2014.

  14. Chang WT, Collins ED, Kerrigan CL. An Internet-based utility assessment of breast hypertrophy. Plast Reconstr Surg. 2001;108(2):370–7.

    Article  CAS  PubMed  Google Scholar 

  15. Atkinson SE, Wilson PW. Comparing mean efficiency and productivity scores from small samples: a bootstrap methodology. J Prod Anal. 1995;6(2):137–52.

    Article  Google Scholar 

  16. Efron B. Nonparametric estimates of standard error: the jackknife, the bootstrap and other methods. Biometrika. 1981;68(3):589–99.

    Article  Google Scholar 

  17. Levy AR, Christensen TL, Johnson JA. Utility values for symptomatic non-severe hypoglycaemia elicited from persons with and without diabetes in Canada and the United Kingdom. Health Qual Life Outcomes. 2008;6:1–8.

    Article  Google Scholar 

  18. Peyrot M, Rubin RR, Chen X, Frias JP. Associations between improved glucose control and patient-reported outcomes after initiation of insulin pump therapy in patients with type 2 diabetes mellitus. Diabetes Technol Ther. 2011;13(4):471–6.

    Article  CAS  PubMed  Google Scholar 

  19. Koopmanschap M, Board C-A. Coping with Type II diabetes: the patient’s perspective. Diabetologia. 2002;45(7):S18–22.

    Article  CAS  PubMed  Google Scholar 

  20. Peyrot M, Barnett AH, Meneghini LF, Schumm-Draeger PM. Insulin adherence behaviours and barriers in the multinational Global Attitudes of Patients and Physicians in Insulin Therapy study. Diabet Med. 2012;29(5):682–9.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  21. Rubin RR. Adherence to pharmacologic therapy in patients with type 2 diabetes mellitus. Am J Med. 2005;118(Suppl 5A):27s–34s.

    Article  CAS  PubMed  Google Scholar 

  22. Saini SD, Schoenfeld P, Kaulback K, Dubinsky MC. Effect of medication dosing frequency on adherence in chronic diseases. Am J Manag Care. 2009;15(6):e22–33.

    PubMed  Google Scholar 

  23. Evans M, Jensen HH, Bøgelund M, Gundgaard J, Chubb B, Khunti K. Flexible insulin dosing improves health-related quality-of-life (HRQoL): a time trade-off survey. J Med Econ. 2013;16(11):1357–65.

    Article  PubMed  Google Scholar 

  24. Kiadaliri A, Gerdtham U-G, Eliasson B, Gudbjörnsdottir S, Svensson A-M, Carlsson K. Health Utilities of Type 2 Diabetes-Related Complications: A Cross-Sectional Study in Sweden. Int J Environ Res Publ Health. 2014;11(5):4939–52.

    Article  Google Scholar 

  25. Bagust A, Beale S. Modelling EuroQol health-related utility values for diabetic complications from CODE-2 data. Health Econ. 2005;14(3):217–30.

    Article  PubMed  Google Scholar 

  26. Lane S, Levy AR, Mukherjee J, Sambrook J, Tildesley H. The impact on utilities of differences in body weight among Canadian patients with type 2 diabetes. Curr Med Res Opin. 2014;30(7):1267–73.

    Article  CAS  PubMed  Google Scholar 

  27. Central Intelligence Agency. The World Factbook 2012. Washington, DC: Government Printing Office; 2012.

Download references

Acknowledgements

Editorial support and data checking were conducted by Adelphi Values Ltd, with funding from Novo Nordisk.

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Correspondence to Marie Markert Jensen.

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Competing interests

This study was funded by Novo Nordisk. MMTJ and AE are employees and shareholders of Novo Nordisk. MB and HHJ both received funding from Novo Nordisk to perform the analyses. JJ has participated in Novo Nordisk advisory boards and received honoraria for lectures. MR is an employee of Steno Diabetes Center, a non-profit company which is owned by Novo Nordisk. ME has received research awards from Novo Nordisk, Novartis and Takeda, honoraria from Novo Nordisk, Novartis, Takeda, MSD, Eli Lilly and participated in advisory boards for Novo Nordisk, Novartis and MSD.

Authors’ contributions

All authors participated in the design of the study. MMTJ, AE, HHJ and MB participated in the analysis. MMJ and AE led the development of the manuscript, and all authors have reviewed and approved the draft and final versions.

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Ridderstråle, M., Evans, L.M., Jensen, H.H. et al. Estimating the impact of changes in HbA1c, body weight and insulin injection regimen on health related quality-of-life: a time trade off study. Health Qual Life Outcomes 14, 13 (2016). https://doi.org/10.1186/s12955-016-0411-0

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