Liquid chromatography—tandem mass spectrometry (LC-MS/MS) is a new method to objectively and robustly detect nonadherence. We applied this technique to study nonadherence to cardiovascular medications in people with type 2 diabetes (T2DM).
Routine urine samples, received at the time of the annual diabetes review from 228 people with T2DM in primary care, were assessed for adherence by LC-MS/MS.
A total of 28.1% patients (N = 64) were nonadherent to antidiabetic, antihypertensive, and/or lipid-lowering medications. Nonadherence to statins was the highest at 23.7%, and nonadherence to oral hypoglycemic agents was 9.3%. HbA1c, albumin-to-creatinine ratio, and lipid profiles were significantly higher in the patients who were nonadherent compared with those who were adherent to treatment.
This unique study shows that routine urine samples can be used for adherence testing screening by LC-MS/MS and has demonstrated high nonadherence rates especially to statins in people with T2DM. Future intervention studies using LC-MS/MS as a diagnostic/therapeutic tool may help to improve clinical outcomes.
Cardiovascular disease is a major cause of morbidity and mortality in people with type 2 diabetes (T2DM) and is the largest contributor to health care costs in this population (1). Although the management of risk factors such as blood pressure, dyslipidemia, and glucose leads to legacy benefits of reduced microvascular and macrovascular complications (2), up to one-third of people with T2DM fail to derive optimal benefit from therapy because of nonadherence to medication (3). Further, poor adherence is associated with increased mortality and number of hospital admissions (4). Few reliable and practical tools exist to accurately to detect nonadherence to therapy (5).
We have set up a unique and robust biochemical method using liquid chromatography—tandem mass spectrometry (LC-MS/MS) that can detect 60 of the most common cardiovascular medications in a spot urine sample (6). LC-MS/MS is an extremely specific and sensitive instrument with a detection limit in the low-nanogram range.
Medications are detected in the urine for between four and six half-lives of the drug, thus providing a snapshot of adherence in a patient (7). The aim of this unique study was to assess nonadherence in people with T2DM in the primary care setting using screening of urine samples by LC-MS/MS.
Research Design and Methods
The study was conducted from March 2016 to July 2017 and included all consecutive people with T2DM attending six different primary care practices in Leicestershire county of the U.K. for their annual diabetes review who consented to participate in the study. On the day of their routine diabetes review, patients were asked for verbal consent to participate in the study. In patients who consented, urine samples were analyzed for treatment adherence. Demographic information and biochemical data were retrieved retrospectively from the laboratory database while data on prescribed medications were collected from the patients’ prescription lists.
Prior to attending the annual review, participants routinely provide a urine sample for albumin-to-creatinine ratio (ACR) analysis. Aliquots from these urine ACR samples received by the laboratory at the University Hospitals of Leicester National Health Service (NHS) Trust were stored at −80°C. Samples were analyzed, where suitable, using an Agilent Technologies (Santa Clara, CA) 1290 high-performance liquid chromatography system interfaced with an Agilent Technologies 6400 Series Triple Quadrupole LC/MS System, as described previously (6).
Total nonadherence was defined as the complete absence of any prescribed cardiovascular medications, partial nonadherence as the detection of at least one but not all cardiovascular medications, and total adherence as the detection of all the prescribed cardiovascular medications. The cardiovascular medications analyzed include 40 of the most common antihypertensive agents, oral hypoglycemic agents (OHAs), and oral lipid-lowering therapies.
The project met all governance and ethical requirements and was approved by the University Hospitals of Leicester NHS Trust as a quality improvement project (Registration #7766e).
Data are presented as counts/percentages, medians with interquartile ranges, or means and SDs. Analysis of the associations between ACR; HbA1c; lipid profile (total cholesterol [TC], LDL cholesterol, HDL cholesterol [HDL-C], TC/HDL ratio); and nonadherence to antidiabetic, antihypertensive, and lipid-lowering medications was conducted using ANCOVA with ACR, HbA1c, and lipid profile as variables, and age (continuous variable), sex, and therapeutic nonadherence (binary phenotypes) as independent parameters. Analysis of the level of glycemic control was conducted using a Pearson χ2 analysis with an HbA1c level of <7% as a marker of adequate control without controlling for medications other than OHAs a priori. Similarly, the analysis of lipid control was conducted with TC of <5 mmol/L as a marker of adequate control without controlling for nonlipid medications a priori. All analyses were performed using SPSS version 24.
The clinical and biochemical characteristics of patients are shown in Table 1. Overall, of the total of 228 participants with suitable samples, 64 patients (28.1%) were completely or partially nonadherent to antidiabetic, antihypertensive, and/or lipid-lowering medications (labeled as “any nonadherent” in Table 1). Of these, 13 of 228 patients (5.7%) were not taking any of the prescribed cardiovascular medications (labeled as “total nonadherent” in Table 1) while the remainder of the 64 patients (i.e., 51 of 228 patients; 22.4%) were partially nonadherent to cardiovascular medications.
The highest rate of nonadherence in this cohort was for statins (42 of 177 analyzed drugs [23.7%]), while nonadherence to antidiabetic medications was 9.3% (N = 28 of 300 analyzed drugs) (Supplementary Fig. 1). After adjusting for age and sex, the means of ACR, HbA1c, and lipid profiles were statistically higher for any nonadherent patients compared with adherent patients (Table 1). This difference was even more striking when comparing the total nonadherent group to the total adherent group.
Overall, 96 adherent patients (58.9%) and 28 of any nonadherent patients (44.4%) had an HbA1c level of <7% (odds ratio 1.79 [95% CI 1.00–3.22]; P = 0.050), suggesting better glycemic control in adherent patients. Similarly, 155 adherent patients (95.1%) and 45 of any nonadherent patients (75.0%) had TC levels of <5 mmol/L (odds ratio 6.45 [95% CI 2.57–16.13]; P < 0.001). The lipid parameters, including TC, were significantly higher (P < 0.001) in the subgroup of patients receiving lipid medications who were totally nonadherent to these medications (TC 4.4 mmol/L [±0.9 mmol/L]) versus those who were totally adherent to their lipid medications (TC 3.8 mmol/L [±0.7 mmol/L]) (Supplementary Table 1).
There was a trend toward higher mean HbA1c values in those patients totally nonadherent to OHAs (HbA1c 8.2% (±2.4%)] versus those partially nonadherent to OHAs (HbA1c 8.0% [±2.1%]; P = 0.088) (Supplementary Table 2).
The difficulty in diagnosing medication adherence reliably in a clinically useful manner remains a major unmet clinical need (4,5,8). This study shows for the first time that a routine urine sample collected in the primary care setting for urine microalbumin screening at the time of annual review can be used to objectively detect, using LC-MS/MS, nonadherence to treatment in people with T2DM. Anecdotally, the test is well accepted by patients and helps to initiate a discussion about the reasons for nonadherence and ways to overcome them (9).
Further, we confirm that there are high rates of nonadherence in people with T2DM within a primary care setting, as demonstrated previously (3). The study also demonstrates that nonadherence is associated with poor control of diabetes and lipids. Since biochemical nonadherence testing indicates only short-term nonadherence, the higher HbA1c levels in the nonadherent population compared with the adherent population provides preliminary evidence that the test may predict longer-term nonadherent behavior. More research is needed to confirm whether biochemical testing is a predictor of longer-term outcomes. Furthermore, adherence is a complex, dynamic process, and whether biochemical adherence testing induces a change in behaviour needs to be confirmed.
Previously, in a study of ∼1,400 patients with hypertension, it was noted that for every increase in the number of prescribed antihypertensive agents the risk for nonadherence (as detected using biochemical screening) increases by 80% (10). In this current primary care study, we did not find any significant association between the total number of prescribed medications and mean HbA1c values or mean lipid values. Larger studies may help to establish whether there is a threshold of OHAs and cardiovascular disease medications that increases the risk of nonadherence in people with T2DM.
Interestingly, the study also shows that rates of nonadherence to statins are much higher. We speculate that the reasons for this may include side effects such as myalgia or the poor perception of statins in the general population (11). The precise knowledge about nonadherence to a specific medication can help to tailor nonadherence advice, which is important to formulate an effective intervention that improves adherence to treatment (8).
Our study had several limitations. Our results are based on a small observational study, and future larger studies are required to confirm these preliminary findings. We also recognize the unavailability of a second measure of adherence, such as patient self-reported measures or prescription refill rates, for comparison in this study or of any data on barriers to nonadherence. Finally, our study is not protected from the so-called “toothbrush effect,” where patients may have taken their medications just a few days before follow-up in general practice (12). Thus, the spot urine assay may have underestimated nonadherence.
In conclusion, a single urine spot sample can be used to objectively screen for nonadherence in primary care, and the technique demonstrates that nonadherence to cardiovascular therapies is high in people with T2DM attending primary care. This could be used to inform clinical decisions about treatment alteration and to improve patient outcomes.
This article is featured in a podcast available at http://www.diabetesjournals.org/content/diabetes-core-update-podcasts.
P.P. and P.G. are joint first authors.
A.B. and A.A.S. are joint second authors.
Funding. P.P., P.G., S.S., and K.K. were supported by the National Institute for Health Research (NIHR) Collaboration for Leadership in Applied Health Research and Care East Midlands (CLAHRC-EM) and the NIHR Leicester Biomedical Research Centre. A.A.S. is supported by a NIHR Academic Clinical Fellowship. D.L. is funded by the University of Leicester.
The views expressed are those of the authors and not necessarily those of the NHS, the NIHR, or the Department of Health.
Duality of Interest. S.S. has received funds for research and has acted as a consultant to or has received honoraria from Boehringer Ingelheim, Eli Lilly, Merck Sharp & Dohme (MSD), Novartis, Novo Nordisk, Sanofi, Amgen, AstraZeneca, Janssen, and Takeda. K.K. has served on advisory panels and is a board member of and has received consulting and speakers’ bureau fees from Novartis, Novo Nordisk, Sanofi, Eli Lilly, Servier, and MSD and has received research support from Novartis, Novo Nordisk, Sanofi, Eli Lilly, Pfizer, Boehringer Ingelheim, and MSD. No other potential conflicts of interest relevant to this article were reported.
Author Contributions. P.P. planned the research, provided intellectual input, contributed input to the data analysis and guidance to the writing of the first draft of the manuscript, and reviewed drafts of the manuscript. P.G. planned the research, provided intellectual input, performed the data analysis, contributed guidance to the writing of the first draft of the manuscript, and reviewed drafts of the manuscript. A.B. gathered the data, ran the data analysis, provided intellectual input, wrote the first draft of the manuscript, and reviewed drafts of the manuscript. A.A.S. provided intellectual input, performed the data analysis, wrote the first draft of the manuscript, and reviewed drafts of the manuscript. R.C. provided intellectual input, ran the data analysis, and reviewed drafts of the manuscript. D.L. gathered the data, ran the data analysis, provided intellectual input, and reviewed drafts of the manuscript. S.S. provided intellectual input and reviewed drafts of the manuscript. K.K. provided intellectual input, planned the research, ran the data analysis, contributed guidance to the writing of the first draft of the manuscript, and reviewed drafts of the manuscript. P.G. is the guarantor of this work and, as such, had full access to all the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis.
Prior Presentation. Parts of this study were presented in poster form at the European Society of Cardiology Congress 2018, Munich, Germany, 25–29 August 2018 and Diabetes UK Professional Conference, Liverpool, U.K., 6–8 March 2019.