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. 2018 Jul 18;19:113. doi: 10.1186/s12875-018-0795-5

Polypharmacy in older patients with chronic diseases: a cross-sectional analysis of factors associated with excessive polypharmacy

Anja Rieckert 1,, Ulrike S Trampisch 2, Renate Klaaßen-Mielke 2, Eva Drewelow 3, Aneez Esmail 4, Tim Johansson 5, Sophie Keller 5, Ilkka Kunnamo 6, Christin Löffler 3, Joonas Mäkinen 6, Giuliano Piccoliori 7, Anna Vögele 7, Andreas Sönnichsen 1,4
PMCID: PMC6052592  PMID: 30021528

Abstract

Background

Polypharmacy is common in older people and associated with potential harms. The aim of this study was to analyse the characteristics of an older multimorbid population with polypharmacy and to identify factors contributing to excessive polypharmacy in these patients.

Methods

This cross-sectional analysis is based on the PRIMA-eDS trial, a large randomised controlled multicentre study of polypharmacy in primary care. Patients’ baseline data were used for analysis. A number of socioeconomic and medical data as well as SF-12-scores were entered into a generalized linear mixed model to identify variables associated with excessive polypharmacy (taking ≥10 substances daily).

Results

Three thousand nine hundred four participants were recruited. Risk factors significantly associated with excessive polypharmacy were frailty (OR 1.45; 95% CI 1.22–1.71), > 8 diagnoses (OR 2.64; 95% CI 2.24–3.11), BMI ≥30 (OR 1.18; 95% CI 1.02–1.38), a lower SF-12 physical health composite score (OR 1.47; 95% CI 1.26–1.72), and a lower SF-12 mental health composite score (OR 1.33; 95% CI 1.17–1.59) than the median of the study population (≤36.6 and ≤ 48.7, respectively). Age ≥ 85 years (OR 0.83; 95% CI 0.70–0.99) led to a significantly lower risk for excessive polypharmacy. No association with excessive polypharmacy could be found for female sex, low educational level, and smoking. Regarding the study centres, being recruited in the UK led to a significantly higher risk for excessive polypharmacy compared to being recruited in Germany 1/Rostock (OR 1.71; 95% CI 1.27–2.30). Being recruited in Germany 2/Witten led to a slightly significant lower risk for excessive polypharmacy compared to Germany 1/Rostock (OR 0.74; 95% CI 0.56–0.97).

Conclusions

Frailty, multimorbidity, obesity, and decreased physical as well as mental health status are risk factors for excessive polypharmacy. Sex, educational level, and smoking apparently do not seem to be related to excessive polypharmacy. Physicians should especially pay attention to their frail, obese patients who have multiple diagnoses and a decreased health-related quality of life, to check carefully whether all the drugs prescribed are evidence-based, safe, and do not interact in an unfavourable way.

Trial registration

This trial has been registered with Current Controlled Trials Ltd. on 31 July 2014 (ISRCTN10137559).

Electronic supplementary material

The online version of this article (10.1186/s12875-018-0795-5) contains supplementary material, which is available to authorized users.

Keywords: Aged, Risk factors, Protective factors, Polypharmacy, Europe, Cross-sectional study, PRIMA-eDS

Background

Older adults (≥65 years) make up an increasing proportion of the European population, particularly the oldest old (≥80 years) [1], and drug use in this age group is common. Depending on setting and age, older adults are prescribed an average of 5.3–6.9 drugs [25]. Around 44.2–57.7% of older adults are on ≥5 different drugs, and additional 9.1–23.2% on ≥10 different drugs [4, 68]. Concurrent use of multiple medications is known as polypharmacy [9]. However, there is no consensus on the definition of polypharmacy in the literature. Likewise, there is no agreed definition of excessive polypharmacy, though the cut-off point of ≥10 drugs is often used [10].

In some cases, polypharmacy may be inevitable, however, in many patients it appears to be inappropriate [11]. This may be specifically true for older people, as age-related changes in pharmacokinetics and pharmacodynamics increase the risk of adverse drug events [12]. There is some evidence, mostly from observational studies, that polypharmacy in older adults is associated with a number of negative health outcomes such as decreased functional and cognitive health status, increased risk of falls, adverse drug events, hospitalisations, and mortality. However, not all studies found these associations [13]. Risks of adverse drug outcomes increase with an increasing number of medications [14]. Wimmer et al. assessed the association between medication regimen complexity in older people and clinical outcomes, and they concluded that regimen complexity is associated with medication nonadherence and increased rates of hospitalisation [15]. In a retrospective cohort study of adults aged ≥20 years, Payne et al. found an association between unplanned hospital admission and consumption of multiple medications. However, after controlling for multimorbidity only consumption of ≥10 medications was significantly associated with unplanned admissions [16]. Also, the King’s Fund has proposed a cut-off of ≥10 medications as a pragmatic approach to identify polypharmacy patients ‘at risk’, whilst recognising that there is no universal consensus around this [17].

In previous research the association between no-polypharmacy and polypharmacy as well as between no-polypharmacy and excessive polypharmacy was investigated [4, 5, 1825]. To our knowledge no study so far has analysed possible predictors for excessive polypharmacy in patients consuming multiple drugs. Given the increased risk of adverse health outcomes in older adults taking ≥10 medications it is important to investigate which factors contribute to excessive polypharmacy. We therefore are analysing in this study the independent descriptive variables of the PRIMA-eDS-trial (Polypharmacy in chronic diseases: Reduction of Inappropriate Medication and Adverse drug events in older populations by electronic Decision Support) population to identify possible predictors of excessive polypharmacy (using the cut-off of ≥10 substances as proposed above).

Methods

Study design and population

This cross-sectional study is based on the baseline data of the PRIMA-eDS trial. In 2015, GPs in five study centres (UK/Manchester, Italy/Bolzano, Austria/Salzburg, Germany 1/Rostock, Germany 2/Witten) were enrolled to recruit patients with polypharmacy. Patient eligibility criteria included age ≥ 75 and taking ≥8 medications regularly. Patient data were collected between September 2014 and September 2015. A more detailed description of the PRIMA-eDS trial has been published [26]. These baseline patient data were used in the analysis presented here.

Data collection

At each practice the GP or an authorised staff member collected patient data and entered it into an electronic case report form (eCRF; Additional file 1). In the UK, data was also collected at some practices by a regional Clinical Research Network research nurse working with the practice. Baseline data used for this study included: age, sex, height, weight, all drugs with an Anatomical Therapeutic Chemical (ATC) code (prescribed and over the counter), all diagnoses, smoking status, and frailty according to the clinical frailty scale [27]. A health-related quality of life questionnaire (SF-12v2) [28] was also administered to each patient and entered into the eCRF by staff of the study centres. Educational level was recorded according to ISCED-97 which was filled out by the patient [29].

Outcome and independent variables

According to the King’s Fund [17] and the median number of drugs used by all patients participating in the study, we defined the outcome variables as non-excessive polypharmacy (< 10 substances) and excessive polypharmacy (≥10 substances). Drugs were coded using the ATC [30] classification system of the World Health Organisation and updated to correspond with changes in 2016 and 2017. Each substance was recorded separately. We took into consideration all substances at baseline with an ATC code. Diagnoses were recorded using the ICD-10 code [31].

Independent variables used in the analysis were age, sex, educational level, physical and mental health composite scores derived from the SF-12, frailty status, body mass index (BMI), smoking status, study centre, and number of diagnoses.

Statistical analysis

Descriptive statistics were used to describe patient demographics and other variables. Means and standard deviations (SD) were used for continuous variables, and proportions for categorical variables. A multivariable generalized linear mixed model was applied to identify factors associated with excessive polypharmacy, with GP practice as a random effect. For the purposes of this analysis, some independent variables were re-categorised: age (into ≥85 years versus < 85); educational level (low versus medium/high); frailty (frail/terminally ill versus managing well/vulnerable); body mass index (BMI ≥30 kg/m2 versus BMI < 30 kg/m2); smoking status (smoker versus non-smoker/ex-smoker). The number of diagnoses was grouped as >median versus ≤median (> 8 vs ≤8 diagnoses). Physical and mental health composite scores were all grouped as ≤median versus >median, which was for the physical health composite score ≤ 36.635 versus > 36.636 and for the mental health composite score ≤ 48.7 versus > 48.8. Lower physical and mental health composite scores, meaning that they are below the median, imply poorer health-related quality of life. As some variables have a high share of missing data, we performed multiple imputations by fully conditional specification. Cramer’s V was used to look for bivariate associations. A significance level of α = 0.05 was used throughout. Data was analysed using the SAS v9.4 statistical software.

Results

Three hundred fifty nine GPs and 3904 patients were recruited. Baseline characteristics of the study sample are presented in Tables 1, 2 and 3, in Additional files 2 and 3. A few patients did not meet the inclusion criteria for the randomised controlled trial (see Table 1), but were included for this analysis. On average, participants were taking 10.5 substances (±2.4) and had 9.5 diagnoses (±4.9). HMG CoA reductase inhibitors were the most commonly used drug, followed by proton pump inhibitors, selective beta blocking agents, platelet aggregation inhibitors, ACE inhibitors, sulphonamides, and dihydropyridine derivatives. Among the ten most commonly used substances according to ATC 5 level, pantoprazole was considered as inappropriate according to the EU(7)-PIM list, and for acetylsalicylic acid, bisoprolol, and amlodipine the EU(7)-PIM list recommended an alternative [32]. Essential (primary) hypertension was the most common diagnosis, followed by disorders of lipoprotein metabolism, type 2 diabetes mellitus, and arthrosis.

Table 1.

Demographic and clinical characteristics of the population

Characteristics All subjects (n = 3904) Polypharmacy 7–10 substancesb (n = 1644) Excessive Polypharmacy ≥10 substances (n = 2260)
n n n
Sociodemographic data
Age 3904
 75-85c (n, %) 3036 77.8 1270 77.3 1766 78.1
  ≥ 85 (n, %) 868 22.2 374 22.7 494 21.9
 mean ± SD (years) 3904 81.5 ± 4.4 1644 81.6 ± 4.4 2260 81.5 ± 4.4
Sex 3904
Female, n (%) 2240 57.4 913 55.5 1327 58.7
Male, n (%) 1664 42.6 731 44.5 933 41.3
Educational level, n (%) 3578a
 Low 1536 39.3 669 40.7 867 38.4
 Medium 1465 37.5 583 35.5 882 39.0
 High 577 14.8 239 14.5 338 15.0
Health-related factors 3736a
Smokers, n (%) 154 3.9 72 4.4 82 3.6
BMI, n (%) 3904
 BMI < 18.5 34 0.9 15 0.9 19 0.8
 BMI 18.5–24 957 24.5 435 26.5 522 23.1
 BMI 25–29 1606 41.1 710 43.2 896 39.7
 BMI ≥30 1307 33.5 484 29.4 823 36.4
Frailty level, n (%) 3781a
 Managing well 1643 42.1 804 48.9 839 37.1
 Vulnerable 868 22.2 358 21.8 510 22.6
 Mildly frail 660 16.9 237 14.4 423 18.7
 Moderately frail 505 13.0 153 9.3 352 15.6
 Severely frail 97 2.5 32 2.0 65 2.9
 Very severely frail 8 0.2 2 0.1 6 0.2
Physical health composite score, median (range) 3484a 36.6 (10–68) 1454 39.4 (12–68) 2030 34.7 (10–63)
Mental health composite score, median (range) 3483a 48.7 (12–76) 1454 50.3 (14–76) 2029 47.4 (12–74)
Study centre, n (%) 3904
 Austria 587 15.0 259 15.8 328 14.5
 Germany 1 981 25.1 351 21.3 630 27.9
 Germany 2 742 19.0 334 20.3 408 18.1
 Italy 901 23.4 439 26.7 462 20.4
 UK 693 17.8 261 15.9 432 19.1
Substances, n (mean ± SD) 3904 10.5 ± 2.4 1644 8.5 ± 0.6 2260 12.0 ± 2.2
Diagnoses, n (mean ± SD) 3898a 9.5 ± 4.9 1644 8.2 ± 4.2 2260 10.5 ± 5.2

aAs n differs from 3904, the rest of the patients have missing data regarding the variable

b7 patients took < 7 substances

c5 patients were < 75 years old

Legend: BMI body mass index, Germany 1 Rostock, Germany 2 = Witten, SD Standard deviation

Table 2.

Percentage of the population using substances (ATC level 4) according to polypharmacy status

Substances All subjects Polypharmacy < 10 substances Excessive polypharmacy ≥10 substances
n (%) n (%) n (%)
C10AA HMG CoA reductase inhibitors 2479 63.5 999 60.8 1480 65.5
A02BC Proton pump inhibitors 2328 59.6 837 50.9 1491 66.0
C07AB Beta blocking agents, selective 2240 57.4 909 55.3 1331 58.9
B01AC Platelet aggregation inhibitors excl. Heparin 1952 50.0 762 46.4 1190 52.7
C09AA ACE Inhibitors, plain 1751 44.9 792 48.2 959 42.4
C03CA Sulfonamides, plain 1715 43.9 569 34.6 1146 50.7
C08CA Dihydropyridine derivates 1611 41.3 658 40.0 953 42.2
C09CA Angiotensin II antagonists, plain 1355 34.7 505 30.7 850 37.6
C03AA Thiazides, plain 1354 34.7 555 33.8 799 35.4
A11CC Vitamin D and analogues 1120 28.7 345 21.0 775 34.3

Table 3.

Most common diagnoses of the population according to polypharmacy status

Diagnoses All subjects Polypharmacy < 10 substances Excessive polypharmacy ≥10 substances
n (%) n (%) n (%)
I10 Essential (primary) hypertension 3428 87.8 1426 86.7 2002 88.6
E78 Disorders of lipoprotein metabolism and other lipidaemias 2078 53.2 814 49.5 1264 55.9
E11 Type 2 diabetes mellitus 1850 47.4 686 41.7 1164 51.5
M19 Osteoarthritis 1752 44.9 683 41.6 1069 47.3
I25 Chronic ischaemic heart disease 1473 37.7 566 34.4 907 40.1
M54 Dorsalgia 1442 36.9 499 30.4 943 41.7
I48 Atrial fibrillation and flutter 1172 30.0 471 28.7 701 31.0
I50 Heart failure 1142 29.3 412 25.1 730 32.3
K21 Gastro-oesophageal reflux disease 982 25.2 369 22.5 613 27.1
F32 Depressive episode 853 21.9 292 17.8 561 24.8

Factors associated with excessive polypharmacy

Table 4 reports the results of the multivariable analysis. Factors were used as described in the methods section. Regarding study centres, Germany 1 as the one having the highest percentage of patients taking ≥10 drugs was chosen as reference for all other centres. Factors significantly associated with excessive polypharmacy were being frail/terminally ill (OR 1.45; 95% CI 1.22–1.71), having more than 8 diagnoses (OR 2.64; 95% CI 2.24–3.11), being obese (OR 1.18; 95% CI 1.02–1.38), having a lower physical health composite score up to the median (OR 1.47; 95% CI 1.26–1.72), and a lower mental health composite score up to the median (OR 1.33; 95% CI 1.17–1.59). In contrast, being ≥85 years old (OR 0.83; 95% CI 0.70–0.99) was significantly associated with a lower risk for excessive polypharmacy. No association with excessive polypharmacy could be found for being female (OR 1.03; 95% CI 0.89–1.19), having a low educational level (OR 0.95; 95% CI 0.80–1.13), and being a smoker (OR 0.85; 95% CI 0.60–1.21). Regarding the study centres, being recruited in the UK led to a significantly higher risk for excessive polypharmacy compared to being recruited in Germany 1 (OR 1.71; 95% CI 1.27–2.30). Being recruited in Germany 2 led to a slightly significant lower risk for excessive polypharmacy compared to Germany 1 (OR 0.74; 95% CI 0.56–0.97). There were no significant associations between recruitment in Austria and Germany 1 (OR 0.97; 95% CI 0.72–1.31) or Italy and Germany 1 (OR 0.90; 95% CI 0.67–1.21).

Table 4.

Factors associated with excessive polypharmacy (≥10 substances); results from the multivariable generalized linear mixed model

Univariable Multivariable
Factors OR (95% CI) p OR (95% CI) p
Sex (female vs male) 1.18 (1.03–1.35) 0.0189 1.03 (0.89–1.19) 0.6718
Age group (≥85 vs < 85) 0.96 (0.82–1.13) 0.6388 0.83 (0.70–0.99) 0.0328
Educational level (low vs medium/high/missing) 0.94 (0.81–1.10) 0.4440 0.95 (0.80–1.13) 0.5506
Frailty (frail/terminally ill vs managing well/vulnerable/missing) 1.83 (1.57–2.13) <.0001 1.45 (1.22–1.71) <.0001
BMI (≥30 vs < 30) 1.34 (1.16–1.54) <.0001 1.18 (1.02–1.38) 0.0303
Smoker (smoker vs non-smoker/ex-smoker/missing) 0.83 (0.59–1.16) 0.2763 0.85 (0.60–1.21) 0.3579
Research centre (Austria vs Germany 1) 0.69 (0.52–0.93) 0.0139 0.97 (0.72–1.31) 0.8519
Research centre (Italy vs Germany 1) 0.58 (0.44–0.75) <.0001 0.90 (0.67–1.21) 0.4950
Research centre (UK vs Germany 1) 0.92 (0.70–1.22) 0.5561 1.71 (1.27–2.30) 0.0004
Research centre (Germany 2 vs Germany1) 0.71 (0.54–0.94) 0.0150 0.74 (0.56–0.97) 0.0303
Number of diagnoses (> 8 vs ≤8) 2.70 (2.32–3.14) <.0001 2.64 (2.24–3.11) <.0001
Physical health composite score (≤36.635 vs > 36.636) 1.83 (1.58–2.11) <.0001 1.47 (1.26–1.72) <.0001
Mental health composite score (≤48.7 vs > 48.8) 1.53 (1.33–1.76) <.0001 1.36 (1.17–1.59) <.0001

Legend: Germany 1 = Rostock, Germany 2 = Witten

Discussion

This cross-sectional study is based on a large sample of older patients with polypharmacy recruited for the European randomised controlled multicentre trial PRIMA-eDS. Results suggest that frailty, multimorbidity, and obesity as well as lower physical and mental health composite scores on the SF-12 are independent risk factors for excessive polypharmacy. Also, in multivariable analysis, the country or even the region plays an important role. Old age alone (≥85 years) does not seem to increase the risk of polypharmacy and may even be associated with lower risk. In our study sample, sex, educational level, and smoking status apparently do not contribute to excessive polypharmacy.

Interpretation and comparison with existing literature

It is easily understandable that > 8 diagnoses contribute to excessive polypharmacy because guideline-adherent treatment of multiple diseases will inevitably lead to a large number of drugs being prescribed. This has also been shown by other studies with no polypharmacy as a comparison to excessive polypharmacy [20, 21, 24].

In our study, being frail/terminally ill is significantly associated with excessive polypharmacy. Saum et al. [33] and Herr et al. [34] showed that taking ≥10 drugs compared to taking ≤4 drugs is significantly associated with frailty [24]. Morley et al. [35] described frailty as a risk factor for a medication increase as physicians lack a concept on how to treat frail old people and thus often start medication. However, the question of causality remains unsettled as polypharmacy may also lead to frailty [36], and polypharmacy as well as frailty may be a result of multimorbidity. Studies suggested that there is a dose-response relationship between the number of drugs taken and the risk of being frail [33, 37].

Regarding health-related quality of life, a lower physical and mental health composite score indicating worse functioning within these health domains are significantly associated with excessive polypharmacy. Jyrkka et al. found moderate and poor self-reported health to be risk factors for excessive polypharmacy compared to no polypharmacy [20]. Polypharmacy patients usually suffer from several diseases and we expect them to have a reduced health-related quality of life due to illness. Here again, causality may not be easily determined as polypharmacy could also lead to a decrease in health-related quality of life e.g. due to adverse effects of drugs.

It is not surprising that obesity is associated with excessive polypharmacy. Obesity has been shown to lead to an increased use of drugs [38] and can result in chronic diseases especially with advancing age [39]. However, a causal inference cannot be made as chronic diseases caused by obesity may be associated with excessive polypharmacy and it might be that obesity is an intermediate variable or a confounder.

We found that being ≥85 years of age is a protective factor against excessive polypharmacy. This was also found by Kim et al. [21] when comparing older patients with and without polypharmacy, and by Onder et al. [24] who detected an inverse correlation between polypharmacy and increasing age. However, Jyrkka et al. [20] found ≥85 years to be a risk factor for excessive polypharmacy compared to no polypharmacy, and two further studies [19, 25] showed being ≥80 years of age to be a risk factor. One explanation for the decreased use of drugs might be that due to a limited life expectancy of these very old people preventive medications are stopped in order to improve the patients’ current well-being [40]. However, whether this really happens is questionable. Age does not influence patients’ priorities in taking preventive medication and reducing adverse events [41], and GPs find deprescribing of preventive medication difficult [42]. Another interpretation could be that excessive polypharmacy patients die earlier and do not reach the very old age.

We did not find that sex was significantly associated with excessive polypharmacy. The literature is conflicting here [19, 20, 24, 25]. In this study there was no significant association between educational level and excessive polypharmacy. In the literature it has been shown that educational level had an impact on health, however, this effect appeared to decrease with age and was not significant anymore in adults ≥51 years [43].

Smoking contributes to the burden of disease. Surprisingly, smoking was not associated with excessive polypharmacy in older polypharmacy patients, but there were very few smokers among the patients in our study.

There was a slightly significant association between excessive polypharmacy and the study centre Germany 1 when compared to Germany 2. One possible explanation could be the differences between the two settings. Germany 1 recruited patients in a more rural setting in the former Eastern part of Germany while Germany 2 recruited patients in the large metropolitan area of the highly industrialised Ruhr-region. These differences cannot be explained by the variables recorded in this study and deserve further investigation. The study centre in the UK was significantly associated with excessive polypharmacy compared to the study centre Germany 1 in the multivariable analysis. A sensitivity analysis showed that the UK was significantly associated with excessive polypharmacy compared to all other centres. Interestingly, the univariable analysis showed a slightly divergent result which was not significant (OR 0.92; 95% CI 0.70–1.22).

The patients in Germany 1 seemed to be frailer and had more diagnoses compared to the patients in the UK. In multivariable analysis the UK resulted in having more excessive polypharmacy. A reversal of effect can result due to the adjustment in the multivariable model. A possible explanation could be the “Quality and Outcomes Framework” (QOF) introduced in 2004 in the UK, which set financial incentives for certain performance indicators (pay-for-performance). Among these were indicators that relate to chronic conditions [44], some of them directly naming the prescription of certain drugs while other indicators indirectly entailed drug treatment in order to reach the targets [45]. Studies observed rising prescription rates of drugs indicated by QOF around the time when the framework was implemented, such as lipid-regulating drugs, renin-angiotensin system drugs [45], ß-blockers or antiplatelet therapy [46].

Implications

Understanding the health characteristics of an aged population taking several drugs, and investigating factors influencing excessive polypharmacy is highly relevant in times when the geriatric population is growing. This study helps to develop targeted strategies to reduce polypharmacy by identifying factors contributing to excessive polypharmacy. Physicians should especially pay attention to their frail, obese patients that have > 8 diagnoses, check whether all medications are necessary, evidence based and appropriate, and whether there are relevant interactions. To do so, GPs should perform medication reviews for their patients with excessive polypharmacy on a regular basis to optimise these patients’ medication. They should allocate extra time to care for these complex patients which needs to be reimbursed by the health care system.

Strengths and limitations

The major strength of our study is that we examined a very large sample of older patients representing several different health care settings/countries. We collected various parameters in this geriatric study population which gave us a comprehensive overview of demographic, clinical and functional status, and recorded the frailty level to distinguish between the fitter and the less fit ones. A major limitation of our study is that its cross-sectional design does not allow conclusions on causality. Further limitations are that the health-related quality of life was self-reported and all variables in the eCRF were reported by the GP, by practice staff or by a clinical research nurse. Even though instructions to record patient data were the same throughout all settings, we do not know whether the documentation of variables differs in different settings. True drug consumption is difficult to assess. We instructed the GPs to talk to their patients about all drugs they are taking. However, we were not able to verify drug consumption. Also, in this cross-sectional analysis, only patients were analysed who were recruited according to the inclusion criteria of the PRIMA-eDS trial. We therefore could only investigate patient characteristics associated with excessive polypharmacy in comparison to less excessive polypharmacy as patients without polypharmacy were not included in the trial. Furthermore, external characteristics e.g. of the prescribers could not be taken into account, and we did not judge whether medication intake was appropriate or not.

A further limitation of this study is that multiple relationships between variables exist. Multicollinearity is the cause of conspicuous differences between univariable and multivariable analysis. The interpretation for the affected variables should be regarded with caution. Noticeable correlations were found for the relationship between the research centre and the educational level (Cramer’s V = 0.48), or the number of diagnoses (Cramer’s V = 0.40) respectively, as well as between frailty, the two SF-12 scales (physical health composite score Cramer’s V = 0.20 and mental health composite score Cramer’s V = 0.33) and age (Cramer’s V = 0.22).

The physical and the mental health composite scores as well as frailty were identified as risk factors in both univariable and multivariable analysis, but the ORs are smaller in multivariable analysis because of the dependencies. Frailty and health-related quality of life are closely associated [47], still we retained these variables in our analysis as they measure different concepts.

In univariable analysis, age was not significantly related to polypharmacy. It could be that there is a connection of the variable age with information about the condition of the patient, such as frailty, health-related quality of life, and diagnoses. Frailty [48], lower health-related quality of life [49], and a high number of diagnoses [50] are more common in old age. On the other hand, these factors increase the likelihood of excessive polypharmacy regardless of age [33, 50, 51]. Therefore, the positive effect of high age may become more apparent when adjusting for these factors.

Problematic is the variable “research centre”, which significantly increases the associations found after adjustment for UK/Manchester. This is mainly attributable to the consideration of the number of diagnoses. After adjustment for this variable, the OR increases from 1.10 to 1.71. We did not want to give up the number of diagnoses as an independent variable, as in the literature this is reported as an important risk factor. The variable “research centre” also seemed essential for the model, since this variable represents a variety of influences, such as the quality of the data collection, country-specific features and so on. Yet, it must be regarded with caution.

Conclusion

Our data suggest that frailty, multimorbidity, obesity as well as low physical and mental health status may be risk factors for excessive polypharmacy. Very old age appears to be a protective factor. Sex, educational level, and smoking are not associated with excessive polypharmacy. To avoid excessive polypharmacy with its possibly unfavourable effects, physicians should carefully review the appropriateness of medication, especially in multimorbid, obese and frail patients.

Additional files

Additional file 1: (202KB, pdf)

Electronic Case Report Form (eCRF) (PDF 201 kb)

Additional file 2: (109.2KB, pdf)

Demographic and clinical characteristics per study centre (PDF 109 kb)

Additional file 3: (41.5KB, pdf)

Percentage of the population using substances (ATC level 5) according to polypharmacy status (PDF 41 kb)

Acknowledgements

We would like to express our gratitude to all participating GPs and patients. Furthermore, we would like to thank the PRIMA-eDS team for their support in collecting data.

Funding

This study is funded by the 7th framework programme of the European Union, theme Health-2012-Innovation-1-2.2.2-2, grant agreement no. 305388–2.

Availability of data and materials

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

Abbreviations

ATC

Anatomical Therapeutic Chemical

BMI

Body mass index

CI

Confidence interval

GP

General practitioner

OR

Odds ratio

PRIMA-eDS

Polypharmacy in chronic diseases: Reduction of Inappropriate Medication and Adverse drug events in older populations by electronic Decision Support

QOF

Quality and Outcomes Framework

SD

Standard deviation

UK

United Kingdom

Authors’ contributions

AR and AS conceptualised the study. ED, AE, TJ, SK, CL, IK, JM, GP, AR, and AV were involved in collecting data. RKM and UST performed the analysis. AR drafted the manuscript. ED, AE, TJ, SK, RKM, CL, IK, JM, GP, AS, UST, and AV critically reviewed the manuscript. All authors read and approved the final manuscript.

Ethics approval and consent to participate

The PRIMA-eDS study has been approved by the five local ethics committees: 1. Ethikkomission der Universität Witten/Herdecke, 3 December 2013, ref. 103/2013; 2. NRES Committee North West Greater Manchester East, 6 June 2014, ref. 14/NW/0197; 3. Ethikkommission für das Bundesland Salzburg, 15 September 2013, ref. 08.04.2014 (415-E/1509/20–2014); 4. Ethikkommission der Universitätsmedizin Rostock, 3 February 2014, ref. A 2014–0020; and 5. Comitato etico di Belluno (Azienda ULSS), 19 June 2013, ref. 305,388–2. Furthermore, all participants provided written informed consent.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Footnotes

Electronic supplementary material

The online version of this article (10.1186/s12875-018-0795-5) contains supplementary material, which is available to authorized users.

Contributor Information

Anja Rieckert, Email: Anja.Rieckert@uni-wh.de.

Ulrike S. Trampisch, Email: Ulrike.Trampisch@uni-wh.de

Renate Klaaßen-Mielke, Email: renate.klaassen-mielke@rub.de.

Eva Drewelow, Email: eva.drewelow@med.uni-rostock.de.

Aneez Esmail, Email: aneez.esmail@manchester.ac.uk.

Tim Johansson, Email: tim.johansson@pmu.ac.at.

Sophie Keller, Email: sophie.keller@pmu.ac.at.

Ilkka Kunnamo, Email: ilkka.kunnamo@duodecim.fi.

Christin Löffler, Email: christin.loeffler@med.uni-rostock.de.

Joonas Mäkinen, Email: joonas.makinen@duodecim.fi.

Giuliano Piccoliori, Email: drgiupic@tin.it.

Anna Vögele, Email: anna.voegele@sakam.it.

Andreas Sönnichsen, Email: Andreas.Soennichsen@uni-wh.de.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Additional file 1: (202KB, pdf)

Electronic Case Report Form (eCRF) (PDF 201 kb)

Additional file 2: (109.2KB, pdf)

Demographic and clinical characteristics per study centre (PDF 109 kb)

Additional file 3: (41.5KB, pdf)

Percentage of the population using substances (ATC level 5) according to polypharmacy status (PDF 41 kb)

Data Availability Statement

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.


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