Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-29T02:12:09.022Z Has data issue: false hasContentIssue false

Patterns of psychotropic prescribing and polypharmacy in older hospitalized patients in Ireland: the influence of dementia on prescribing

Published online by Cambridge University Press:  16 August 2016

Kieran Anthony Walsh*
Affiliation:
Pharmaceutical Care Research Group, School of Pharmacy, University College Cork, Cork, Ireland Department of Epidemiology and Public Health, University College Cork, Cork, Ireland Centre for Gerontology and Rehabilitation, School of Medicine, University College Cork, Cork, Ireland
Niamh A. O'Regan
Affiliation:
Centre for Gerontology and Rehabilitation, School of Medicine, University College Cork, Cork, Ireland
Stephen Byrne
Affiliation:
Pharmaceutical Care Research Group, School of Pharmacy, University College Cork, Cork, Ireland
John Browne
Affiliation:
Department of Epidemiology and Public Health, University College Cork, Cork, Ireland
David J. Meagher
Affiliation:
Graduate Entry Medical School, University of Limerick, Limerick, Ireland
Suzanne Timmons
Affiliation:
Centre for Gerontology and Rehabilitation, School of Medicine, University College Cork, Cork, Ireland
*
Correspondence should be addressed to: Kieran Anthony Walsh, Pharmaceutical Care Research Group, School of Pharmacy, College Road, Cork, Ireland. Phone: +353 214901690; Fax: +353 214901656. Email: [email protected]; [email protected].
Rights & Permissions [Opens in a new window]

Abstract

Background:

Neuropsychiatric Symptoms (NPS) are ubiquitous in dementia and are often treated pharmacologically. The objectives of this study were to describe the use of psychotropic, anti-cholinergic, and deliriogenic medications and to identify the prevalence of polypharmacy and psychotropic polypharmacy, among older hospitalized patients in Ireland, with and without dementia.

Methods:

All older patients (≥ 70 years old) that had elective or emergency admissions to six Irish study hospitals were eligible for inclusion in a longitudinal observational study. Of 676 eligible patients, 598 patients were recruited and diagnosed as having dementia, or not, by medical experts. These 598 patients were assessed for delirium, medication use, co-morbidity, functional ability, and nutritional status. We conducted a retrospective cross-sectional analysis of medication data on admission for 583/598 patients with complete medication data, and controlled for age, sex, and co-morbidity.

Results:

Of 149 patients diagnosed with dementia, only 53 had a previous diagnosis. At hospital admission, 458/583 patients experienced polypharmacy (≥ 5 medications). People with dementia (PwD) were significantly more likely to be prescribed at least one psychotropic medication than patients without dementia (99/147 vs. 182/436; p < 0.001). PwD were also more likely to experience psychotropic polypharmacy (≥ two psychotropics) than those without dementia (54/147 vs. 61/436; p < 0.001). There were no significant differences in the prescribing patterns of anti-cholinergics (23/147 vs. 42/436; p = 0.18) or deliriogenics (79/147 vs. 235/436; p = 0.62).

Conclusions:

Polypharmacy and psychotropic drug use is highly prevalent in older Irish hospitalized patients, especially in PwD. Hospital admission presents an ideal time for medication reviews in PwD.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © International Psychogeriatric Association 2016

Introduction

The number of people with dementia (PwD) is escalating worldwide; estimates project the prevalence at over 131.5 million by 2050 (Alzheimer's Disease International, 2015). The majority will experience Behavioral and Psychological Symptoms of Dementia (BPSD), also referred to as Neuropsychiatric Symptoms (NPS) during their disease (Lawlor, Reference Lawlor2002). BPSD refers to the spectrum of distressing, non-cognitive symptoms of dementia, ranging from wandering and agitation to delusional and aggressive behavior (Cahill et al., Reference Cahill, O'Shea and Pierce2012). Psychotropic medications are commonly prescribed to manage BPSD and have some evidence to support their use (Bishara et al., Reference Bishara, Taylor, Howard and Abdel-Tawab2009; Seitz et al., Reference Seitz2013). For example, the CitAD trial showed that the addition of citalopram to a psychosocial intervention was more effective at reducing agitation and caregiver distress in PwD than the addition of placebo (Porsteinsson et al., Reference Porsteinsson2014). Furthermore, treatment of BPSD with atypical anti-psychotics has been found to cause a small yet significant reduction in caregiver burden (Mohamed et al., Reference Mohamed, Rosenheck, Lyketsos, Kaczynski, Sultzer and Schneider2012). However, anti-psychotics are known to increase the risk of stroke and mortality in PwD (Schneider et al., Reference Schneider, Dagerman and Insel2005), and a recent study has found that for every 26 PwD treated with haloperidol, there was one death (Maust et al., Reference Maust2015). Additionally, the DIADS-2 trial found that sertraline was not efficacious for the treatment of depression in PwD and was associated with an increased risk of adverse events (Rosenberg et al., Reference Rosenberg2010; Weintraub et al., Reference Weintraub2010). Guidelines generally recommend that non-pharmacological treatments should be used as first-line treatment of BPSD, and only when these fail should psychotropic agents be trialed for short-term use (Azermai et al., Reference Azermai, Petrovic, Elseviers, Bourgeois, Van Bortel and Vander Stichele2012). Despite this, the usage of anti-psychotics and other psychotropics in this vulnerable patient group remains unacceptably high (Maust et al., Reference Maust, Langa, Blow and Kales2016).

Polypharmacy, which is defined as the use of five or more medications (Gnjidic et al., Reference Gnjidic2012), is common in older people and is associated with poorer health outcomes (Hajjar et al., Reference Hajjar, Cafiero and Hanlon2007). Similarly, psychotropic polypharmacy (concurrent use of two or more psychotropic agents) increases the risk of adverse events (Mojtabai and Olfson, Reference Mojtabai and Olfson2010). Delirium super-imposed on dementia is often drug-related and medications such as opioids and benzodiazepines can trigger a delirium episode in susceptible people (Clegg and Young, Reference Clegg and Young2011). Also, anti-cholinergic medications can negatively affect cognitive and physical function in older people and their use should be minimized in PwD (Collamati et al., Reference Collamati2016).

Hospitalization in PwD is associated with significantly poorer health outcomes (Zekry et al., Reference Zekry2009). PwD are particularly vulnerable in this setting, due to the challenges of illness, new medications, and unfamiliar environments/carers (Borbasi et al., Reference Borbasi, Jones, Lockwood and Emden2006). The report of the Irish National Audit of Dementia (INAD) care in acute hospitals found high levels of anti-psychotic prescribing in hospitalized PwD, particularly when admitted from nursing homes (de Siún et al., Reference de Siún2014). The authors highlighted a need for regular medication review on admission, echoed in the recently published Irish National Dementia Strategy (Department of Health, 2014). However, only 20 healthcare records from each hospital were reviewed for anti-psychotic prescribing in this audit (de Siún et al., Reference de Siún2014). Furthermore, only people with an explicit diagnosis of dementia who had a minimum length of stay of five days were included. Therefore, it is unclear whether this data is representative of the majority of Irish PwD who are admitted to hospital.

The objectives of this study were to describe the use of psychotropic, anti-cholinergic, and deliriogenic medication among older hospitalized patients, with and without dementia, and to identify the prevalence of polypharmacy (≥5 medications) and psychotropic polypharmacy (concurrent use of ≥2 psychotropic agents) in these patient groups. Our research question was “Are there any differences in the patterns of prescribing between older people (≥70 years) with and without dementia, upon admission to six acute hospitals in the south of Ireland, controlling for age, sex and co-morbidity?” Our primary hypothesis was that PwD are significantly more likely to be prescribed psychotropics and to be exposed to psychotropic polypharmacy than people without dementia, as previously reported (Giron et al., Reference Giron, Forsell, Bernsten, Thorslund, Winblad and Fastbom2001; Hartikainen et al., Reference Hartikainen, Rahkonen, Kautiainen and Sulkava2003). Our secondary hypothesis was that PwD are more likely to be prescribed deliriogenic and anti-cholinergic medications and to be prescribed more medications than people without dementia; however, the evidence for this is mixed or lacking (Schmader et al., Reference Schmader, Hanlon, Fillenbaum, Huber, Pieper and Horner1998; Andersen et al., Reference Andersen, Viitanen, Halvorsen, Straume and Engstad2011).

Methods

Study design, setting, and patients

The Cork Dementia Study has been described in detail elsewhere (Timmons et al., Reference Timmons2015). In brief, this longitudinal observational study explored the prevalence and associations of dementia in older patients admitted to all six acute hospitals in County Cork, Ireland. County Cork has a population of 519,032 which is comprised of 49.61% males, an older population (≥70 years) of 42,382 (Central Statistics Office, 2012) and an estimated dementia population of 4,830 (Cahill et al., Reference Cahill, O'Shea and Pierce2012). This is relatively comparable to the proportions for the Republic of Ireland as a whole (total population = 4,588,252; males = 49.53%; older population ≥70 years = 361,755; and estimated dementia population = 41,720).

Eligibility criteria for this study included age ≥70 years old and elective or emergency admission (non-day case). Recruitment occurred in each hospital for a period of two weeks and lasted from May 2012 to February 2013. Informed consent was obtained for all patients. Exclusion criteria included patient refusal or being moribund on arrival to hospital. Patients were diagnosed with dementia by a three-step approach, involving initial cognitive screening utilizing the Standardized Mini-Mental State Examination, followed by informant-derived data utilizing the Informant Questionnaire on Cognitive Decline in the Elderly. Finally, dementia status was established by the senior author (ST), a consultant geriatrician, based on all available information (i.e. cognitive testing, informant-derived data, medical and demographic history). Patients were also assessed for delirium, depression, medication use, co-morbidity, functional ability, and nutritional status. Data were prospectively collected by researchers with nursing or psychology backgrounds, after extensive training in all assessment tools.

This present study is a retrospective cross-sectional analysis of the original Cork Dementia Study medication data, collected on admission. First, the original medication data were cleaned by the study pharmacist (KAW), using a three-step cycle of screening, diagnosing, and editing suspected data irregularities, for the purpose of ensuring that incorrectly spelled or partially filled entries could be corrected and coded accurately (Van den Broeck et al., Reference Van den Broeck, Cunningham, Eeckels and Herbst2005). Second, the cleaned medication data were coded by World Health Organization (WHO) Anatomical Therapeutic Chemical (ATC) classifications (WHO, 2015), excluding emollients or nutritional supplements without any active ingredients. Information on strength, quantity, duration, or usage at follow-up, were not recorded consistently so were not coded. Patients with missing medication data were excluded from the analysis. Finally, the coded medication data were cleaned again and linked at individual patient-level to the previously coded clinical data.

The “Strengthening the Reporting of Observational Studies in Epidemiology” (STROBE) guidelines have been followed in the conduct and reporting of this research (Von Elm et al., Reference Von Elm2007). Ethical approval was obtained from the local ethics committee (reference ECM 4 (t) 06/12/11 & ECM 3 (yy) 07/07/15).

Prescribing patterns

The primary outcome in this study was the difference in prescribing patterns between people with and without dementia, particularly psychotropic agents in PwD, and especially anti-psychotics. The definition of a psychotropic varies significantly throughout the literature; the research group, by consensus, included anti-psychotics (N05A), anti-depressants (N06A), anxiolytics (N05B), hypnotics (N05C), anti-convulsants/mood-stabilizers (N03A), and anti-dementia drugs (N06D), as these medication classes are used to manage BPSD (Bishara et al., Reference Bishara, Taylor, Howard and Abdel-Tawab2009). It is important to acknowledge that anti-dementia drugs are inevitably utilized more in PwD than people without dementia, due to their cognitive enhancing properties. Additionally, some studies do not consider anti-convulsants/mood-stabilizers to be psychotropics (Avorn et al., Reference Avorn1992; Patterson et al., Reference Patterson, Hughes, Crealey, Cardwell and Lapane2010). Therefore, we conducted sensitivity analyses to assess the impact of more conservative psychotropic definitions on our outcomes by excluding the following in a step-wise manner:

  1. 1. N06D (Anti-dementia drugs),

  2. 2. N06D and N03A (Anti-dementia drugs and anti-convulsants/mood-stabilizers).

We utilized ATC codes, but reclassified Lithium (N05AN01) as a mood-stabilizer rather than an anti-psychotic (Søndergård et al., Reference Søndergård, Lopez, Andersen and Kessing2008). We were also interested in psychotropic polypharmacy, and patterns of anti-psychotic prescribing in those admitted from nursing homes. Other prescribing patterns of interest included the 14 main ATC anatomical groups (excluding “D- Dermatologicals”), levels of minor or major polypharmacy (5–9 medications; or ≥10 medications, respectively), deliriogenic medications and anti-cholinergics. Deliriogenic medication definition was based on published literature, decided upon by consensus between the study pharmacist (KAW) and two consultant geriatricians (ST, NOR) who are delirium experts. The included deliriogenic medications were predominantly in line with findings from a systematic review conducted by Clegg et al. which investigated the associations between medications and risk of delirium (Clegg and Young, Reference Clegg and Young2011). These definitions and the associated ATC codes are shown in Table 1.

Table 1. Drug class definitions by WHO-ATC code

WHO ATC = world health organization anatomical therapeutic chemical.

Statistical analysis

The original data were entered into a FileMaker Pro 11 database and subsequently exported into Excel 2011 for ATC coding and linking, before transferal into STATA software version 13 (StataCorp, College Station, TX, USA) for data analysis; statistical significance at p-value < 0.05 was assumed. Descriptive statistics were utilized to summarize the population. Differences in prescribing patterns between those with and without dementia were assessed using the χ 2 test (Fisher's exact test if expected cell frequency was <5) for categorical variables, and Student's t-test (normally distributed) or Mann–Whitney U test (non-normally distributed) for continuous variables. To control for age, sex, and co-morbidity (Cumulative Illness Rating Scale in Geriatrics) effects, these were entered as independent variables into a model for each dependent variable, utilizing multivariate linear, or logistic regression, for continuous or binary dependent variables, respectively. Results are reported in terms of adjusted odds ratios (aOR) and their 95% confidence intervals (95% CI).

Results

Study population characteristics

Of 676 patients eligible for study enrolment, 598 were recruited and had a diagnosis of dementia or no dementia assigned (Figure 1). In total, a quarter of patients had dementia (N = 149); 53/149 (35.5%) had a known diagnosis prior to the study, and another 16/149 (11%) had known cognitive impairment. Eighty patients (53.5%) were diagnosed with dementia de-novo in the study, 29% (N = 23) of whom had moderate or severe dementia.

Figure 1. Flow diagram of participant.

Fifteen patients had missing medication data, resulting in 583 patients (86% of all admissions) with linked medication and clinical data. There was no significant difference in terms of the proportion of patients with missing medication data between those with and without dementia (χ 2 = 1.1; p-value = 0.29). Just under half of the study population were male (49%; N = 285), the median age was 79 years (Interquartile range = 74–84) and the vast majority were admitted from a home environment (own home, children's home, or social/sheltered accommodation) (91%; N = 530) (Table 2). PwD were significantly older, more dependent, and had higher co-morbidities than those without dementia (all p-values < 0.001). PwD were also significantly more likely to be admitted from a nursing home, to be acutely admitted to hospital, or to have delirium on admission (all p-values ≤ 0.001). One-fifth (N = 115) of all patients were diagnosed with delirium at admission and PwD constituted the majority of these cases (73%; N = 84).

Table 2. Demographics of study population

a N = two dementia patients without completed medication data.

b N = 13 non-dementia patients without completed medication data.

*Statistically significant at p-level < 0.05, utilizing MWU test.

**Statistically significant at p-level < 0.05, utilizing χ 2 test.

MWU = Mann–Whitney U test, CIRS-G = cumulative illness rating scale in geriatrics, IQR = inter-quartile range.

Prescribing patterns

Six patients were taking no medication on admission. PwD were prescribed almost one medication more per patient, on average, than those without dementia (mean ± standard deviation = 7.9 ± 3.3 vs. 7.1 ± 3.6; T= −2.1; p-value = 0.04) as shown in Table 3. However, when corrected for age, sex, and co-morbidity, this difference became non-significant (β = 0.3; 95% CI = −0.4–1.0; p-value = 0.43). The prevalence of polypharmacy was 84% in PwD and 77% in people without dementia; however, this difference was not significant (p = 0.08). Furthermore, there was no significant difference between the two groups in terms of the prevalence of major polypharmacy (27% in PwD and 23% in people without dementia; p-value = 0.35).

Table 3. Prescribing patterns in hospitalized patients with and without dementia

a Psychotropic defined as anti-psychotics, anti-depressants, anxiolytic, hypnotics, anti-convulsants/mood-stabilizer, and anti-dementia drugs.

b Deliriogenic medications defined by group consensus a priori.

c Systemic anti-cholinergics defined by group consensus a priori.

d Systemic non-steroidal anti-inflammatory drugs not included in the potentially deliriogenic drug category, but shown here for illustration purposes.

e p-value for two-way table with measures of association.

f Adjusted odds ratio for dependent variable utilizing linear or logistic regression as appropriate, with age, sex, and CIRS-G as the independent variables.

*Statistically significant at p-level < 0.05, utilizing Student's t-test.

**Statistically significant at p-level < 0.05, utilizing χ 2 test or Fishers exact test.

ǂStatistically significant at p-level < 0.05, utilizing logistic regression.

^Although significant at p-level < 0.05, this variable does not contain a minimum of ten cases of event and no event that are usually required for logistic regression analysis, therefore the findings should not be interpreted as statistically significant.

CIRS-G = Cumulative Illness Rating Scale in Geriatrics, aOR = adjusted odds ratio, NSAID = Non-steroid anti-inflammatory drug, β = beta- coefficient, 95% CI = 95% confidence interval.

PwD were significantly more likely to be prescribed at least one psychotropic medication (χ 2 = 28.9; aOR = 2.6, 95% CI = 1.7–4.0; p-value < 0.001). Atypical anti-psychotics, anti-depressants, anxiolytics, and anti-dementia drugs were all significantly more likely to be prescribed to PwD, even controlling for age, sex, and co-morbidity (all p-values < 0.05). However, there was no significant difference in hypnotic, anti-convulsant/mood-stabilizer, or typical anti-psychotic prescription between the two groups (all p-values > 0.05). The prevalence of psychotropic polypharmacy was 37% in PwD and 14% in people without dementia and thus PwD were over three times more likely to experience psychotropic polypharmacy (χ 2 = 35.9; aOR = 3.5; 95% CI = 2.1–5.6; p-value < 0.001). Sensitivity analyses found that even when we excluded anti-dementia drugs and subsequently anti-convulsants/mood-stabilizers from our definition of psychotropics, PwD were still significantly more likely to be prescribed at least one psychotropic (p-values ≤ 0.002) and to be exposed to psychotropic polypharmacy (p-values < 0.001) than those without dementia (Table 3). Removing these two classes of medications reduced the prevalence of psychotropic polypharmacy in patients with and without dementia to 29% versus 14% (excluding N06D), and then to 24% versus 10% (excluding N06D and N03A) respectively.

Looking at psychotropic medications in more detail, 32% of PwD were prescribed anti-depressants, compared to 19% of people without dementia (χ 2 = 10.1; aOR = 2.1; 95% CI = 1.3–3.3; p-value = 0.002). Similarly, 14% of PwD (N = 20) were prescribed at least one anti-psychotic, compared to 5% of their peers (N = 21) (χ 2 = 13.0; aOR = 3.7; 95% CI = 1.8–7.6; p-value < 0.001). In terms of those who had a previous diagnosis of dementia (N = 53), 28% (N = 15) were prescribed an anti-psychotic, compared to just 5% (N = 5) of those who had no prior diagnosis or a diagnosis of cognitive impairment (N = 94). Patients admitted from nursing homes were almost five times more likely to be prescribed an anti-psychotic than those who were admitted from home controlling for dementia diagnosis, age, sex, and co-morbidity (χ 2 = 26.7; aOR = 4.8; 95% CI = 1.9–12.1; p-value = 0.001). Atypical anti-psychotics (N = 30) were more commonly prescribed than typical anti-psychotics (N = 14), predominantly quetiapine (N = 17), and olanzapine (N = 11).

Just over half of all patients were prescribed ≥1 potentially deliriogenic medication (54%), with no differences in the level of prescribing of these agents between the two groups (χ 2 < 0.01; aOR = 0.9; 95% CI = 0.6–1.4; p-value = 0.6). Benzodiazepines and systemic anti-cholinergics were significantly more likely to be prescribed to PwD (both p-value < 0.05), but differences became non-significant after adjusting for age, sex, and co-morbidity (both p-value > 0.05).

The four most commonly prescribed WHO ATC anatomical groups were (i) cardiovascular system, (ii) blood and blood forming organs, (iii) alimentary tract and metabolism, and (iv) nervous system, prescribed to 87%, 70%, 70%, and 60% of all patients, respectively (see Table S1 published as supplementary material online attached to the electronic version of this paper at www.journals.cambridge.org/jid_IPG). There were no differences in the level of prescribing of any of the 13 included WHO-ATC anatomical groups (all p-values > 0.05), except for nervous system drugs, which were more commonly prescribed to PwD (χ 2 = 19.6; aOR = 2.0, 95% CI = 1.3–3.2; p-value = 0.003).

Discussion

Main findings

This retrospective cross-sectional study aimed to explore the prescribing patterns of psychotropic, anti-cholinergic, and deliriogenic medications, and polypharmacy, in a well-defined cohort of hospitalized older Irish patients; and to assess whether having dementia influenced these prescribing patterns. Overall, we found that this population was prescribed high levels of medication, with over two-thirds experiencing polypharmacy and a quarter experiencing major polypharmacy. PwD were more likely to be prescribed psychotropic medications and to experience psychotropic polypharmacy. We found no differences in the prescribing patterns in terms of number of medications, anti-cholinergic medications, deliriogenic medications, or any of the other main WHO ATC anatomical groups, except for nervous system medications.

Another important finding of the Cork Dementia Study was that only 35.5% of PwD had an explicit diagnosis of dementia prior to the study. Previous studies conducted in Australia (Travers et al., Reference Travers, Byrne, Pachana, Klein and Gray2013) and the UK (Sampson et al., Reference Sampson, Blanchard, Jones, Tookman and King2009) reported similar levels of under-diagnosis in PwD requiring an admission to hospital. This low rate of diagnosis may result in inappropriate medications being prescribed to PwD and hospital physicians incorrectly assuming capacity to consent for complex treatments (Timmons et al., Reference Timmons2015).

Our results are in agreement with several pharmacoepidemiological studies, which found a high prevalence of psychotropic medicine use in older hospitalized patients in general (Vidal et al., Reference Vidal2016), and significantly higher levels of psychotropic medications being prescribed to PwD than to those without dementia (Wills et al., Reference Wills, Claesson, Fastbom, Fratiglioni, Thorslund and Winblad1997; Hartikainen et al., Reference Hartikainen, Rahkonen, Kautiainen and Sulkava2003; Hosia-Randell and Pitkälä, Reference Hosia-Randell and Pitkälä2005; Wergeland et al., Reference Wergeland, Selbæk, Høgset, Söderhamn and Kirkevold2014). These findings are not surprising due to the ubiquity of BPSD in dementia. One large scale study of the longitudinal course of BPSD in PwD reported a five-year period prevalence of BPSD symptoms of 97% (Steinberg et al., Reference Steinberg2008). The most commonly reported symptoms were apathy, depression, and delusions. Of note in this study, many PwD already had BPSD at the time of initial dementia diagnosis. Furthermore, many studies have reported the presence of BPSD in Mild Cognitive Impairment (MCI) (Mariani et al., Reference Mariani, Monastero and Mecocci2007). There are very recently published criteria for diagnosing Mild Behavioral Impairment (MBI) (Ismail et al., Reference Ismail2016) that describe BPSD as a possible index manifestation of dementia, in advance of measurable cognitive impairment. This is an important conceptual advance in our understanding of dementia, and the prescription of psychotropic medications for changes in behavior or personality may give an indication of an emergent dementia. Furthermore, benzodiazepines are often associated with cognitive decline and dementia (Billioti de Gage et al., Reference Billioti de Gage2012); with the implication of causality between the two, although a recent study has questioned this causal association (Gray et al., Reference Gray2016). An alternative hypothesis is that anxiety can present as the index manifestation of dementia, with benzodiazepines prescribed, and when the underlying dementia ultimately declares itself, the benzodiazepine is labeled as the culprit for cognitive decline (Ismail et al., Reference Ismail2016). The bottom line is that BPSD are fundamental and core features of dementia, and result in greater illness burden, higher caregiver burden, poorer quality of life, higher rates of institutionalization, faster cognitive decline and death, and are associated with greater plaque and tangle burden (Tekin et al., Reference Tekin2001; Shin et al., Reference Shin, Carter, Masterman, Fairbanks and Cummings2005; Steinberg et al., Reference Steinberg2008).

Notwithstanding these important contextual issues, the fact remains that PwD are often excessively and inappropriately prescribed psychotropic medications, and for prolonged periods of time (Banerjee, Reference Banerjee2009). We know that in PwD, anti-psychotics significantly increase the risk of stroke and mortality (Maust et al., Reference Maust2015) and benzodiazepines significantly increase the risk of falls and hip fractures (Hartikainen et al., Reference Hartikainen, Lönnroos and Louhivuori2007). Prescription of multiple psychotropic agents results in even greater risk of adverse events (Mojtabai and Olfson, Reference Mojtabai and Olfson2010). It is imperative that prescribers and care providers adhere to guidelines, in so far as possible, by utilizing non-pharmacological interventions in the first instance and prescribing anti-psychotics as a last resort, with regular review and trials of withdrawal (Azermai et al., Reference Azermai, Petrovic, Elseviers, Bourgeois, Van Bortel and Vander Stichele2012). There is evidence to support the use of non-pharmacological interventions in managing BPSD (Cabrera et al., Reference Cabrera2015); however, better quality trials are required in this area.

The prevalence of anti-psychotic usage in the pharmacoepidemiological studies mentioned above ranged from 5% to 43% in those with dementia, highest in studies looking at institutionalized patients. In comparison, the prevalence of anti-psychotic usage in PwD in our study, where 91% of patients were admitted from a home environment, was 14%, lower than a previous study of home-dwelling older people (33%) (Hartikainen et al., Reference Hartikainen, Rahkonen, Kautiainen and Sulkava2003). This probably reflects the high rate of undiagnosed cases in our study, with only 35.5% having a prior diagnosis. The rates of prescribing in our study population with known dementia was 28%, similar to that found in the study by Hartikainen et al. The INAD study conducted in 2013 found that 41% of PwD were prescribed anti-psychotic medications during their admission in Irish hospitals, and also found poor levels of documentation of mental health assessment and drug indication (de Siún et al., Reference de Siún2014; Gallagher et al., Reference Gallagher2016). This figure is much higher than what we found in our study, and may reflect the purposeful selection of patients for the audit who had an explicit diagnosis of dementia and a longer length of stay, thereby potentially representing a much frailer sub-population of PwD. Nonetheless, this high figure is still alarming, considering the same audit conducted in England and Wales in 2012–2013 (Royal College of Psychiatrists, 2013) and Northern Ireland in 2014–2015 (O'Shea et al., Reference O'Shea, Manning, Ross, McErlean and Timmons2015) found much lower levels of anti-psychotic prescribing; 18% and 21%, respectively.

We found that patients admitted from a nursing home (N = 35) were almost five times more likely to be prescribed an anti-psychotic than those admitted from other home types. The INAD report also found that PwD admitted from nursing homes were significantly more likely to be prescribed an anti-psychotic compared to those admitted from their own home (46% vs. 19%; p < 0.001) (de Siún et al., Reference de Siún2014; Gallagher et al., Reference Gallagher2016). Similarly, a cross-sectional Finnish nursing home population study found that 43% of residents were prescribed anti-psychotics (Hosia-Randell and Pitkälä, Reference Hosia-Randell and Pitkälä2005). These findings would indicate that in a busy hospital setting, pharmacists and other healthcare professionals should prioritize PwD, along with patients admitted from nursing homes, for review of their anti-psychotic medications. However, a recent systematic review concluded that there is a distinct lack of such studies conducted in hospitalized dementia patients (Walsh et al., Reference Walsh, O'Riordan, Kearney, Timmons and Byrne2016). It is important that any anti-psychotic medication review conducted in a hospital setting involves effective communication with the patient's General Practitioner, carers, and nursing home staff, as it is necessary to know the indication for the anti-psychotic and whether any non-pharmacological intervention or dose reduction had been previously attempted (Mueller et al., Reference Mueller, Sponsler, Kripalani and Schnipper2012). It is also crucial that these community-based care providers are informed of any plans for dose titrations or withdrawals at hospital discharge to prevent the unintended re-commencement of these patients on anti-psychotics.

We did not find any significant differences in terms of anti-cholinergic, deliriogenic, or total number of medications prescribed between the two patient groups. We were surprised by the former finding, as previous studies have reported higher levels of anti-cholinergic prescribing in PwD (Roe et al., Reference Roe, Anderson and Spivack2002). One potential hypothesis is that a greater level of awareness surrounding the risk of cognitive decline with these agents has resulted in more careful prescribing in PwD. However, a repeated cross-sectional study conducted in Scotland found that despite the increasing evidence surrounding the adverse effects of anti-cholinergics, exposure to these agents in the elderly has actually increased in recent years (Sumukadas et al., Reference Sumukadas, McMurdo, Mangoni and Guthrie2013). We were unable to find literature on the prevalence of deliriogenic medication usage in PwD, thus our a priori hypothesis on this topic was purely speculative, based on the knowledge that the PwD in the study had more co-morbidities than their peers. Further research should be conducted to investigate the consequences of deliriogenic prescribing in PwD. The evidence on medication burden in PwD is mixed, with some studies finding PwD are prescribed more (Andersen et al., Reference Andersen, Viitanen, Halvorsen, Straume and Engstad2011) and others finding they are prescribed less medications (Schmader et al., Reference Schmader, Hanlon, Fillenbaum, Huber, Pieper and Horner1998) than people without dementia. The discrepancies may relate to population differences between the studies.

Our results differ from previous findings in that we did not detect any significant differences in prescribing patterns of cardiovascular agents between those with and without dementia, whereas previous studies found that PwD were prescribed significantly less of these agents (Wolf-Klein et al., Reference Wolf-Klein1988; Wills et al., Reference Wills, Claesson, Fastbom, Fratiglioni, Thorslund and Winblad1997). One study found that PwD had less co-morbidities than those without dementia (Wolf-Klein et al., Reference Wolf-Klein1988). Another group suggested that people without cardiovascular disease may live longer and thus develop dementia without requiring cardiovascular agents (Wills et al., Reference Wills, Claesson, Fastbom, Fratiglioni, Thorslund and Winblad1997). Given the known links between cerebrovascular disease and dementia, we would suggest that reduced cardiovascular medication prescribing may have resulted from practitioners reducing non-essential medications, such as statins, in older, frailer PwD, especially in more advanced disease. Our cohort of PwD, where 64.5% had no previous diagnosis, probably reflects true prescribing rates without any bias from prescriber's dementia status knowledge. Our analysis shows that drug use by patients with and without dementia was relatively similar for all groups of medications, once age, sex, and co-morbidity were considered, except for nervous system medications.

Strengths and limitations

The main strength of this research was the large number of patients recruited into this multi-centered trial and the vast amount of rich data that were collected from each patient allowing us to tease apart effects of dementia from confounding factors such as age, sex, and co-morbidity.

The main limitation of this study is due to the retrospective nature of the medication analysis, so that it was not possible to resolve any ambiguous medication data entries. However, the quality of data collection was quite high and this ambiguity rarely occurred. Second, as the study is observational, it is not possible to draw any conclusions on causality, as dementia or cognitive impairment may have been the cause of or potentially even the result of differences in medication usage between the two patient groups. Third, the lack of information on strength, quantity, and duration of medication usage is a limitation to our study. It would have been interesting to investigate the differences in dosing within and between the two patient groups, as toxicity with anti-psychotics, for example, is largely dose-dependent (De Hert et al., Reference De Hert, Detraux, van Winkel, Yu and Correll2012). Finally, as the study was conducted in only one county in Ireland, the findings may not be representative of the entire older Irish population. However, as the demographic profile of Cork County is relatively similar to that of the rest of the country, we believe these results may possibly be representative of the entire older Irish population.

Conclusion

Psychotropic drug use and polypharmacy is highly prevalent, and dementia is under-diagnosed among older Irish hospitalized patients. PwD are more likely to be prescribed anti-psychotics, anti-depressants, anxiolytics, and anti-dementia drugs. PwD are also more likely to be exposed to psychotropic polypharmacy. These differences in prescribing patterns may be largely attributed to BPSD in dementia, and NPS in pre-dementia clinical syndromes like MCI and MBI. Longitudinal research is required to assess the long-term impact that medication usage or non-usage has on the development of dementia in older people and also to assess the impact that a diagnosis of dementia has on the physician's prescribing patterns. High quality trials of multi-disciplinary team medication reviews should be conducted in the acute care setting, targeting older patients at high risk of potentially inappropriate prescribing of anti-psychotics, namely PwD and those admitted from nursing homes.

Conflict of interest

None.

Description of authors’ roles

Study concept and design: KAW, NOR, SB, JB, DM, ST. Acquisition of Data: KAW, NOR, ST. Analysis and Interpretation of data: KAW, NOR, SB, ST. Preparation of paper: KAW. Critical Review of paper: NOR, SB, JB, DM, ST. Final approval of version to be published: KAW, NOR, SB, JB, DM, ST.

Acknowledgments

The original Cork Dementia Study was supported by the Health Research Board grant number HRA HSR/2011/4. This research was funded by the Health Research Board and Atlantic Philanthropies, a limited life foundation, and was conducted as part of the SPHeRE Programme under Grant No. SPHeRE/2013/1. The investigators were solely responsible for the design, planning, conducting, interpretation, and publication of this study and the funding sources did not participate in such. We gratefully acknowledge all the researchers, staff, and patients who were involved in the original Cork Dementia Study. We also acknowledge the assistance of Dr Tony Fitzgerald for his help with STATA, Mr David O'Riordan for proof-reading the paper and Dr Maire O'Dwyer for her help with defining psychotropics.

Supplementary material

To view supplementary material for this paper, please visit http://dx.doi.org/.10.1017/S1041610216001307

References

Alzheimer's Disease International (2015). World Alzheimer's Report. London: Alzheimer's Disease International.Google Scholar
Andersen, F., Viitanen, M., Halvorsen, D. S., Straume, B. and Engstad, T. A. (2011). Co-morbidity and drug treatment in Alzheimer's disease. A cross sectional study of participants in the dementia study in northern norway. BMC Geriatrics, 11, 17.Google Scholar
Avorn, J. et al. (1992). A randomized trial of a program to reduce the use of psychoactive drugs in nursing homes. New England Journal of Medicine, 327, 168173.CrossRefGoogle ScholarPubMed
Azermai, M., Petrovic, M., Elseviers, M. M., Bourgeois, J., Van Bortel, L. M. and Vander Stichele, R. H. (2012). Systematic appraisal of dementia guidelines for the management of behavioural and psychological symptoms. Ageing Research Reviews, 11, 7886.Google Scholar
Banerjee, S. (2009). The use of Antipsychotic Medication for People with Dementia: Time for Action. London: Department of Health.Google Scholar
Billioti de Gage, S. et al. (2012). Benzodiazepine use and risk of dementia: prospective population based study. BMJ, 345, e6231.Google Scholar
Bishara, D., Taylor, D., Howard, R. J. and Abdel-Tawab, R. (2009). Expert opinion on the management of behavioural and psychological symptoms of dementia (BPSD) and investigation into prescribing practices in the UK. International Journal of Geriatric Psychiatry, 24, 944954.CrossRefGoogle ScholarPubMed
Borbasi, S., Jones, J., Lockwood, C. and Emden, C. (2006). Health professionals’ perspectives of providing care to people with dementia in the acute setting: toward better practice. Geriatric Nursing, 27, 300308.Google Scholar
Cabrera, E. et al. (2015). Non-pharmacological interventions as a best practice strategy in people with dementia living in nursing homes. A systematic review. European Geriatric Medicine, 6, 134150.Google Scholar
Cahill, S., O'Shea, E. and Pierce, M. (2012). Creating Excellence in Dementia Care: A Research Review for Ireland's National Dementia Strategy. Dublin: Dementia Services Information and Development Centre (DSIDC).Google Scholar
Central Statistics Office (2012). Census 2011 Reports. Dublin, Ireland: Central Statistics Office.Google Scholar
Clegg, A. and Young, J. B. (2011). Which medications to avoid in people at risk of delirium: a systematic review. Age and Ageing, 40, 2329.Google Scholar
Collamati, A. et al. (2016). Anticholinergic drugs and negative outcomes in the older population: from biological plausibility to clinical evidence. Aging Clinical and Experimental Research, 28, 2535.Google Scholar
De Hert, M., Detraux, J., van Winkel, R., Yu, W. and Correll, C. U. (2012). Metabolic and cardiovascular adverse effects associated with antipsychotic drugs. Nature Reviews Endocrinology, 8, 114126.Google Scholar
de Siún, A. et al. (2014). Irish National Audit of Dementia Care in Acute Hospitals. Cork: National Audit of Dementia Care.Google Scholar
Department of Health (2014). The Irish National Dementia Strategy. Dublin: Department of Health.Google Scholar
Gallagher, P. et al. (2016). Antipsychotic prescription amongst hospitalized patients with dementia. QJM. Epublished ahead of print, DOI: 10.1093/qjmed/hcw023.Google Scholar
Giron, M. S. T., Forsell, Y., Bernsten, C., Thorslund, M., Winblad, B. and Fastbom, J. (2001). Psychotropic drug use in elderly people with and without dementia. International Journal of Geriatric Psychiatry, 16, 900906.Google Scholar
Gnjidic, D. et al. (2012). Polypharmacy cutoff and outcomes: five or more medicines were used to identify community-dwelling older men at risk of different adverse outcomes. Journal of Clinical Epidemiology, 65, 989995.Google Scholar
Gray, S. L. et al. (2016). Benzodiazepine use and risk of incident dementia or cognitive decline: prospective population based study. BMJ, 352, i90.Google Scholar
Hajjar, E. R., Cafiero, A. C. and Hanlon, J. T. (2007). Polypharmacy in elderly patients. The American Journal of Geriatric Pharmacotherapy, 5, 345351.Google Scholar
Hartikainen, S., Lönnroos, E. and Louhivuori, K. (2007). Medication as a risk factor for falls: critical systematic review. The Journals of Gerontology Series A: Biological Sciences and Medical Sciences, 62, 11721181.Google Scholar
Hartikainen, S., Rahkonen, T., Kautiainen, H. and Sulkava, R. (2003). Use of psychotropics among home-dwelling nondemented and demented elderly. International Journal of Geriatric Psychiatry, 18, 11351141.Google Scholar
Hosia-Randell, H. and Pitkälä, K. (2005). Use of psychotropic drugs in elderly nursing home residents with and without dementia in Helsinki, Finland. Drugs & Aging, 22, 793800.Google Scholar
Ismail, Z. et al. (2016). Neuropsychiatric symptoms as early manifestations of emergent dementia: provisional diagnostic criteria for mild behavioral impairment. Alzheimer's & Dementia: The Journal of the Alzheimer's Association, 12, 195202.Google Scholar
Lawlor, B. (2002). Managing behavioural and psychological symptoms in dementia. The British Journal of Psychiatry: The Journal of Mental Science, 181, 463465.Google Scholar
Mariani, E., Monastero, R. and Mecocci, P. (2007). Mild cognitive impairment: a systematic review. Journal of Alzheimer's Disease, 12, 2335.Google Scholar
Maust, D. T., Langa, K. M., Blow, F. C. and Kales, H. C. (2016). Psychotropic use and associated neuropsychiatric symptoms among patients with dementia in the USA. International Journal of Geriatric Psychiatry. Epublished ahead of print, DOI: 10.1002/gps.4452.Google Scholar
Maust, D. T. et al. (2015). Antipsychotics, other psychotropics, and the risk of death in patients with dementia: number needed to harm. JAMA Psychiatry, 72, 438445.Google Scholar
Mohamed, S., Rosenheck, R., Lyketsos, C. G., Kaczynski, R., Sultzer, D. L. and Schneider, L. S. (2012). Effect of second-generation antipsychotics on caregiver burden in Alzheimer's disease. Journal of Clinical Psychiatry, 73, 121128.Google Scholar
Mojtabai, R. and Olfson, M. (2010). National trends in psychotropic medication polypharmacy in office-based psychiatry. Archives of General Psychiatry, 67, 2636.CrossRefGoogle ScholarPubMed
Mueller, S. K., Sponsler, K., Kripalani, S. and Schnipper, J. L. (2012). Hospital-based medication reconciliation practices: a systematic review. Archives of Internal Medicine, 172, 10571069.Google Scholar
O'Shea, E., Manning, E., Ross, E., McErlean, S. and Timmons, S. (2015). Northern Ireland Audit of Dementia Care in Acute Hospitals. Cork: Northern Ireland Audit of Dementia.Google Scholar
Patterson, S. M., Hughes, C. M., Crealey, G., Cardwell, C. and Lapane, K. L. (2010). An evaluation of an adapted US model of pharmaceutical care to improve psychoactive prescribing for nursing home residents in Northern Ireland (Fleetwood Northern Ireland study). Journal of the American Geriatrics Society, 58, 4453.Google Scholar
Porsteinsson, A. P. et al. (2014). Effect of citalopram on agitation in alzheimer disease: the citad randomized clinical trial. JAMA, 311, 682691.Google Scholar
Roe, C. M., Anderson, M. J. and Spivack, B. (2002). Use of anticholinergic medications by older adults with dementia. Journal of the American Geriatrics Society, 50, 836842.CrossRefGoogle ScholarPubMed
Rosenberg, P. B. et al. (2010). Sertraline for the treatment of depression in Alzheimer disease. American Journal of Geriatric Psychiatry, 18, 136145.Google Scholar
Royal College of Psychiatrists (2013). National Audit of Dementia Care in General Hospitals 2012-13: Second Round Audit Report and Update: Healthcare Improvement Quality Partnership.Google Scholar
Sampson, E. L., Blanchard, M. R., Jones, L., Tookman, A. and King, M. (2009). Dementia in the acute hospital: prospective cohort study of prevalence and mortality. British Journal of Psychiatry, 195, 6166.Google Scholar
Schmader, K. E., Hanlon, J. T., Fillenbaum, G. G., Huber, M., Pieper, C. and Horner, R. (1998). Medication use patterns among demented, cognitively impaired and cognitively intact community-dwelling elderly people. Age and Ageing, 27, 493501.Google Scholar
Schneider, L. S., Dagerman, K. S. and Insel, P. (2005). Risk of death with atypical antipsychotic drug treatment for dementia: meta-analysis of randomized placebo-controlled trials. JAMA, 294, 19341943.Google Scholar
Seitz, D. P. et al. (2013). Pharmacological treatments for neuropsychiatric symptoms of dementia in long-term care: a systematic review. International Psychogeriatrics, 25, 185203.CrossRefGoogle ScholarPubMed
Shin, I.-S., Carter, M., Masterman, D., Fairbanks, L. and Cummings, J. L. (2005). Neuropsychiatric symptoms and quality of life in Alzheimer disease. The American Journal of Geriatric Psychiatry, 13, 469474.Google Scholar
Søndergård, L., Lopez, A. G., Andersen, P. K. and Kessing, L. V. (2008). Mood-stabilizing pharmacological treatment in bipolar disorders and risk of suicide. Bipolar Disorders, 10, 8794.Google Scholar
Steinberg, M. et al. (2008). Point and 5-year period prevalence of neuropsychiatric symptoms in dementia: the cache county study. International Journal of Geriatric Psychiatry, 23, 170177.Google Scholar
Sumukadas, D., McMurdo, M. E. T., Mangoni, A. A. and Guthrie, B. (2013). Temporal trends in anticholinergic medication prescription in older people: repeated cross-sectional analysis of population prescribing data. Age and ageing, 43, 515521.Google Scholar
Tekin, S. et al. (2001). Orbitofrontal and anterior cingulate cortex neurofibrillary tangle burden is associated with agitation in Alzheimer disease. Annals of Neurology, 49, 355361.Google Scholar
Timmons, S. et al. (2015). Dementia in older people admitted to hospital: a regional multi-hospital observational study of prevalence, associations and case recognition. Age and Ageing, 44, 993999.Google Scholar
Travers, C., Byrne, G., Pachana, N., Klein, K. and Gray, L. (2013). Prospective observational study of dementia and delirium in the acute hospital setting. Internal Medicine Journal, 43, 262269.Google Scholar
Van den Broeck, J., Cunningham, S. A., Eeckels, R. and Herbst, K. (2005). Data cleaning: detecting, diagnosing, and editing data abnormalities. PLoS Medicine, 2, 966.Google Scholar
Vidal, X. et al. (2016). Elderly patients treated with psychotropic medicines admitted to hospital: associated characteristics and inappropriate use. European Journal of Clinical Pharmacology, 72, 755764.Google Scholar
Von Elm, E. et al. (2007). The strengthening the reporting of observational studies in epidemiology (STROBE) statement: guidelines for reporting observational studies. Preventive Medicine, 45, 247251.CrossRefGoogle ScholarPubMed
Walsh, K. A., O'Riordan, D., Kearney, P. M., Timmons, S. and Byrne, S. (2016). Improving the appropriateness of prescribing in older patients: a systematic review and meta-analysis of pharmacists’ interventions in secondary care. Age and Ageing, 45, 201209.Google Scholar
Weintraub, D. et al. (2010). Sertraline for the treatment of depression in Alzheimer disease: week-24 outcomes. American Journal of Geriatric Psychiatry, 18, 332340.Google Scholar
Wergeland, J. N., Selbæk, G., Høgset, L. D., Söderhamn, U. and Kirkevold, Ø. (2014). Dementia, neuropsychiatric symptoms, and the use of psychotropic drugs among older people who receive domiciliary care: a cross-sectional study. International Psychogeriatrics, 26, 383391.Google Scholar
WHO (2015). Collaborating centre for drug statistics methodology. About the ATC/DDD system. Available at http://www.whocc.no; last accessed 1 July 2015.Google Scholar
Wills, P., Claesson, C. B., Fastbom, J., Fratiglioni, L., Thorslund, M. and Winblad, B. (1997). Drug use by demented and non-demented elderly people. Age and Ageing, 26, 383391.Google Scholar
Wolf-Klein, G. P. et al. (1988). Are Alzheimer patients healthier? Journal of the American Geriatrics Society, 36, 219224.Google Scholar
Zekry, D. et al. (2009). Does dementia predict adverse hospitalization outcomes? A prospective study in aged inpatients. International Journal of Geriatric Psychiatry, 24, 283291.Google Scholar
Figure 0

Table 1. Drug class definitions by WHO-ATC code

Figure 1

Figure 1. Flow diagram of participant.

Figure 2

Table 2. Demographics of study population

Figure 3

Table 3. Prescribing patterns in hospitalized patients with and without dementia

Supplementary material: File

Walsh supplementary material

Supplementary Table

Download Walsh supplementary material(File)
File 15.4 KB