The Incidence of Benzodiazepine and Related Drug Use in Persons with and without Alzheimer’s Disease

Abstract

Background:

Benzodiazepines and related drugs (BZDR) are occasionally used to treat certain symptoms of Alzheimer’s disease (AD). However, the risks related to BZDR use are high in older persons. Although frequent BZDR use has been reported in persons with AD, no previous study has focused specifically on the incidence of BZDR use in this population.

Objective:

We investigated the incidence of BZDR use in persons with and without AD during a five-year follow-up.

Methods:

The Finnish nationwide, register-based MEDALZ cohort includes all AD cases who received a clinically verified AD diagnosis in 2005–2011 (n = 70,718) and their matched comparison persons. Incidence of BZDR, including benzodiazepines (lorazepam, oxazepam, temazepam, alprazolam, chlordiazepoxide, diazepam, and nitrazepam) and Z-drugs (zolpidem and zopiclone), use was investigated in the cohort from two years before to three years after the diagnosis of AD. Further, initial BZDRs were investigated.

Results:

The incidence of BZDR use was higher in persons with AD starting from 12 months before the diagnosis and peaked at six months after the diagnosis of AD (incidence rate ratio [IRR] = 2.6, 95% confidence interval [CI] = 2.5–2.8). Benzodiazepines were more frequently initiated by persons with AD, with the incidence peaking at six months after the diagnosis (IRR = 4.5, 95% CI = 4.1–4.9) and remaining over three times higher than in comparison persons until three years after the diagnosis.

Conclusion:

Early symptomatic treatment with BZDRs is contrary to AD treatment guidelines. As BZDRs impair cognition, the observed early treatment with BZDRs may complicate the monitoring of AD treatment effectiveness.

Keywords

Alzheimer’s disease benzodiazepines drug utilization registries

INTRODUCTION

The number of persons with Alzheimer’s disease(AD), the most common cause of dementia, isincreasing as the population ages [1]. Up to 97% of persons with dementia experience behavioral andpsychological symptoms of dementia (BPSD) during the course of the disorder [2], and similar prevalence has been observed specifically in persons with AD [3].

Benzodiazepines and related drugs (BZDR) can be used in treatment of particular BPSDs, including anxiety, agitation, and sleep disturbances [4]. They can be used in short-term treatment in persons with AD if non-pharmacological and other pharmacological treatments have not been adequate or if only infrequent treatment is needed. Older persons, however, are more sensitive to the effects of these drugs, resulting in an increased risk of adverse drug events [5]. BZDR use increases the risk of falls and hip fractures [6, 7], which may further lead to other severe outcomes including increased health care service use, morbidity, and mortality [8]. High age and multiple comorbidities predispose older persons to BZDR dependence [9]. Especially long-term benzodiazepine use has been associated with cognitive decline and an increased risk of AD [10, 11].

A previous cross-sectional and nationwide study in Finland demonstrated that 29% of persons with AD used BZDRs during the first year after the diagnosis of AD [12]. Further, a longitudinal study in Finland demonstrated 45% of persons with AD using BZDRs during a four-year follow-up [13]. In both studies, the prevalence of BZDR use was higher in persons with AD compared with their matched comparison persons without AD. Several other studies have reported a high prevalence of BZDR use in persons with AD in various settings [3 , 14–26]. Although the risks related to BZDR use in older persons are well known and the adverse effects on cognition have been demonstrated, there are no previous studies regarding the incidence of BZDR use in persons with AD. Similarly, the temporal relationship between the initiation of BZDR use and AD diagnosis has not been previously assessed.

The aim of this study was to investigate theincidence of benzodiazepine and related drug use from two years before to three years after the diagnosis of AD in a Finnish nationwide cohort of community-dwelling persons with and without AD.

MATERIALS AND METHODS

Cohort

This nationwide, register-based study was based on the MEDALZ (Medication use and Alzheimer’s disease) cohort [12]. The cohort included all Finnish persons diagnosed with AD between 2005 and 2011 (n = 73,005). Persons with dementia related to Parkinson’s disease were excluded, leaving 70,718 persons with AD in the study population. For each person with AD, four age-, gender-, and region of residence-matched comparison persons without AD were selected from a nationwide register including all residents. As a result, the cohort consisted of 353,576 persons in total (Fig. 1). The cohort [12] and the applied registers [27] have been previously described in more detail.

Persons with the verified diagnosis of AD were identified from the Special Reimbursement Register maintained by the Social Insurance Institution (SII). The verified diagnosis included symptoms consistent with mild to moderate AD, decrease in social capacity, computed tomography or magnetic resonance imaging scan, exclusion of alternative diagnoses, and confirmation of the diagnosis by a neurologist or geriatrician [28]. The diagnosis of AD was based on the NINCDS-ADRDA and DSM-IV criteria [29, 30] and it has been described in more detail previously [27]. The validity of the AD diagnosis based on the Special Reimbursement Register has been demonstrated [31].

Drug use

Data on drug use from years 1995–2012 were obtained from the Prescription Register. The Prescription Register contains information on each reimbursed drug purchase for all residents in Finland [27]. All drugs are coded according to the Anatomical Therapeutic Chemical (ATC) classification [32]. The register data relevant for this study included package size, strength, dosage form, date of purchase, and the purchased amount in defined daily doses [33]. Drugs used during stays at hospitals or public nursing homes are not recorded in the register and, therefore, only community-dwelling persons were included in the analyses.

BZDRs were categorized according to the ATC classification as benzodiazepines (classes N05BA and N05CD) and benzodiazepine-related drugs (“Z-drugs”, N05CF). Lorazepam, oxazepam, and temazepam were categorized as medium-acting benzodiazepines whereas alprazolam, chlordiazepoxide, diazepam, and nitrazepam as long-acting benzodiazepines. Zolpidem and zopiclone were categorized as Z-drugs. Midazolam, triazolam, and zaleplon were excluded from the analyses because they were not reimbursed during the study period. Furthermore, clobazam was excluded from the analyses because it is indicated only for the treatment for epilepsy. The Prescription Register provides valid information on BZDR use in older community-dwelling Finnish persons, especially in regular drug use [34].

Fixed dosage assumptions based on tablets or defined daily doses are not valid in older Finnish persons [35, 36]. Thus, BZDR use was modeled with the PRE2DUP method [37]. This method was based on modeling individual purchasing behavior by calculating the sliding averages of the daily dose. The method considered regularity of drug purchases, possible stockpiling of drugs and hospitalization periods. Each drug was modeled separately according to the ATC classification. The model provided drug use periods, i.e., dates of the beginning and the end of continuous drug use. The use of benzodiazepines and Z-drugs was modeled similarly. For this study, we combined overlapping benzodiazepine and Z-drug use periods to retrieve the duration of BZDR use. During BZDR use, persons were allowed to switch between drug substances unless there were any breaks in drug use. BZDR polypharmacy (use of two or more BZDRs concomitantly) was defined as overlapping drug use periods of ≥60 days.

Study design

One-year washout period for BZDR use was utilized to exclude prevalent users from the analyses (Fig. 1). The washout period began three years before and ended two years before the diagnosis of AD, including the corresponding matching date of comparison persons. Persons with any BZDR use during the washout period were excluded from all analyses. Other exclusion criteria were ≥6 months hospital stay during the washout period and ongoing ≥90 days hospital stay at the end of the washout period because drug use during hospitalizations was not known. Furthermore, comparison persons for the excluded persons with AD were excluded. Finally, persons with AD without any comparison persons were excluded to maintain the matching.

For the included persons, the study follow-up began two years before and ended three years after the diagnosis of AD or the corresponding matching date unless the follow-up was censored for any of the following reasons: ≥90 days hospitalization, death, end of study (December 31, 2012), or diagnosis of AD for the comparison persons. The AD status was considered as a time-dependent variable and, in total, 7,802 comparison persons were diagnosed with AD within three years after the matching date. For these comparison persons, the study follow-up in the comparison cohort ended two years before the diagnosis of AD. The incidence of BZDR use was investigated during the five-year study follow-up.

Comorbidities

Comorbid conditions recorded by the time of AD diagnosis, including the corresponding date of comparison persons, were obtained for each person from the Special Reimbursement Register since 1972. The Special Reimbursement Register contains information on each person’s entitlement to higher reimbursement of drugs due to chronic diseases [27]. A modified Charlson’s comorbidity index (CCI, including chronic heart failure, coronary artery disease, diabetes, asthma or chronic obstructive pulmonary disease [COPD], disseminated connective tissue diseases, rheumatoid arthritis and other comparable conditions, uremia requiring dialysis, severe anemia in connection with chronic renal failure, leukemia and other malignant diseases of blood and bone marrow including malignant diseases of the lymphatic system, breast cancer, prostate cancer, gynecological cancer, and malignant neoplasms) was computed for each person based on the comorbidities as in a previous study [38]. In addition, data on epilepsy, hypothyroidism and all chronic cardiovascular diseases (coronary artery disease, heart failure, hypertension, and arrhythmias) were obtained from the register.

Data on history of psychiatric disorders were collected from the Hospital Discharge Register maintained by the National Institute of Health and Welfare. Data since 1972 were applied in this study. The register contains information on admission and discharge dates as well as person’s diagnoses related to the inpatient admissions according to the International Statistical Classification of Diseases and Related Health Problems (ICD) classification [39]. Only psychiatric diagnoses from hospitalizations at least five years before the diagnosis of AD, including the corresponding date of comparison persons, were considered to exclude hospitalizations due to the prodromal symptoms of AD. Diagnoses for schizophrenia, schizotypal or delusional disorders (ICD-10 codes F20-29; ICD-9 codes 295, 297, 298, 3010 and 3012; ICD-8 codes 295, 297, 298, 29999, 30100 and 30120), bipolar disorder (ICD-10 codes F30-31; ICD-9 codes 2962, 2963, 2964 and 2967; ICD-8 codes 29610, 29620, 29630, 29688 and 29699), and severe depression (ICD-10 codes F32-39; ICD-9 codes 2961, 2968, 3004 and 3011; ICD-8 codes 29600, 30040, 30041 and 30110) were collected from the register.

Statistical analyses

The five-year incidence of BZDR use was defined as having at least one purchase of the drugs during the study follow-up. Incidence rates (IR) were calculated for each six-month interval during the five-year follow-up as a rate per 100 person-years. The IRs were compared between persons with AD and comparison persons with the Poisson regression and the results were reported as incidence rate ratios (IRR) with 95% confidence intervals (CI). Separate IR values for benzodiazepine and Z-drug use were calculated from persons initiating drug use with monotherapy.

Participants’ characteristics according to incident BZDR use were compared with the chi-squared test for categorical variables and with t-test or Mann-Whitney U test for the continuous variables. Mean, median, range, and interquartile range (IQR) were applied in describing the continuous variables.

The prevalence of BZDR polypharmacy was analyzed as having at least one polypharmacy period during the five-year follow-up. In addition, the duration of first BZDR use period was investigated. Initial drugs were investigated among BZDR users who initiated with monotherapy. Further, the number of BZDR initiations within 10 days after hospital discharge was investigated. All analyses were performed using SAS (version 9.3; SAS Institute Inc., Cary, NC, USA).

No ethics approval or informed consent from the cohort was required by the Finnish legislation as the persons in the sample were not contacted and only de-identified data were utilized. Permissions for data use were received from the maintainers of registers.

RESULTS

Study population

The study population included 211,955 persons with AD and comparison persons without AD in total (Table 1). The mean age of the study population at the time of AD diagnosis was 79.1 years (range 34.1–104.6). Most persons (60.3%) were women. The median follow-up time was 1,826 days (IQR = 1,371–1,826) in the whole study population, 1,687 days (IQR = 1,259–1,826) in persons with AD, and 1,826 days (IQR = 1,402–1,826) in comparison persons (p < 0.0001).

Incident benzodiazepine and related drug use

Altogether, 13,341 (25.7%) persons with AD and 27,028 (16.9 %) comparison persons initiated BZDR use during the five-year follow-up (p < 0.0001). BZDR users were more likely to be women (Table 1). Furthermore, BZDR users were more likely to have higher CCI, cardiovascular diseases, asthma/COPD, hypothyroidism, and history of psychiatric disorders.

The IR of BZDR use was higher in persons with AD compared with those without AD starting from 12 months before the diagnosis of AD and the difference remained significant until the end of the five-year follow-up (Fig. 2a). The difference between the IRs of BZDR use was at highest at six months after the diagnosis, when the IR in persons with AD was 11.2/100 person-years and in comparison persons 4.1/100 person-years (IRR = 2.6, 95% CI = 2.48–2.76). The IR of BZDR use decreased gradually in comparison persons during the five-year follow-up.

The IR of benzodiazepine use was higher in persons with AD throughout the five-year follow-up (Fig. 2b). The difference between the IRs was at highest at six months after the diagnosis, the IR being 6.4/100 person-years in persons with AD and 1.4/100 person-years in comparison persons (IRR = 4.5, 95% CI = 4.13–4.88). After the diagnosis, the IR of benzodiazepine use in persons with AD remained three to four times higher than in those without AD.

The difference between the IRs of Z-drug use was at highest at six months after the AD diagnosis (Fig. 2c), when the IRs were 4.4/100 person-years and 2.7/100 person-years in persons with and without AD, respectively (IRR = 1.6, 95% CI = 1.46–1.71). When compared to persons without AD, the IR of Z-drug use in persons with AD was higher from the diagnosis to 18 months after diagnosis.

Among the incident BZDR users, initiation with benzodiazepines was more frequent in persons with AD (54.0%) than in comparison persons (35.2% , p < 0.0001) during the five-year follow-up (Table 2). Medium-acting benzodiazepines were the initial drugs for 47.4% of BZDR users with AD and 26.7% of comparison persons using BZDRs (p < 0.0001). Use of long-acting benzodiazepines was less frequent in BZDR users with AD (6.6%) compared with comparison persons (8.6 %) using BZDRs (p < 0.0001). BZDR users with AD (46.0%) initiated drug use with Z-drugs less frequently compared with comparison persons (64.8% , p < 0.0001).

The median duration of the first BZDR use period was 121 days (IQR = 40–349) in persons with AD and 88 days (IQR = 37–211) in comparison persons (p < 0.0001). BZDR polypharmacy was twice as frequent in incident BZDR users with AD (9.1% , n = 1,213) compared with those without AD (4.4% , n = 1,189) (p < 0.0001). Zopiclone and oxazepam were the most common drugs used in combination by concomitant BZDR users with and without AD (24.7% and 27.3% , respectively, p = 0.1462). Among the incident BZDR users, 20.3% (n = 2,706) of persons with AD and 12.2% (n = 3,289) of comparison persons initiated their BZDR use within 10 days after discharge from hospital care (p < 0.0001).

DISCUSSION

To our knowledge, this is the first study to report the incidence of BZDR use in persons with AD. This incidence was higher in persons with AD compared with those without AD from one year before to three years after the diagnosis of the disease. Benzodiazepines were the most frequently initiated drugs in persons with AD and a considerable increase in benzodiazepine incidence occurred around the time of AD diagnosis, peaking at six months after the diagnosis.

The early symptomatic treatment with BZDRs in persons with AD is not in line with treatment guidelines [4, 28]. Cholinesterase inhibitors (ChEI) are the first-line pharmacological treatment for AD [4, 28] and more than 80% of persons with AD in Finland use them shortly after the diagnosis [38]. It may take up to six months to observe the beneficial effects of ChEIs [28]. Concomitant treatment with BZDRs may prevent monitoring the effectiveness of ChEI treatment because BZDR use has been associated with cognitive decline in persons with AD [19, 40].

Older persons are more sensitive to the central nervous system effects of BZDRs due to age-related changes in pharmacodynamics and pharmacokinetics [5] and, therefore, BZDR use may cause daytime sedation and impair alertness in this population [41]. BZDRs affect cognition, gait, and balance as well, resulting in an increased risk of falls and fractures [42]. Although the risk of injuries is at highest at the beginning of BZDR use, the risk remains high throughout the treatment. Therefore, the longer duration of the first BZDR use period in persons with AD compared with those without AD in the current study is alarming. Longer duration of use in persons with AD has been demonstrated in prevalent users as well, as a previous nationwide study in Finland reported 30% of persons with AD and 26% of persons without AD having long-term (≥180 days) BZDR use during a four-year follow-up (13).

Initiation of BZDR use during the first ten days after hospital discharge was more frequent in persons with AD compared with those without AD in our study. A previous study reported a similar finding in general older population as 13% of older persons initiated benzodiazepine use within 10 days after discharge [43]. The same study reported a three-fold risk of receiving initial BZDR prescription associated with hospital care. High initiation rate in our study was observed especially in persons with AD, which may result from increasing number and severity of BPSDs during acute hospitalization [44].

BZDR polypharmacy was twice as frequent inincident BZDR users with AD than in those withoutAD in this study. A previous longitudinal study reported that the 3-month prevalence of concomitant use of ≥2 benzodiazepines was 25% among benzodiazepine users with AD [17]; however, in that study, the total duration of concomitant use was not considered. An increased risk of adverse drug events has been associated with BZDR polypharmacy in general older population, as polypharmacy increased the risk of hip fractures more than BZDR monotherapy [45, 46]. The higher prevalence of BZDR polypharmacy in persons with AD raises concern as AD itself has been shown to be a risk factor for falls and fractures [47, 48] and, therefore, BZDR as well as psychotropic polypharmacy should be avoided in this population [28].

As BPSDs are highly prevalent in newly-diagnosed persons with AD [49], the higher incidence of BZDR use in persons with AD in this study may reflect the treatment of BPSDs. However, nonpharmacological treatment should be the first-line option in BPSD treatment [2, 4] and if pharmacological treatment is needed, cholinesterase inhibitors are the primary option [50, 51]. Further, if cholinesterase inhibitors are not effective enough, benzodiazepines can be used in infrequent or short-term treatment of anxiety and agitation [4]. However, the evidence on the effectiveness of benzodiazepines in the treatment for BPSDs in AD is insufficient [51] and the risk of associated adverse drug events is considerable [2]. It is noteworthy that benzodiazepine use may actually worsen the BPSDs. In the current study, benzodiazepine use consisted mainly of medium-acting drugs which are preferred over long-acting drugs because of smaller risk of accumulation due to delayed elimination and associated excess daytime sedation [52]. The Z-drugs can be used if treatment of mainly sleep disturbances is needed [4], but there are no randomized controlled trials on BZDR use for this indication in persons with AD [53]. The pharmacological treatment of BPSDs is problematic as there are safety concerns related to other pharmacological treatment options as well [51].

Due to the nationwide cohort in this study, the selection bias was minimal. Therefore, our results are representative of the community-dwelling Finnish persons with AD. In addition, major strengths of our research include the clinically verified diagnoses of AD and follow-up for the study population both before and after the diagnosis. The Finnish registers are comprehensive [27] and, therefore, they enable high-quality pharmacoepidemiological research. Our exposure modeling approach, based on the purchased amounts of drugs and the intervals between purchases obtained from the Prescription Register, enabled more realistic estimation on duration of drug use than the fixed dosage assumptions. With the drug use model, we defined BZDR polypharmacy as the concomitant use for ≥60 days to differentiate it from drug switches. Our data, with one-year washout period, enabled us to investigate the incidence of drug use. Furthermore, we were able to compare the incidence between persons with AD and the matched comparison persons without AD.

There are some recognized limitations regarding the use of register-based data. The Prescription Register did not include some small packages of non-reimbursed BZDRs, which may have led to minor underestimation of BZDR use in this study population. Moreover, the register-based data did not include BZDR use during hospital care or nursing home stays. The register data did not contain indication for BZDR use, either. Another limitation of this study concerns the lack of information on severity of AD and BPSDs. Further, history of psychiatric disorders was likely to be underestimated as the Hospital Discharge Register included only the most serious cases requiring inpatient treatment. However, the amount of underestimation was unlikely to differ between persons with and without AD.

In conclusion, the incidence of benzodiazepine and related drug use was higher in persons with AD compared with those without the disease from one year before the diagnosis. As clinicians, we are concerned about the incidence peak at six months after the diagnosis since early treatment with these drugs is contrary to treatment guidelines of the disease. Further, the concomitant use of these and antidementia drugs complicates the assessment of the effectiveness of antidementia treatment because benzodiazepines and related drugs have adverse effects on cognition. Due to the increasing use of benzodiazepines and related drugs before the diagnosis of AD, further studies on the associated risks are urgently needed.

Footnotes

ACKNOWLEDGMENTS

LS was funded by the University Pharmacy, HT by the Finnish Cultural Foundation and AMT by the European Regional Development Fund (Regional Council of Pohjois-Savo).

Authors’ disclosures available online ().

References

Alzheimer’s Association

2015

2015 Alzheimer’s disease facts and figures

Alzheimers Dement 11 332 384

Kales

Gitlin

Lyketsos

2015

Assessment and management of behavioral and psychological symptoms of dementia

BMJ 350 h369

Eustace

Coen

Walsh

Cunningham

Walsh

Coakley

Lawlor

2002

A longitudinal evaluation of behavioural and psychological symptoms of probable Alzheimer’s disease

Int J Geriatr Psychiatry 17 968 973

American Psychiatric Association (2007) Practice guideline for the treatment of patients with Alzheimer’s disease and other dementias, American Psychiatric Association, Available from: http://psychiatryonline.org/guidelines, [accessed on June 18, 2015]

Trifiró

Spina

2011

Age-related changes in pharmacodynamics: Focus on drugs acting on central nervous and cardiovascular systems

Curr Drug Metab 12 611 620

Hartikainen

Lönnroos

Louhivuori

2007

Medication as a risk factor for falls: Critical systematic review

J Gerontol A Biol Sci Med Sci 62 1172 1181

Bakken

Engeland

Engesæter

Ranhoff

Hunskaar

Ruths

2014

Risk of hip fracture among older people using anxiolytic and hypnotic drugs: A nationwide prospective cohort study

Eur J Clin Pharmacol 70 873 880

Friedman

Mendelson

2014

Epidemiology of fragility fractures

Clin Geriatr Med 30 175 181

Bogunovic

Greenfield

2004

Practical geriatrics:Use of benzodiazepines among elderly patients

Psychiatr Serv 55 233 235

10.

Barker

Greenwood

Jackson

Crowe

2004

Cognitive effects of long-term benzodiazepine use: A meta-analysis

CNS Drugs 18 37 48

11.

de Gage

Moride

Ducruet

Kurth

Verdoux

Tournier

Pariente

Bégaud

2014

Benzodiazepine use and risk of Alzheimer’s disease: Case-control study

BMJ 349 g5205

12.

Taipale

Koponen

Tanskanen

Tolppanen

Tiihonen

Hartikainen

2014

High prevalence of psychotropic drug use among persons with and without Alzheimer’s disease in Finnish nationwide cohort

Eur Neuropsychopharm 24 1729 1737

13.

Taipale

Koponen

Tanskanen

Tolppanen

Tiihonen

Hartikainen

2015

Long-term use of benzodiazepines and related drugs among community-dwelling persons with and without Alzheimer’s disease

Int Clin Psychopharmacol 30 202 208

14.

Montastruc

Gardette

Cantet

Piau

Lapeyre-Mestre

Vellas

Montastruc

Andrieu

2013

Potentially inappropriate medication use among patients with Alzheimer disease in the REAL. FR cohort: Be aware of atropinic and benzodiazepine drugs!

Eur J Clin Pharmacol 69 1589 1597

15.

Rosenberg

Mielke

Han

Leoutsakos

Lyketsos

Rabins

Zandi

Breitner

Norton

Welsh-Bohmer

2012

The association of psychotropic medication use with the cognitive, functional, and neuropsychiatric trajectory of Alzheimer’s disease

Int J Geriatr Psychiatry 27 1248 1257

16.

Ellul

Archer

Foy

CML

Poppe

Boothby

Nicholas

Brown

Lovestone

2007

The effects of commonly prescribed drugs in patients with Alzheimer’s disease on the rate or deterioration

J Neurol Neurosurg Psychiatry 78 233 239

17.

Lagnaoui

Moore

Moride

Miremont-Salamé

Bégaud

2003

Benzodiazepine utilization patterns in Alzheimer’s disease patients

Pharmacoepidemiol Drug Saf 12 511 515

18.

Balfour

O’Rourke

2003

Older adults with Alzheimer disease, comorbid arthritis and prescription of psychotropic medications

Pain 8 198 204

19.

Semla

Cohen

Freels

Paveza

Ashford

Gorelick

Luchins

Eisdorfer

1995

Psychotropic drug use in relation to psychiatric symptoms in community-living persons with Alzheimer’s disease

Pharmacotherapy 15 495 501

20.

Lopez

Becker

Sweet

Klunk

Kaufer

Saxton

DeKosky

2003

Patterns of change in the treatment of psychiatric symptoms in patients with probable Alzheimer’s disease from 1983 to 2000

J Neuropsychiatry Clin Neurosci 15 67 73

21.

Bartorelli

Giraldi

Saccardo

Cammarata

Bottini

Fasanaro

Trequattrini

2005

Effects of switching from an AChE inhibitor to a dual AChE-BuChE inhibitor in patients with Alzheimer’s disease

Curr Med Res Opin 21 1809 1817

22.

Rhee

Csernansky

Emanuel

Chang

Shega

2011

Psychotropic medication burden and factors associated with antipsychotic use: An analysis of a population-based sample of community-dwelling older persons with dementia

J Am Geriatr Soc 59 2100 2107

23.

Street

Clark

Kadam

Mitan

Juliar

Feldman

Breier

2001

Long-term efficacy of olanzapine in the control of psychotic and behavioral symptoms in nursing home patients with Alzheimer’s dementia

Int J Geriatr Psychiatry 16 S62 S70

24.

Suzuki

Inoue

Mikami

Gen

2014

The influence and changes in the dosages of concomitantly used psychotropic drugs associated with the discontinuation of donepezil in severe Alzheimer’s disease with behavioral and psychological symptoms on dementia: A preliminary open-label trial

Ther Adv Psychopharmacol 4 37 42

25.

Lopez

Wisniewski

Becker

Boller

DeKoshy

1999

Psychiatric medication and abnormal behavioras predictors of progression in probable Alzheimer disease

Arch Neurol 56 1266 1272

26.

Lasser

Sunderland

1998

Newer psychotropic medication use in nursing home residents

J Am Geriatr Soc 46 202 207

27.

Tolppanen

Taipale

Koponen

Lavikainen

Tanskanen

Tiihonen

Hartikainen

2013

Use of existing data sources in clinical epidemiology: Finnish health care registers in Alzheimer’s disease research–the Medication use among persons with Alzheimer’s disease (MEDALZ-2005) study

Clin Epidemiol 5 277 285

28.

Finnish Medical Society Duodecim

2010

The Finnish Medical Society Duodecim

Memory Disorders. Current Care Guideline [in Finnish with English summary] Helsinki

29.

American Psychiatric Association

1994 Diagnostic and Statistical Manual of Mental Disorders: DSM-IV American Psychiatric Association

Washington DC

30.

McKhann

Drachman

Folstein

1984

Clinical diagnosis of Alzheimer’s disease: Report of the NINCDS-ADRDA work group under the auspices of Department of Health and Human Services Task Force on Alzheimer’s disease

Neurology 34 939 944

31.

Solomon

Ngandu

Soininen

Hallikainen

Kivipelto

Laatikainen

2014

Validity of dementia and Alzheimer’s disease diagnoses in Finnish national registers

Alzheimers Dement 10 303 309

32.

WHO Collaborating Centre for Drug Statistics Methodology, ATC Structure and Principles, http://www.whocc.no/atc/structure_and_principles/, Last updated March 25, 2011, Accessed on May 22, 2015

33.

Furu

Wettermark

Andersen

Martikainen

Almarsdottir

Sørensen

2010

The Nordic countries as a cohort for pharmacoepidemiological research

Basic Clin Pharmacol Toxicol 106 86 94

34.

Rikala

Hartikainen

Sulkava

Korhonen

2010

Validity of the Finnish prescription register for measuring psychotropic drug exposures among elderly Finns: A population-based intervention study

Drugs Aging 27 337 349

35.

Tanskanen

Taipale

Koponen

Tolppanen

Hartikainen

Ahonen

Tiihonen

2014

From prescriptions to drug use periods - things to notice

BMC Res Notes 7 796

36.

Rikala

Hartikainen

Saastamoinen

Korhonen

2013

Measuring psychotropic drug exposures in register-based studies - validity of a dosage assumption of one unit per day in older Finns

Int J Methods Psychiatr Res 22 155 165

37.

Tanskanen

Taipale

Koponen

Tolppanen

Hartikainen

Ahonen

Tiihonen

2015

From prescription drug purchases to drug use periods–a second generation method (PRE2DUP)

BMC Med Inform Decis Mak 15 21

38.

Taipale

Tanskanen

Koponen

Tolppanen

Tiihonen

Hartikainen

2014

Antidementia drug use among community-dwelling individuals with Alzheimer’s disease in Finland: A nationwide register-based study

Int Clin Psychopharmacol 29 216 223

39.

Sund

2012

Quality of the Finnish Hospital Discharge Register: A systematic review

Scand J Public Health 40 505 515

40.

Defrancesco

Marksteiner

Fleischhacker

Blasko

2015

Use of benzodiazepines in Alzheimer’s disease: A systematic review of literature

Int J Neuropsychopharmacol 18 10

41.

Dell’Osso

Lader

2013

Do benzodiazepines still deserve a major role in the treatment of psychiatric disorders? A critical reappraisal

Eur Psychiatry 28 7 20

42.

Cumming

Le Couteur

2003

Benzodiazepines and risk of hip fractures in older people: A review of the evidence

CNS Drugs 17 825 837

43.

Halme

Beland

Preville

Tannenbaum

2013

Uncovering the source of new benzodiazepine prescriptions in community-dwelling older adults

Int J Geriatr Psychiatry 28 248 255

44.

Sampson

White

Leurent

Scott

Lord

Round

Jones

2014

Behavioural and psychiatric symptoms inpeople with dementia admitted to the acute hospital: Prospective cohort study

Br J Psychiatry 205 189 196

45.

Nurminen

Puustinen

Piirtola

Vahlberg

Kivela

2010

Psychotropic drugs and the risk of fractures in old age: A prospective population-based study

BMC Public Health 10 396

46.

Pierfitte

Macouillard

Thicoipe

Chaslerie

Pehourcq

Aissou

Martinez

Lagnaoui

Fourrier

Begaud

Dangoumau

Moore

2001

Benzodiazepines and hip fractures in elderly people: Case-control study

BMJ 322 704 708

47.

Allan

Ballard

Rowan

Kenny

2009

Incidence and prediction of falls in dementia: A prospective study in older people

PLoS One 4 e5521

48.

Tolppanen

Lavikainen

Soininen

Hartikainen

2013

Incident hip fractures among community dwelling persons with Alzheimer’s disease in a Finnish nationwide register-based cohort

PLoS One 8 e59124

49.

Spalletta

Musicco

Padovani

Perri

Fadda

Canonico

Trequattrini

Pettenati

Caltagirone

Palmer

2010

Neuropsychiatric symptoms and syndromes in a large cohort of newly diagnosed, untreated patients with Alzheimer disease

Am J Geriatr Psychiatry 18 1026 1035

50.

Sink

Holden

Yaffe

2005

Pharmacological treatment of neuropsychiatric symptoms of dementia: A review of the evidence

JAMA 293 596 608

51.

Wang

Meng

Wang

Tan

2015

Pharmacological treatment of neuropsychiatric symptoms in Alzheimer’s disease: A systematic review and meta-analysis

J Neurol Neurosurg Psychiatry 86 101 109

52.

Greenblatt

Shader

Divoll

Harmatz

1981

Benzodiazepines: A summary of pharmacokinetic properties

Br J Clin Pharmacol 11 11S 16S

53.

McCleery

2014

Cochrane Database of Systematic Reviews

Pharmacotherapies for sleep disturbances in Alzheimer’s disease John Wiley & Sons, Ltd