2020 年 5 巻 論文ID: 20200010
Objectives: Medications with anticholinergic or sedative effects induce impaired cognitive and physical performances. The aim of this study was to evaluate the associations of anticholinergic and sedative drug burden with recovery of physical function and activities of daily living in patients admitted to a Japanese rehabilitation hospital after cerebrovascular accidents. Methods: We retrospectively reviewed the medical records of patients aged 18 years or older who had undergone the inpatient rehabilitation program for cerebrovascular disease in Nerima Ken-ikukai Hospital. Patients who did not complete the rehabilitation program because of acute unexpected changes of physical or psychological condition or the need for surgical procedures were excluded. The primary outcome was recovery of activities of daily living as measured by the motor and cognitive subscores of the Functional Independence Measure. The secondary outcome was recovery of physical function as assessed by the 10-m walk test and the Berg balance scale. Multiple Cox proportional hazard regression analyses were conducted to calculate hazard ratios with 95% confidence intervals for the outcome measures. Results: Of 122 patients included in the study, 81 (66%) were exposed to anticholinergics and sedatives. Patients’ age, body mass index, and average daily drug burden during hospitalization were independently associated with achieving the cutoff Functional Independence Measure–motor subscore. Patients’ age and average daily drug burden during hospitalization were independently associated with achieving the Berg balance scale cut-off score. Conclusions: Our study of Japanese patients who were transferred from acute stroke care hospitals to a rehabilitation facility identified the drug burden of anticholinergics and sedatives as an independent factor associated with the time to recovery of activities of daily living and postural balance.
Medications with anticholinergic or sedative effects induce impaired cognitive and physical performances.1,2,3) A number of studies have found associations between medications and the risk of accidental falls in older patients.1,4) The use of benzodiazepine receptor agonists is associated with increased risk of dementia and impaired physical performance measures.5,6) Therefore, to minimize the risks of falls and fractures, the Beers criteria,7) the STOPP/START criteria,8) and the Japanese Guidelines for Medical Treatment and its Safety in the Elderly9) recommend reassessment of appropriate use of some medications that can induce confusion, sedation, and hypotension in elderly patients. Moreover, because the risk of falls is increased by initiation and dose escalation of benzodiazepines not only in the elderly but also in middle-aged inpatients,10) the middle-aged population shares the same risk of those medications as older persons. According to a meta-analysis,11) the use not only of benzodiazepines but also of sedative hypnotics, antipsychotics, and antidepressants increases the risk of falls.
Anticholinergic agents act on the muscarinic receptors in the central and peripheral nervous systems and inhibit acetylcholine-mediated responses by binding to these receptors. Typical and central side effects are dry mouth, nausea, vomiting, dizziness, weakness, and mental confusion.12) A previous study described an association between worse physical performance and cumulative exposure to anticholinergic medication.12) Medications with anticholinergic and sedative effects are often taken concurrently in clinical practice. According to a previous study,13) 30% of inpatients in a Japanese rehabilitation hospital were taking psychotropic agents, including concurrent administrations of anticholinergic agents such as medications for overactive bladder and sedative drugs such as benzodiazepine receptor agonists.
The drug burden index (DBI) is a pharmacological risk assessment tool that calculates exposure to both anticholinergic and sedative agents.14) The index is based on the principles of cumulative exposure and dose response. The DBI is the sum of scores for prescribed medications with anticholinergic and sedative effects for each patient. Previous studies have reported that increases in the DBI score are associated with significant functional impairment in older patients.15,16,17) Additionally, Hilmer et al.18) showed that both DBI and the cumulative exposure, calculated as the area under the curve for drug burden, were associated with lower objective physical function over 5 years in community-dwelling older people.
In Japan, convalescent rehabilitation wards, called Kaifuku-ki rehabilitation wards, were established by the national insurance system in 2000. Patients who are admitted to a convalescent rehabilitation ward can receive early and intensive rehabilitation. The purpose of convalescent-phase inpatient rehabilitation programs for patients who have had cerebrovascular accidents is to help them to recover physical functions and activities of daily living (ADL) and to re-establish an independent life. Currently, the maximum length of stay covered by medical insurance is 150 days for stroke and 180 days for stroke with other neurological diseases with severe disability and cognitive impairment. Discharge is considered when a patient reaches a plateau of ADL, as evaluated by outcome measures such as the Functional Independence Measure (FIM) comprising the FIM–motor subscore (FIM-M) and the FIM–cognitive subscore (FIM-C).19)
To the best of our knowledge, information is scarce on the association between medications with anticholinergic or sedative effects and the recovery of physical functions, including walking ability and ADL. Therefore, the influence of these drugs on rehabilitation outcomes is an unresolved issue in the field of rehabilitation. Consequently, the aim of this study was to evaluate the associations of the anticholinergic and sedative drug burden with the recovery of physical function and ADL after cerebrovascular diseases in a rehabilitation hospital in Japan.
The study design was that of a retrospective descriptive study. We reviewed the medical records of patients who were admitted to Nerima Ken-ikukai Hospital, a convalescent rehabilitation center with a convalescent ward, between May 2017 and March 2018. Eligible patients were 18 years of age or older and had undergone the rehabilitation program for cerebrovascular disease. We excluded those patients who did not complete the rehabilitation program in our facility for the following reasons: transfer to another hospital because of acute unexpected changes of physical or psychological condition or the need for surgical procedures (details are listed in Fig. 1), and difficulties of follow-up, for example, because the patient moved house. The following covariates were retrieved from medical charts: age, sex, type of cerebrovascular disease, height, body weight, length of stay, complications, the presence of higher brain dysfunction, and the time of onset of cerebrovascular disease. The study protocol was approved by the Ethics Committee of Nerima Ken-ikukai Hospital (approval number: Rin-1). The study was conducted in accordance with the Declaration of Helsinki.
STROBE flow chart of the study cohort.
Therapists consult with the attending physician who determines the frequency or duration of rehabilitation according to the patient’s background (e.g., age, physical condition, and comorbidities). The main rehabilitation programs were (1) range-of-motion exercises, standing balance training, transfer training, and walking training by physical therapists; (2) ADL training, upper limb rehabilitation, training for higher brain function, and mental practice for brain activation by occupational therapists; and (3) aphasia therapy, articulation therapy, dysphagia rehabilitation, and training for higher brain function by speech therapists. The standard rehabilitation program in our hospital includes three to six sessions per day of physical therapy, two to four sessions per day of occupational therapy, and zero to three sessions per day of speech therapy (a total of nine sessions per day); each session lasts 20 min.
OutcomesThe primary outcome was recovery of ADL from baseline (at admission), as measured by FIM-M and FIM-C. FIM is a composite scale consisting of 18 items that assess 6 areas of function: self-care, sphincter control, mobility, locomotion, communication, and social cognition. FIM can be subdivided into FIM-M and FIM-C, which assess the physical domain and cognitive domain, respectively. The scores ranged from 13 to 91 points for FIM-M and from 5 to 35 points for FIM-C. We preferred to analyze FIM-M and FIM-C to evaluate physical and cognitive function separately, rather than using the combined FIM score. We used FIM version 3.1.20) The secondary outcome was recovery of physical function from baseline measured by the 10-m walk test (10MWT) and the Berg balance scale (BBS). The 10MWT is widely used to assess gait speed because it is safe, simple to administer, and psychometrically well established. We applied a comfortable walking speed during the 10MWT.21,22) Physical therapists performed 10MWT twice and calculated the average time. The BBS provides a quantitative assessment of balance. This scale is composed of 14 items that require patients to maintain various physical positions and to complete movement tasks of varying degrees of difficulty.23) The maximum score is 56 points.
We evaluated the outcome measures (FIM-M, FIM-C, 10MWT, and BBS) at admission; on hospital days 30, 60, and 90; and at discharge. We calculated the time to achieve the cut-off point for recovery for each outcome measure. Based on previous studies, the definition of “recovery” was set by discussions among medical doctors, physical therapists, occupational therapists, and pharmacists.24,25,26) We used the following cut-off values to define “recovery” of ADL and physical function: (1) 58 points for FIM-M, (2) 24 points for FIM-C, (3) 25 s for 10MWT, and (4) 45 points for BBS. According to a previous study,24) the cut-off values of 58 and 24 points for FIM-M and FIM-C, respectively, are the borderline ADL measures for home discharge of post-stroke patients. The cut-off score of 25 s for 10MWT is reportedly the cut-off value for a least-limited community walker who can independently negotiate both local stores and uncrowded shopping centers.25) The cut-off score of 45 points for BBS has been reported as the cut-off value between individuals who are safe to ambulate independently and those who require assessment concerning their need for assistive devices or supervision.26)
Medication ExposureWe hypothesized that anticholinergic and sedative drugs are potential risk factors that delay the recovery of ADL and physical functions. Medications with anticholinergic or sedative effects included in this study were antidepressants, antipsychotics, antihistamines, dopaminergics, opioid receptor agonists, hypnotics (including benzodiazepine receptor agonists), anticonvulsants, muscarinic antagonists for overactive bladder, codeine, disopyramide, furosemide, isosorbide, loperamide, nifedipine, theophylline, and warfarin. Medications with anticholinergic effects were identified according to the anticholinergic rank scale,27) the anticholinergic cognitive burden scale,28) and the anticholinergic drug scale.29) Exposure to anticholinergic and sedative medications was quantified using total drug burden (TDB). TDB depends not only on the number of prescribed drugs but also on the daily dosage. TDB was calculated for each patient according to the following equation14):
TDB=DBIAC + DBIS
where DBIAC and DBIS represent the standardized drug burden from anticholinergic and sedative drugs, respectively. DBI was calculated using the following equation:
where Dactual is the daily dose taken by the patient and Dminimum is the recommended minimum daily dose approved by Ministry of Health, Labour and Welfare. If a patient was administered the minimum approved daily dose of a certain drug, the DBI of the drug would be 0.5. Topical medications without significant systemic effects (e.g., ointments and eye drops) were excluded from analysis. However, we included isosorbide tape because, although it is topical, it is expected to produce systemic effects.
TDB was calculated at admission, every 30 days thereafter, and at discharge. Cumulative exposure of the drugs of interest over the entire period of hospitalization (AUCDB) was calculated as the area under the curve for TDB by applying the trapezoidal rule18) because patients who are admitted to rehabilitation hospitals in Japan are in the subacute stage and their prescriptions are modified according to their medical conditions. For example, we would calculate AUCDB for a patient whose length of stay was 50 days as:
We also calculated the average daily drug burden during hospitalization for each patient because longer hospital stays usually result in a greater AUCDB. The average daily drug burden was calculated using the following equation:
Patients were classified into three groups according to the calculated average daily drug burden as follows: (1) no drug burden throughout the hospital stay (zero drug burden group), (2) average daily drug burden between 0.01 and 0.49 (low drug burden group), and (3) average daily drug burden >0.49 (high burden group). We allocated patients who took medications with anticholinergic or sedative effects during hospitalization into two groups. The cut-off value of 0.49 was the median value for all patients, excluding patients in the zero drug burden group.
Statistical AnalysisData are presented as medians with first and third quartiles. The Kruskal-Wallis test and the chi-squared test were used to compare numerical and categorical data, respectively, among groups (zero, low, and high drug burden groups). Univariate and multiple Cox proportional hazard regression analyses were conducted to calculate hazard ratios (HR) and 95% confidence intervals (CI) for achievement of the cut-off values of the outcome measures. In this study, higher HR values mean an association with longer times to achieve the cut-off value of outcome measures. We incorporated age, sex, body mass index (BMI), the presence of higher brain dysfunction, and the average daily drug burden as covariates into the multiple Cox proportional hazard regression analysis. In addition to the variables specified above, other variables with P values below 0.10 in the univariate analyses were also included as potential covariates in the multivariate analysis. We examined the existence of multicollinearity between factors using Pearson’s or Spearman’s rank-correlation coefficients. When there was significant multicollinearity between variables, we selected one of them based on its clinical relevance. We performed subgroup analyses by stratifying age (≤64, 65–80, ≥81 years) and BMI (≤18.4, 18.5–24.9, ≥25) to evaluate the interactions of these factors with the outcome measures. Statistical significance was defined by a two-sided alpha level of 0.05. A sample size calculation for the Cox proportional hazard regression model with nonbinary covariates30) with alpha and beta errors of 0.05 and 0.2, respectively, indicated that a total of 80 patients who achieved the primary outcome were required to detect a daily drug burden with a HR of 0.95 per 0.1 increase in the daily drug burden. All statistical analyses were performed using Stata 15 (College Station, TX, USA).
In total, 122 patients were included in the analysis (Fig. 1). The clinical characteristics of the study population are shown in Table 1. Eighty-one patients (59%) took medications that contributed to the drug burden during hospitalization. Benzodiazepine receptor agonists were the most frequently prescribed class contributing to the drug burden in this population [total: 43 patients (35%); low drug burden group: 15 patients (33%), high drug burden group: 28 patients (80%)]. The median time from the onset of cerebrovascular disease to admission was 37 days (zero drug burden group: 35 days, low drug burden group: 37 days, high drug burden group: 41 days). The values of the outcome measures at admission and discharge are shown in Table 2. The median TDB increased during hospitalization from 0.00 to 0.50 in the low drug burden group and from 0.50 to 1.00 in the high drug burden group (Table 3). The frequencies of anticholinergic and sedative medications used in this study population are shown in Table 4. The number of patients administered antipsychotics, benzodiazepine receptor agonists, anticonvulsants, and others (furosemide, isosorbide, loperamide, nifedipine, theophylline, and warfarin) were higher in the high drug burden group than in the low drug burden group.
| Overall (n=122) |
Zero DB (n=41) |
Average daily drug burden ≥0.01* | P-value** | ||
| Low DB (n=46) |
High DB (n=35) |
||||
| Age, years | 76 [56, 83] | 73 [54, 82] | 75 [61, 82] | 79 [57, 83] | 0.962 |
| ≤64, n (%) | 39 (32) | 14 (34) | 14 (30) | 11 (31) | 0.931 |
| 65–80, n (%) | 39 (32) | 13 (32) | 16 (35) | 10 (29) | 0.838 |
| ≥81, n (%) | 44 (36) | 14 (34) | 16 (35) | 14 (40) | 0.846 |
| Female, n (%) | 48 (39) | 12 (29) | 19 (41) | 17 (49) | 0.216 |
| Height, cm | 161 [153, 167] | 163 [155,170] | 160 [153, 166] | 161 [154, 166] | 0.421 |
| Body weight, kg | 54 [49, 62] | 56 [50, 67] | 53 [48, 58] | 53 [46, 58] | 0.102 |
| BMI, kg/m2 | 20.8 [19.2, 23.2] | 21.3 [19.3, 22.4] | 20.7 [19.3, 22.4] | 20.6 [18.5, 23.0] | 0.128 |
| BMI <18.5, n (%) | 22 (18) | 4 (10) | 9 (20) | 9 (26) | 0.185 |
| 18.5≤ BMI ≤24.9, n (%) | 85 (70) | 28 (68) | 32 (70) | 25 (71) | 0.957 |
| BMI ≥25, n (%) | 15 (12) | 9 (22) | 5 (11) | 1 (3) | 0.038 |
| Higher brain dysfunction, n (%) | 85 (70) | 26 (63) | 33 (72) | 26 (74) | 0.547 |
| Time from onset of cerebrovascular accident to admission, days | 37 [28, 45] | 35 [27, 42] | 37 [29, 46] | 41 [28, 54] | 0.145 |
| Type of cerebrovascular disease | |||||
| Cerebral infarction, n (%) | 53 (43) | 18 (44) | 20 (43) | 15 (43) | 0.996 |
| Intracerebral hemorrhage, n (%) | 24 (20) | 11 (27) | 7 (15) | 6 (17) | 0.359 |
| Subarachnoid hemorrhage, n (%) | 11 (9) | 2 (5) | 7 (15) | 2 (6) | 0.176 |
| Others***, n (%) | 34 (28) | 10 (24) | 12 (26) | 12 (34) | 0.596 |
| Atrial fibrillation, n (%) | 20 (16) | 4 (10) | 8 (17) | 8 (23) | 0.298 |
| Coronary heart disease, n (%) | 19 (16) | 5 (12) | 10 (22) | 4 (11) | 0.342 |
| Dementia, n (%) | 10 (8) | 3 (7) | 4 (9) | 3 (9) | 0.969 |
| Diabetes mellitus, n (%) | 20 (16) | 7 (17) | 8 (17) | 5 (14) | 0.923 |
| Epilepsy, n (%) | 9 (7) | 0 (0) | 2 (4) | 7 (20) | 0.002 |
| Heart failure, n (%) | 8 (7) | 3 (7) | 2 (4) | 3 (9) | 0.727 |
| Hypertension, n (%) | 81 (66) | 28 (68) | 33 (72) | 20 (57) | 0.368 |
| Parkinson’s disease, n (%) | 3 (2) | 1 (2) | 1 (2) | 1 (3) | 0.981 |
Data are presented as median [first quartile, third quartile] or number (percent).
* Low DB: average daily drug burden 0.01–0.49, High DB: average daily drug burden >0.49.
** Kruskal-Wallis test or chi-squared test, comparing three groups.
*** Head trauma, traumatic subarachnoid hemorrhage, and brain tumor.
BMI, body mass index; DB, drug burden.
| Outcome measure | Overall (n=122) |
Zero DB (n=41) |
Average daily drug burden ≥0.01* | P-value** | |
| Low DB (n=46) | High DB (n=35) | ||||
| 10MWT, s | |||||
| Admission | 12.0 [8.5, 18.6] | 10.3 [8.0, 18.1] | 11.9 [9.6, 17.5] | 14.4 [10.5, 23.9] | 0.282 |
| Discharge | 10.3 [7.4, 17.6] | 8.8 [6.7, 16.4] | 10.9 [8.5, 14.7] | 10.5 [7.5, 27.6] | 0.170 |
| BBS, points | |||||
| Admission | 30 [4, 48] | 39 [7, 51] | 31 [3, 44] | 12 [3, 40] | 0.048 |
| Discharge | 48 [23, 54] | 53 [44, 55] | 47 [25, 53] | 41 [15, 53] | 0.015 |
| FIM-M, points | |||||
| Admission | 47 [23, 65] | 53 [29, 70] | 48 [23, 65] | 31 [22, 52] | 0.031 |
| Discharge | 83 [57, 90] | 87 [76, 90] | 82 [55, 90] | 77 [41, 87] | 0.039 |
| FIM-C, points | |||||
| Admission | 22 [12, 28] | 23 [18, 30] | 23 [10, 29] | 18 [9, 23] | 0.034 |
| Discharge | 29 [18, 35] | 31 [26, 35] | 30 [13, 35] | 27 [16, 34] | 0.159 |
Data are presented as median [first quartile, third quartile].
* Low DB: average daily drug burden 0.01–0.49, High DB: average daily drug burden >0.49.
** Kruskal-Wallis test, comparing three groups.
| Overall (n=122) |
Zero DB (n=41) |
Average daily drug burden ≥0.01* | P-value** | ||
| Low DB (n=46) | High DB (n=35) | ||||
| Anticholinergic and sedative drugs, n/a patient | 1 [0, 2] | 0 | 1 [1, 1] | 3 [2, 4] | <0.001 |
| TDB at admission | 0.00 [0.00, 0.50] | 0 | 0.00 [0.00, 0.50] | 0.50 [0.41, 0.92] | <0.001 |
| TDB at 30 days | 0.20 [0.00, 0.50] | 0 | 0.33 [0.00, 0.50] | 0.83 [0.50, 1.50] | <0.001 |
| TDB at 60 days | 0.50 [0.00, 0.70] | 0 | 0.50 [0.24, 0.50] | 1.00 [0.68, 1.38] | <0.001 |
| TDB at 90 days | 0.42 [0.00, 1.00] | 0 | 0.33 [0.15, 0.50] | 1.00 [0.67, 1.55] | <0.001 |
| TDB at discharge | 0.38 [0.00, 0.67] | 0 | 0.50 [0.27, 0.50] | 1.00 [0.67, 1.58] | <0.001 |
| AUCDB | 17.50 [0.00, 53.08] | 0 | 19.72 [9.33, 36.25] | 91.83 [52.83, 145.01] | <0.001 |
| Average daily drug burden | 0.32 [0.00, 0.57] | 0 | 0.33 [0.24, 0.46] | 0.77 [0.66, 1.39] | <0.001 |
| Length of stay, days | 87 [49, 125] | 77 [45, 112] | 84 [49, 108] | 107 [63, 146] | 0.172 |
Data are presented as median [first quartile, third quartile].
* Low DB: average daily drug burden 0.01–0.49, High DB: average daily drug burden >0.49.
** Kruskal-Wallis test, comparing three groups.
| Drug class* | Overall (n=122) |
Zero DB (n=41) |
Average daily drug burden ≥0.01** | P-value*** | |
| Low DB (n=46) |
High DB (n=35) |
||||
| Antidepressants, n (%) | 15 (12) | 0 (0) | 6 (13) | 9 (26) | 0.146 |
| Antipsychotics, n (%) | 20 (16) | 0 (0) | 5 (11) | 15 (43) | 0.001 |
| Antihistamines, n (%) | 15 (12) | 0 (0) | 9 (20) | 6 (17) | 0.781 |
| Dopaminergic, n (%) | 9 (7) | 0 (0) | 4 (9) | 5 (14) | 0.663 |
| Opioid receptor agonists, n (%) | 2 (2) | 0 (0) | 0 (0) | 2 (6) | - |
| Benzodiazepine receptor agonists, n (%) | 46 (38) | 0 (0) | 15 (33) | 28 (80) | <0.001 |
| Suvorexant or ramelteon, n (%) | 8 (7) | 0 (0) | 3 (7) | 5 (14) | 0.246 |
| Anticonvulsants, n (%) | 26 (21) | 0 (0) | 6 (13) | 20 (57) | <0.001 |
| Muscarinic antagonists for bladder, n (%) | 11 (9) | 0 (0) | 6 (13) | 5 (14) | 0.872 |
| Others****, n (%) | 18 (15) | 0 (0) | 5 (11) | 13 (37) | 0.012 |
*Patients who took the drug at least once during hospitalization were counted, even if the drug was discontinued before discharge.
** Low DB: average daily drug burden 0.01–0.49, High DB: average daily drug burden >0.49.
***Chi-squared test (Low DB vs High DB).
****Furosemide, isosorbide, loperamide, nifedipine, theophylline, and warfarin.
Table 5 shows the results of multiple Cox proportional hazard regression analysis for primary outcomes. Age [HR 0.985 (95% CI 0.972–0.999), P=0.033], BMI [HR 1.066 (1.011–1.133), P=0.045], and the average daily drug burden [HR 0.935 (0.889–0.983), P=0.008] were independent variables associated with the time to achieve the FIM-M cut-off value. Thirty-five patients (85%) in the zero drug burden group, 33 patients (72%) in the low drug burden group, and 21 patients (60%) in the high drug burden group achieved the FIM-M cut-off score (58 points) during hospitalization.
| Outcome variables |
Univariate | Multivariate | ||
| HR (95% CI) | P-value | Adjusted HR (95% CI) | P-value | |
| Time to achieve FIM-M cutoff | ||||
| Age, per year | 0.988 (0.977, 0.999) | 0.039 | 0.985 (0.972, 0.999) | 0.033 |
| Female | 0.761 (0.493, 1.176) | 0.219 | 0.851 (0.540, 1.342) | 0.487 |
| BMI, per kg/m2 | 1.074 (1.005, 1.148) | 0.036 | 1.066 (1.011, 1.133) | 0.045 |
| Presence of higher brain dysfunction | 0.680 (0.437, 1.059) | 0.088 | 0.724 (0.457, 1.148) | 0.170 |
| Average daily drug burden, per 0.1 | 0.948 (0.904, 0.995) | 0.030 | 0.935 (0.889, 0.983) | 0.008 |
| Presence of cerebral infarction | 0.608 (0.394, 0.938) | 0.024 | 0.913 (0.524, 1.592) | 0.749 |
| Presence of other cerebrovascular disease* | 1.756 (1.124, 2.742) | 0.013 | 1.665 (0.958, 2.893) | 0.071 |
| Time to achieve FIM-C cutoff | ||||
| Age, per year | 0.989 (0.977, 1.001) | 0.080 | 0.988 (0.975, 1.002) | 0.085 |
| Female | 0.968 (0.626, 1.496) | 0.884 | 1.061 (0.677, 1.664) | 0.796 |
| BMI, per kg/m2 | 1.082 (1.017, 1.150) | 0.012 | 1.073 (1.011, 1.138) | 0.020 |
| Presence of higher brain dysfunction | 0.636 (0.405, 0.997) | 0.048 | 0.729 (0.452, 1.177) | 0.196 |
| Average daily drug burden, per 0.1 | 0.964 (0.919, 1.011) | 0.127 | 0.962 (0.917, 1.009) | 0.115 |
| Presence of other cerebrovascular disease* | 1.486 (0.937, 2.358) | 0.093 | 1.327 (0.820, 2.147) | 0.250 |
| Presence of hypertension | 0.683 (0.440, 1.058) | 0.088 | 0.799 (0.504, 1.267) | 0.341 |
* Head trauma, traumatic subarachnoid hemorrhage, brain tumor.
CI, confidence interval; HR, hazard ratio
Multiple Cox proportional hazard regression analysis also indicated that BMI [HR 1.073 (1.011–1.138), P=0.020] was an independent variable associated with the time to achieve the FIM-C cut-off value (Table 5). Thirty-four patients (83%) in the zero drug burden group, 32 patients (70%) in the low drug burden group, and 20 patients (57%) in the high drug burden group achieved the FIM-C cut-off score (24 points) during hospitalization.
Ten-meter Walk TestTwenty-one patients were unable to undergo or complete the 10MWT during hospitalization because of impaired walking ability, difficulty with understanding, or orthostatic hypertension. Thirty-six patients (88%) in the zero drug burden group, 32 patients (70%) in the low drug burden group, and 18 patients (51%) in the high drug burden group achieved the 10MWT cut-off time (25 s) during hospitalization. Table 6 shows the results of multiple Cox proportional hazard regression analysis.
| Outcome variables |
Univariate | Multivariate | ||
| HR (95% CI) | P-value | Adjusted HR (95% CI) | P-value | |
| Time to achieve 10MWT cutoff | ||||
| Age, per year | 0.998 (0.986, 1.011) | 0.815 | 0.996 (0.982, 1.010) | 0.591 |
| Female | 0.971 (0.623, 1.512) | 0.895 | 1.013 (0.663, 1.621) | 0.958 |
| BMI, per kg/m2 | 1.022 (0.960, 1.088) | 0.501 | 1.017 (0.953, 1.084) | 0.617 |
| Presence of higher brain dysfunction | 0.723 (0.461, 1.134) | 0.157 | 0.757 (0.477, 1.203) | 0.239 |
| Average daily drug burden, per 0.1 | 0.965 (0.921, 1.011) | 0.138 | 0.967 (0.922, 1.016) | 0.181 |
| Time to achieve BBS cutoff | ||||
| Age, per year | 0.987 (0.975, 0.999) | 0.042 | 0.980 (0.966, 0.994) | 0.005 |
| Female | 0.839 (0.519, 1.357) | 0.475 | 0.945 (0.570, 1.565) | 0.825 |
| BMI, per kg/m2 | 1.059 (0.986, 1.138) | 0.117 | 1.049 (0.978, 1.124) | 0.179 |
| Presence of higher brain dysfunction | 0.693 (0.425, 1.130) | 0.142 | 0.694 (0.418, 1.154) | 0.159 |
| Average daily drug burden, per 0.1 | 0.931 (0.877, 0.987) | 0.017 | 0.924 (0.872, 0.979) | 0.008 |
Table 6 shows the results of multiple Cox proportional hazard regression analysis. Age [HR 0.980 (0.966–0.994), P=0.005] and the average daily drug burden [HR 0.924 (0.872–0.979), P=0.008] were independent variables associated with the time to achieve the BBS cut-off value (Table 6). One patient did not undergo BBS measurement because of being discharged within 30 days (i.e., before the first measurement after admission). Thirty-one patients (76%) in the zero drug burden group, 25 patients (54%) in the low drug burden group, and 15 patients (43%) in the high drug burden group achieved the BBS cut-off score (45 points) during hospitalization.
Subgroup AnalysesSubgroup analyses showed that the associations of independent variables (age, BMI, and average daily drug burden) with outcome measures (FIM-M, FIM-C, and BBS) were consistent across different age groups and BMI groups (Fig. 2).
Subgroup analyses of outcomes by stratifying patients’ (A) age and (B) body mass index. BBS, Berg balance scale; BMI, body mass index; CI; confidence interval; FIM-C, Functional Independence Measure‒cognitive subscore; FIM-M, Functional Independence Measure‒motor subscore.
We demonstrated that a higher average daily drug burden was associated with delayed recovery of BBS and FIM-M in patients admitted to a rehabilitation hospital after cerebrovascular accidents. Patients in the convalescent ward are regularly monitored (usually monthly) for FIM-M and FIM-C to assess ADL in clinical practice. Our study revealed that, in addition to age and BMI, the average daily drug burden was independently associated with the time to achieve the FIM-M cut-off value. Higher DBI values were reportedly associated with ADL disability after 3-year follow-up in Japanese elderly persons aged 85 years or older.31) Although our study population did not exclusively consist of elderly patients and the follow-up duration was less than 1 year, our results showed the same tendency as that identified in the previous report.31) However, it remains unclear which items in FIM-M are most influenced by the average daily drug burden, age, and BMI, because we did not retrieve those details in this study. Our results also indicated that higher BMI was associated with faster improvement in FIM-M and FIM-C. Previous studies have reported that sarcopenia weakened physical function,32) whereas obesity had a negative effect on the recovery of physical function.33) There was only one patient with a BMI greater than 30 kg/m2 in this study. Therefore, in our study population, we speculated that BMI was an indicator of nutritional status, not obesity.
Several recent long-term studies have addressed the association between the use of anticholinergic or sedative drugs and cognitive impairment.2,34,35) However, we found no significant association between the average daily drug burden and FIM-C in patients of our convalescent ward. Patients transferred from acute stroke care facilities to convalescent hospitals are in the sub-acute stage of cerebrovascular accidents, and their higher brain function is in the process of recovery. Because early treatment with selective serotonin reuptake inhibitors could be beneficial for the recovery of FIM in patients with post-stroke depression,36,37) the effectiveness of anticholinergic and sedative drugs might outweigh the risk of any negative effects on cognitive function during this period.
The 10MWT and BBS are often used to assess gait speed and balance, respectively. We found that, in addition to age, the average daily drug burden is independently associated with the time to achieve the BBS cut-off score. Anticholinergic drugs and sedative drugs are widely prescribed. Previous studies have suggested that the use of these medications induces impairment of physical functions such as gait speed and balance in older patients.17,38) The relationship between physical function and the drug burden of anticholinergics and sedatives observed in our study was consistent with these previous reports (Fig. 2), suggesting that there may be an interaction between drug burden and age groups. Further large-scale studies are required to clarify this interaction.
Factors affecting the average daily drug burden include the number of DBI-contributing medications prescribed and the daily doses. We also examined whether the daily dose was an important factor. Of the 41 patients who took one DBI-contributing drug during hospitalization, 35 patients belonged to the low drug burden group and 6 patients belonged to the high drug burden group. The most frequently prescribed DBI-contributing drugs were levetiracetam (eight patients: five in the low drug burden group and three in the high drug burden group), brotizolam (four patients: all in the low drug burden group), and zolpidem (four patients: all in the low drug burden group). Regarding levetiracetam, the daily dose was 500 or 1000 mg/day (1000 mg is the minimum daily dose approved by Ministry of Health, Labour and Welfare) in the low drug burden group and 2000 mg/day in the high drug burden group. Additionally, the administration period may also influence the average drug burden. Brotizolam and zolpidem were used short-term in all patients prescribed these drugs. Only one patient in the high drug burden group was prescribed lorazepam throughout hospitalization, although at the minimum daily dose. Although the sample size was small, our results suggest the possibility that the dose may influence the time to achieve the cut-off values of outcome measures.
We found that patient prescriptions were changed during hospitalization (Table 3), suggesting the possibility that the post-cerebrovascular disease conditions (such as post-stroke depression, apathy, or dysuria) changed over time because patients in the Japanese convalescent ward were in the subacute stage. Interestingly, benzodiazepine receptor agonists were more frequently prescribed in the high drug burden group than in the low drug burden group. Zolpidem and brotizolam for insomnia were frequently prescribed in our study population. Guidelines for geriatrics7,8,9) recommend that these medications should be avoided in elderly patients because of the risks of confusion, sedation, and falls. We propose that both the daily dose and the duration of treatment should be considered carefully so as not to delay the recovery of ADL as measured by FIM-M and balance ability as measured by BBS. Healthcare providers need to share patients’ information and pay attention to the doses of anticholinergic agents and sedative drugs as well as the number of these drugs being used in rehabilitation hospitals.
There are some limitations to our study. First, we did not retrieve data on the severity of cerebrovascular disease or the type of higher brain dysfunction. According to pervious research,39) hemispatial neglect, apathy, and right hemisphere brain damage influence the effectiveness of rehabilitation. It was difficult to investigate separately the contributions of symptom severity and high drug burden to the recovery of ADL. However, at least, the attending physician-determined median session times of the rehabilitation routine, which might be adjusted according to disease severity, were comparable irrespective of the three drug burden groups (i.e., zero, low, and high drug burden groups), i.e., four sessions for physical therapy, three sessions for occupational therapy, and two sessions for speech therapy. In our study population, the average number of rehabilitation sessions was 8.3 sessions per day. Second, we could not evaluate the impact of drug burden on the recovery of walking ability in severely impaired patients who were unable to undergo or complete a 10MWT during hospitalization. Third, we studied the effect of anticholinergic and sedative drugs together and did not analyze their effects separately. Fourth, the study was retrospective. Finally, the sample size was limited because the Nerima Ken-ikukai Hospital was established in April 2017. Further prospective research with a larger sample size is needed to confirm whether drug burden with anticholinergic and sedative agents influences the recovery of ADL or physical function.
Our descriptive study conducted in a rehabilitation hospital revealed that, in addition to age, the average daily drug burden of anticholinergics/sedatives was independently associated with the time to recovery of FIM-M and BBS. Therefore, both the daily dose and dosing duration of anticholinergic/sedative drugs should be considered carefully to avoid delaying the recovery of ADL and balance ability.
We would like to thank Teresa Nakatani for English language editing. We would also like to thank Kenji Ito, Yuta Sato, and Soji Tanaka for advice on the outcome measures.
The authors declare no conflicts of interest.
