Affiliations
Division of General Medicine and Geriatrics, Department of Medicine, Baystate Medical Center, Springfield, Massachusetts
Tufts University School of Medicine, Boston, Massachusetts
Given name(s)
Beatriz
Family name
Korc‐Grodzicki
Degrees
MD, PhD

Inappropriate Hospital Prescribing

Article Type
Changed
Sun, 05/28/2017 - 22:19
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Potentially inappropriate medication use in hospitalized elders

Medications can be considered inappropriate when their risk outweighs their benefit. The Beers list1 identifies medications that should be avoided in persons 65 years or older because they are ineffective or pose an unnecessarily high risk or because a safer alternative is available. Initially developed in 1991, the list has gained wide acceptance and has been updated twice.2, 3 In July 1999 it was adopted by the Centers for Medicare & Medicaid Services (CMS) for nursing home regulation, and in 2006 the National Committee on Quality Assurance adopted a modified version as a Health Plan Employer Data and Information Set (HEDIS) measure of quality of care for older Americans.4

A number of studies have demonstrated that inappropriate prescribing is common in the ambulatory setting,57 in nursing homes,8, 9 and in emergency departments10, 11 and that exposure to inappropriate medications is associated with increased risk of adverse drug reactions12 and hospitalization.13, 14 Initial studies of hospitalized patients1517 suggest that potentially inappropriate prescribing is also common among elderly inpatients and that reducing the misuse of psychotropic medications can prevent falls.18 We report on the incidence of and risk factors associated with potentially inappropriate prescribing in a large sample of hospitalized elders.

METHODS

Patients

We conducted a retrospective cohort study using data from 384 hospitals participating in Perspective (Premier, Inc., Charlotte, NC), a database developed for measuring quality and health care utilization. Participating hospitals represent all regions of the United States and are primarily small‐ to medium‐sized nonteaching hospitals most of which are in urban areas. Premier collects data elements from participating hospitals via a custom data extract from hospitals' decision support system. Hospitals aggregate the data elements into their decision support systems from multiple information technology systems including billing, medical records, pharmacy, and laboratory systems. In addition to the information contained in the standard hospital discharge file, Perspective includes a date‐stamped log of all billed items, including medications with dose and quantity, for individual patients.

We included patients at least 65 years old admitted between September 1, 2002, and June 30, 2005, with a principal diagnosis of acute myocardial infarction, chronic obstructive pulmonary disease, chest pain, community‐acquired pneumonia, congestive heart failure, ischemic stroke, or urinary tract infection. International Classification of Diseases, Ninth Revision (ICD‐9‐CM) codes were used to identify diagnoses. Patients cared for by an attending physician with a surgical specialty were excluded. The study protocol was approved by the institutional review board of Baystate Medical Center.

Data Elements

For each patient, Perspective contains fields for age, sex, race, marital status, insurance status, principal diagnosis, comorbidities, and specialty of the attending physician. Comorbidities were identified from ICD‐9‐CM secondary diagnosis codes and APR‐DRGs using Healthcare Cost and Utilization Project Comorbidity Software, version 3.1, based on the work of Elixhauser.19 Because almost all patients had Medicare coverage, plans were classified according to managed care status. Finally, for each patient we identified all medications administered, as well as discharge status, readmission rate, total costs, and length of stay. Hospitals were categorized by region (Northeast, South, Midwest, or West), bed size, setting (urban or rural), teaching status, and whether there were geriatricians.

Potentially Inappropriate Prescribing

Using the 2002 updated Beers criteria3 for potentially inappropriate medication (PIM) use in older adults, we identified the total number of PIMs administered to each patient during his or her hospital stay. We classified each PIM as either high or low severity based on the expert consensus expressed in the 1997 update of the Beers criteria.2 The list contains 48 PIMs and an additional 20 that should be avoided in patients with certain conditions. We did not include the second category of PIMs because we did not necessarily have sufficient patient information to make this determination. In addition, some of the standard PIMs, such as laxatives, although inappropriate for chronic outpatient use, could be appropriate in the hospital setting and were excluded from this analysis. Finally, several medications were considered inappropriate only above a given threshold (eg, lorazepam >3.0 mg/day) or for patients without a specific diagnosis (eg, digoxin >0.125 mg/day for patients without atrial fibrillation). We grouped PIMs that had similar side effects into 4 categories: sedatives, anticholinergics, causing orthostasis, or causing bleeding (Fig. 1).

Figure 1
Beers list of potentially inappropriate medications modified for hospitalized patients >65 years old.

Statistical Analysis

Summary statistics at the patient, physician, and hospital levels were constructed using frequencies and proportions for categorical data and means, standard deviations, medians, interquartile ranges, and box plots for continuous‐scale variables. Patients were identified as receiving a PIM if the drug was administered (above threshold dose where applicable) on at least 1 hospital day. We examined the association of each patient characteristic with use of any PIM, any high‐severity‐rated PIM, and each side effect category using chi‐square statistics. Kruskal‐Wallis analysis of variance was used to examine variation in hospital use rates by each hospital characteristic, and physician use rates for high‐severity PIMs by attending specialty. To examine whether it was feasible to avoid PIMs altogether, we compared individual hospitals as well as individual prescribers within their specialty, limiting the comparison to hospitals that contributed at least 100 patients and to physicians with at least 50 patients.

We developed a multivariable model for any high‐severity medication (HS‐PIM) use that included all patient, physician, and hospital characteristics except length of stay, mortality, cost, discharge status, and readmission rate. A generalized estimating equation model (SAS PROC GENMOD) with a logit link and a subcluster correlation structure was used to account for clustering at the hospital, physician, and diagnosis levels, adjusting for the clustering of primary diagnosis within physician level, nested within hospital level. Effects with P < .10 were retained in the model, and interaction effects were also evaluated for significance. Model fit was assessed using deviance and Pearson chi‐square statistics. All analyses were performed with SAS statistical software, version 9.1 (SAS Institute, Cary, NC).

RESULTS

We identified 519,853 patients at least 65 years old during the study period; 564 were excluded because of missing data for key variables or unclear principal diagnosis. An additional 25,318 were excluded because they were cared for by an attending with a surgical specialty. A total of 493,971 patients were included in the study (Table 1). Mean age was 78 years, and 24% of patients were 85 years or older. Forty‐three percent were male, 71% were white, and 39% were currently married. The most common principal diagnoses were community‐acquired pneumonia, congestive heart failure, and acute myocardial infarction. The most common comorbidities were hypertension, diabetes, and chronic pulmonary disease. Medicare was the primary payer for 91% of subjects, and 13% were in managed care plans. Most patients were cared for by internists (49%), family practitioners (18%), or cardiologists (17%). Only 1% of patients had a geriatrician as attending.

Characteristics of 493,971 Older Patients Hospitalized with 1 of 7 Common Medical Conditions
Characteristicn (%)
  • Other physician category includes 42 specialties.

Age group 
6574 years168,527 (34%)
7584 years206,407 (42%)
85+ years119,037 (24%)
Sex 
Male212,358 (43%)
Female281,613 (57%)
Race 
White351,331 (71%)
Black52,429 (11%)
Hispanic18,057 (4%)
American Indian1876 (0%)
Asian/Pacific Islander5926 (1%)
Other64,352 (13%)
Marital status 
Married/partner194,496 (39%)
Widowed155,273 (31%)
Single/separated/divorced75,964 (15%)
Other68,238 (14%)
Primary diagnosis 
Pneumonia122,732 (25%)
Heart failure109,071 (22%)
Acute MI70,581 (14%)
Ischemic stroke57,204 (12%)
Chest pain50,404 (10%)
COPD44,582 (9%)
Urinary tract infection39,397 (8%)
Comorbidities 
Hypertension310,163 (63%)
Diabetes151,755 (31%)
Chronic pulmonary disease134,900 (27%)
Fluid and electrolyte disorders128,703 (26%)
Deficiency anemias92,668 (19%)
Congestive heart failure69,201 (14%)
Hypothyroidism68,711 (14%)
Peripheral vascular disease47,244 (10%)
Depression41,507 (8%)
Other neurological disorders40,200 (8%)
Renal failure38,134 (8%)
Obesity25,143 (5%)
Payer type 
Not Managed care431,583 (87%)
Managed care62,388 (13%)
Attending physician specialty 
Internal medicine (internist)241,982 (49%)
Family/general medicine90,827 (18%)
Cardiology83,317 (17%)
Pulmonology21,163 (4%)
Hospitalist14,924 (3%)
Nephrology8257 (2%)
Neurology5800 (1%)
Geriatrics3099 (1%)
Other*24,602 (5%)
 
Mortality 
Expired28,321 (6%)
Alive465,650 (94%)
Discharge status, n (% of survivors) 
Home323,629 (66%)
Nursing care119,468 (24%)
Transfer/short‐term hospital13,531 (3%)
Hospice9022 (2%)
14‐Day readmission, n (% of survivors) 
Yes35,309 (8%)
No430,334 (92%)
Length of stay (days), median (IQR)4 (2, 7)
Total cost (dollars)$5513 ($3366, $9902)

Just under half of all patients (49%) received at least 1 PIM, and 6% received 3 or more (Table 2). Thirty‐eight percent received at least 1 drug with a high severity rating (HS‐PIM). The most common PIMs were promethazine, diphenhydramine, propoxyphene, clonidine, amiodarone, and lorazepam (>3 mg/day).

Number and Type of Potentially Inappropriate Medications (PIMs) Prescribed
 Patients, n (%)
Number of PIMs 
0254,200 (51%)
1146,028 (30%)
261,445 (12%)
322,128 (4%)
4+10,170 (2%)
Number of high‐severity‐rated PIMs 
0304,523 (62%)
1129,588 (26%)
243,739 (9%)
312,213 (2%)
4+3908 (1%)
Use of any PIM by side effect class 
Sedatives156,384 (32%)
Anticholinergic effects109,293 (22%)
Causing orthostasis43,805 (9%)
Causing bleeding14,744 (3%)
Most commonly prescribed 
Promethazine49,888 (10%)
Diphenhydramine45,458 (9%)
Propoxyphene41,786 (8%)
Clonidine34,765 (7%)
Amiodarone34,318 (7%)
Lorazepam (>3 mg/day)25,147 (5%)

Patient, Physician, and Hospital Factors Associated with PIMs

Patient, physician, and hospital characteristics were all associated with use of PIMs (Table 3). In univariate analyses, older patients were less likely to receive any class of PIM, and this difference was accentuated for HS‐PIMs. Women, American Indians, married people, and those not in managed care plans were slightly more likely to receive PIMs, whereas patients admitted with acute myocardial infarction or congestive heart failure were even more likely to receive PIMs (P < .0001 for all comparisons).

Potentially Inappropriate Medication Use by Patient Characteristic
Patient characteristicAny PIM n (row %)Any high‐severity PIM n (row %)Sedatives n (row %)Anticholinergic effects n (row %)Causing orthostasis n (row %)Causing bleeding n (row %)
  • An additional 24,602 patients (5%) seen by 42 additional physician specialties were excluded from this analysis.

  • Chi‐square tests indicated all differences by patient characteristics were significant at P < .0001 except there was no significant difference by managed care status for use rates of drugs potentially causing orthostasis or drugs potentially causing bleeding.

Overall239,771 (49%)189,448 (38%)156,384 (32%)109,293 (22%)43,805 (9%)14,744 (3%)
Age group
6574 years89,168 (53%)72,573 (43%)61,399 (36%)44,792 (27%)15,799 (9%)6655 (4%)
7584 years100,787 (49%)79,595 (39%)65,034 (32%)45,121 (22%)18,519 (9%)5727 (3%)
85+ years49,816 (42%)37,280 (31%)29,951 (25%)19,380 (16%)9487 (8%)2362 (2%)
Sex
Male100,824 (47%)79,535 (37%)63,591 (30%)42,754 (20%)17,885 (8%)5771 (3%)
Female138,947 (49%)109,913 (39%)92,793 (33%)66,539 (24%)25,920 (9%)8973 (3%)
Race
White173,481 (49%)139,941 (40%)112,556 (32%)81,097 (23%)27,555 (8%)10,590 (3%)
Black26,793 (51%)18,655 (36%)18,720 (36%)11,263 (21%)8925 (17%)1536 (3%)
Hispanic8509 (47%)6370 (35%)5549 (31%)3505 (19%)2047 (11%)648 (4%)
American Indian1091 (58%)849 (45%)818 (44%)563 (30%)190 (10%)76 (4%)
Asian/Pacific Islander2386 (40%)1896 (32%)1420 (24%)1023 (17%)519 (9%)127 (2%)
Other27,511 (43%)21,737 (34%)17,321 (27%)11,842 (18%)4569 (7%)1767 (3%)
Marital status
Married/partner96,874 (50%)77,803 (40%)63,303 (33%)45,042 (23%)16,765 (9%)5969 (3%)
Widowed74,622 (48%)58,012 (37%)48,367 (31%)33,516 (22%)13,865 (9%)4354 (3%)
Single/separated/divorced36,583 (48%)28,799 (38%)24,251 (32%)16,115 (21%)7229 (10%)2399 (3%)
Other31,692 (46%)24,834 (36%)20,463 (30%)14,620 (21%)5946 (9%)2022 (3%)
Primary diagnosis
Pneumonia56,845 (46%)46,271 (38%)35,353 (29%)25,484 (21%)9184 (7%)4155 (3%)
Heart failure56,460 (52%)42,231 (39%)34,340 (31%)22,093 (20%)10,117 (9%)1945 (2%)
Acute MI43,046 (61%)37,849 (54%)32,560 (46%)25,568 (36%)4738 (7%)2549 (4%)
Ischemic stroke25,763 (45%)17,613 (31%)18,500 (32%)8742 (15%)9644 (17%)1384 (2%)
Chest pain20,655 (41%)16,363 (32%)13,536 (27%)10,520 (21%)3474 (7%)2027 (4%)
COPD18,876 (42%)14,626 (33%)12,087 (27%)8096 (18%)3209 (7%)1139 (3%)
Urinary tract infection18,126 (46%)14,495 (37%)10,008 (25%)8790 (22%)3439 (9%)1545 (4%)
Payer type
Nonmanaged care212,150 (49%)168,013 (39%)138,679 (32%)97,776 (23%)38,341 (9%)12,868 (3%)
Managed care27,621 (44%)21,435 (34%)17,705 (28%)11,517 (18%)5464 (9%)1876 (3%)
Attending physician specialty*
Internal medicine (internist%)112,664 (47%)86,907 (36%)71,382 (30%)48,746 (20%)23,221 (10%)7086 (3%)
Family/general medicine41,303 (45%)32,338 (36%)25,653 (28%)18,274 (20%)7660 (8%)2852 (3%)
Cardiology48,485 (58%)40,752 (49%)34,859 (42%)25,792 (31%)5455 (7%)2542 (3%)
Pulmonology10,231 (48%)8105 (38%)6746 (32%)4064 (19%)1739 (8%)574 (3%)
Hospitalist7003 (47%)5443 (36%)4447 (30%)3179 (21%)1471 (10%)463 (3%)
Nephrology4508 (55%)3388 (41%)3132 (38%)2054 (25%)1326 (16%)198 (2%)
Neurology2420 (42%)1789 (31%)1625 (28%)851 (15%)699 (12%)174 (3%)
Geriatrics1020 (33%)785 (25%)596 (19%)404 (13%)196 (6%)41 (1%)

The HS‐PIM prescribing varied substantially by attending specialty (Fig. 2). Internists, family practitioners, and hospitalists all had similar median rates (33%), cardiologists had a higher median rate (48%), and geriatricians had a lower rate (24%). The most common PIM also differed by specialty: whereas promethazine was the most commonly prescribed drug across most specialties, nephrologists and neurologists used clonidine, pulmonologists used lorazepam, and cardiologists used diphenhydramine most often. Among the 8% of physicians who saw at least 50 patients, there was also great variation in each specialty (Fig. 2). Among internists and cardiologists who saw at least 50 patients, the high‐severity PIM usage rate ranged from 0% to more than 90%.

Figure 2
Distribution of physician prescribing rates for high‐severity‐rated PIM by specialty for physicians treating at least 50 hospitalized patients during the study period (N, number of physicians in each specialty). The line in the middle of each box represents the median use rate across physicians, and the box extends to the interquartile range (IQR). The lines emerging from the box extend to the adjacent values. The upper adjacent value is defined as the largest data point less than or equal to the 75th percentile plus 1.5 times the IQR; the lower adjacent value is defined as the smallest data point greater than or equal to the 25th percentile minus 1.5 IQR. Observed points more extreme than the adjacent values are individually plotted.

There was substantial variation in PIM usage among hospitals, most notably by region. The mean proportion of patients receiving PIMs ranged from 34% at hospitals in the Northeast to 55% at hospitals in the South (Table 4). Smaller hospitals and those in urban settings had slightly lower rates, as did those that had geriatricians on staff. The teaching status of the hospital had little effect. Variation at the individual hospital level was extreme (Fig. 3). Although half of all hospitals had rates between 43% and 58%, in 7 hospitals with more than 300 encounters each, PIMs were never prescribed for geriatric patients.

Figure 3
Distribution of hospital use rates for each category of PIM among hospitals with at least 100 eligible patients during the study period. Thirteen hospitals (3%) and 324 patients (<0.1%) were excluded. For interpretation of the box plots, see Figure 2.
Percentage of Patients Prescribed Potentially Inappropriate Medication (PIM) by Hospital Characteristic
 Hospitals Total = 384 n (%)Patients N = 49,3971 n (%)Any PIM Mean = 48.2 Mean (SD)Any high‐severity PIM Mean = 38.7 Mean (SD)Sedatives Mean = 30.2 Mean (SD)Anticholinergic effects Mean = 21.5 Mean (SD)Causing orthostasis Mean = 8.5 Mean (SD)Causing bleeding Mean = 3.1 Mean (SD)
  • Note: P values from analysis of variance of hospital use rates for each hospital characteristic.

  • P < .05,

  • P < .001,

  • P < .0001.

Hospital region  *****************
Midwest76 (20%)95,791 (19%)38.8 (19.7)30.0 (16.4)24.3 (13.8)15.1 (9.9)6.9 (6.3)3.1 (2.3)
Northeast47 (12%)79,138 (16%)34.1 (12.6)26.2 (11.2)19.0 (9.2)13.5 (8.1)4.9 (2.3)2.1 (1.6)
South199 (52%)260,870 (53%)54.5 (10.1)42.7 (9.6)36.0 (10.8)26.4 (8.6)10.4 (4.6)3.6 (2.5)
West62 (16%)58,172 (12%)45.8 (8.1)37.4 (7.1)27.3 (7.7)19.5 (5.7)7.4 (4.8)2.7 (1.3)
Teaching status        
Nonteaching297 (77%)324,948 (66%)47.3 (14.6)36.9 (12.3)29.8 (12.0)21.3 (9.9)8.7 (5.4)3.3 (2.4)
Teaching87 (23%)169,023 (34%)48.2 (16.0)38.8 (14.2)31.6 (14.5)22.1 (10.2)7.8 (4.4)2.7 (1.5)
Staffed beds   ***   
22200143 (37%)80,741 (16%)45.5 (16.9)35.2 (14.6)27.5 (14.0)20.1 (10.3)8.0 (6.2)3.5 (3.1)
200400137 (36%)177,286 (36%)47.7 (14.2)37.8 (12.0)30.5 (11.6)22.0 (10.0)8.4 (4.7)3.0 (1.6)
400+104 (27%)235944 (48%)50.1 (12.4)39.6 (10.6)33.5 (10.9)22.7 (9.3)9.3 (4.2)2.9 (1.4)
Population serviced     ****
Rural119 (31%)102,799 (21%)48.4 (13.0)38.3 (10.6)29.2 (11.0)23.2 (9.3)7.5 (4.0)3.7 (3.0)
Urban265 (69%)391,172 (79%)47.1 (15.7)36.9 (13.7)30.6 (13.2)20.7 (10.2)9.0 (5.6)2.9 (1.8)
Geriatrician presence        
No340 (89%)409,281 (83%)47.7 (15.3)37.6 (13.0)30.3 (12.8)21.7 (10.0)8.4 (5.3)3.2 (2.3)
Yes44 (11%)84,690 (17%)45.8 (11.4)35.5 (10.6)29.4 (10.8)19.6 (9.4)9.3 (4.3)2.9 (1.6)

Multivariable Model

In a multivariable logit model that included all patient, hospital, and physician characteristics and that accounted for clustering at the hospital, physician, and diagnosis levels, several characteristics were associated with HS‐PIM prescribing (Table 5). By far the most important predictor of use was hospital region. Compared with patients at hospitals in the Midwest, patients in the South (OR 1.63, 95% CI 1.591.67) and West (OR 1.43, 95% CI 1.381.47) were more likely and those in the Northeast were less likely (OR 0.85, 95% CI 0.830.88) to receive HS‐PIMs. Larger hospitals had higher HS‐PIM rates than smaller ones, but teaching status and rural or urban setting were not associated with HS‐PIM prescribing. The presence of geriatricians in a hospital was also associated with lower HS‐PIM prescribing for the entire hospital.

Adjusted Odds Ratio Estimates for High‐Severity PIM Use
Effect (reference)Odds ratio95% Confidence limits
Age   
6574 years1.00  
7584 years0.830.820.84
85+ years0.590.580.61
Sex   
Female1.00  
Male0.850.830.86
Race   
White1.00  
Black0.780.760.80
Hispanic0.840.810.87
American Indian0.970.881.07
Asian/Pacific Islander0.740.700.79
Other0.940.920.97
Marital Status   
Married/partner1.00  
Single/separated/divorced0.960.940.98
Widowed0.960.950.98
Other0.930.900.95
Primary diagnosis   
Pneumonia1.00  
COPD0.830.810.85
Heart failure1.141.121.16
Ischemic stroke0.840.820.86
Acute MI1.951.902.01
Urinary tract infection1.061.031.09
Chest pain0.870.840.89
Comorbidities (yes or no)   
Hypertension0.980.970.99
Diabetes0.980.971.00
Chronic lung disease1.111.101.13
Fluid and electrolyte disorders1.261.241.27
Anemia deficiencies1.171.151.18
Congestive heart failure1.341.321.37
Hypothyroidism1.131.111.15
Peripheral vascular disease1.091.061.11
Depression1.381.351.41
Neurological disorders0.890.870.91
Renal failure1.231.201.26
Obesity1.111.081.14
Payer type   
Managed care1.00  
Not managed care1.041.021.06
Attending physician specialty   
Internal medicine1.00  
Cardiology1.321.281.36
Family/general medicine0.990.971.01
Geriatrics0.690.610.78
Hospitalist0.900.840.96
Nephrology1.020.961.08
Neurology0.930.861.00
Pulmonology1.101.051.15
Setting   
Rural1.00  
Urban1.021.001.05
 
Teaching status   
Nonteaching1.00  
Teaching1.010.981.03
Number of beds   
222001.00  
2004001.081.051.11
400+1.121.091.16
Region   
Midwest1.00  
Northeast0.850.830.88
South1.631.591.67
West1.431.381.47
Geriatrician presence   
No1.00  
Yes0.930.900.95

Physician specialty was also important. Adjusting for diagnosis attenuated some of this association, but compared with internists, cardiologists (OR 1.32, 95% CI 1.281.36) and pulmonologists (OR 1.10, 95% CI 1.051.15) were still more likely, hospitalists (OR 0.90, 95% CI 0.840.96) were less likely, and geriatricians (0.69, 95% CI 0.610.78) were least likely to prescribe any HS‐PIM.

Patient factors were also associated with HS‐PIM use. Compared with patients age 6574 years, patients older than 85 years were much less likely to receive an HS‐PIM (OR 0.59, CI 0.580.61), as to a lesser extent were nonwhites compared with whites and unmarried people compared with those who were married. Compared with patients with pneumonia, those with COPD, stroke, or chest pain were less likely and those with myocardial infarction and congestive heart failure were more likely to receive HS‐PIMs. Patients with a secondary diagnosis of depression were also at high risk (OR 1.38, CI 1.351.41).

DISCUSSION

Although Americans age 65 years and older make up less than 15% of the U.S. population, they consume about one third of all prescription drugs20 and account for one third of all hospital admissions.21 Using the Beers list, numerous studies have documented high rates of potentially inappropriate prescribing for community‐dwelling elderly and nursing home patients and, in some studies, an attendant risk of falling,2224 hip fracture,25, 26 hospitalization,13 or death.14 Applying these same criteria to a large sample of medical inpatients, we found that almost half received a potentially inappropriate drug, most of high severity. Moreover, the PIM prescribing rate varied substantially by region, hospital, and attending physician specialty. Although the use of PIMs was associated with patient age, comorbidities, and primary diagnosis, these patient factors explained only a small portion of the variation in prescribing practices across groups of physicians and hospitals.

Using consensus criteria, Beers originally found that 40% of the residents in 12 nursing homes received at least 1 PIM,8 and studies of community‐dwelling elderly demonstrated rates of 21% to 37%, with little change over time.6, 27, 28 Several small studies have examined inpatient prescribing.16, 17, 29, 30 The largest17 found that only 15% of elderly Italian inpatients received a PIM. Our finding, that 49% of inpatients had received at least 1 PIM, may partially reflect the high prevalence of use among elderly US patients in nursing homes and the community.

Regional variation has been demonstrated for ambulatory patients in the US6 and Europe.31 Zhan et al. found slightly higher rates of PIM use in the Midwest and the South (23%) than in the Northeast and the West (19%). Variation in Europe was greater, with 41% of patients in the Czech Republic versus 5.8% of patients in Denmark receiving at least 1 PIM. We found that region was the strongest predictor of in‐hospital HS‐PIM use, with patients in the South most likely and patients in the Northeast least likely to receive HS‐PIMs. This variation persisted even after adjusting for differences in other patient and hospital factors, suggesting that local custom played a large role in the decision to prescribe HS‐PIMs. Moreover, because outpatient rates are more uniform, these large differences seem limited to inpatient practice.

Patient factors have also been examined. Advanced age was associated with decreased PIM use in some studies17, 28, 31 but not in others.6, 27 We found increasing age to be strongly associated with decreased PIM use, suggesting that in the hospital, at least, doctors take care to avoid prescribing certain drugs to the frail elderly. Women appear to be consistently at higher risk than men,6, 27, 28, 31 and white patients are more at risk than those of other races.6 Our finding that certain diagnoses were associated with higher or lower rates has not been reported previously. The lower rates associated with stroke and COPD suggest that prescribers were aware that these patients were at increased risk of delirium and respiratory depression. The higher rates associated with myocardial infarction may have to do with the use of standardized order sets (eg, cath lab orders) that do not consider the age of the patient going for the procedure.

Admission to a geriatric service32 and intervention by a clinical pharmacist33 have been shown to decrease PIM prescribing at discharge. We noted that patients cared for by a geriatrician had the lowest rates of PIM prescribing during hospitalization as well and that hospitals with geriatricians had lower rates overall, possibly demonstrating that geriatricians had a ripple effect on their colleagues. Hospitalists also had lower rates than internists, supporting the notion that hospitalists provide higher‐quality inpatient care.

Our study had some important limitations. First, we only had access to inpatient administrative records. Thus, we could not identify which medications were continued from home and which were begun in the hospital, nor could we know the indications for which specific drugs were prescribed or who prescribed them. Based on published outpatient rates, however, we could assume that many of the drugs were started in the hospital and that others could have been discontinued but were not. Second, the Beers list was developed by the modified Delphi method; there was little empirical evidence of the danger of specific drugs, although some classes, such as benzodiazepines, opiates and digoxin, have been associated with inpatient falls.18, 3436 Furthermore, our administrative database did not allow us to balance the risks and benefits for particular patients; hence, the medications were only potentially inappropriate, and our study did not address the consequences of such prescribing. Although some of these drugs may be appropriate under certain circumstances, it is unlikely that these circumstances would vary by 60% across geographic regions or that internists would encounter these circumstances more often than do hospitalists. Thus, although we could not identify specific patients who received inappropriate medications, we did identify certain hospitals and even whole regions of the country in which the rate of inappropriate prescribing was high. Third, the Beers list, which was developed for outpatient use, may be less relevant in the inpatient setting. However, given that inpatients have more organ dysfunction and are at higher risk of delirium and falls, it may actually be more applicable to hospitalized patients. We similarly did not distinguish between single and multiple doses because the Beers list does not make such a distinction, and there is no empirical evidence that a single dose is safe. Indeed, patients are often at highest risk of falls immediately after initiation of therapy.3739 We did, however, exclude drugs such as laxatives, which may be appropriate for brief inpatient use but not for chronic use.

Our study also had a number of strengths. The large sample size, representing approximately 5% of annual inpatient admissions in the US over 2 years, offered an instructive look at the recent prescribing patterns of thousands of US physicians. We were able to identify many patient, physician, and hospital factors associated with PIM prescribing that have not previously been reported. Some of these factors, such as advanced age and comorbid diagnoses, suggest that physicians do tailor their treatment to individual patients. Nevertheless, patient factors accounted for only a small portion of the variation in prescribing. The largest variation, associated with regional, hospital, and physician factors, highlights the opportunity for improvement.

At the same time, our findings are encouraging for 2 reasons. First, most inappropriate prescribing involved only a handful of medications, so small changes in prescribing patterns could have a tremendous impact. Second, observing the practice of individual physicians and hospitals reveals what is possible. We found that in most specialties there were physicians who rarely or never used PIMs. We also found 7 hospitals, each with at least 300 cases, where no PIMs were ever prescribed.

Where should hospitals focus their efforts to prevent inappropriate prescribing? Our data highlight the complexity of the problem, which seems daunting. PIM prescribing is spread across all specialties, including geriatrics, and although cardiologists had the highest rate of prescribing, internists, who were more numerous, accounted for a much higher overall number of potentially inappropriate prescriptions. It would be instructive to study the 7 hospitals where PIMs were never prescribed or to interview those physicians who never prescribed PIMs, but the anonymous nature of our data would not allow for this. However, our data do suggest some directions. First, hospitals should become aware of their own rates of PIM use because measurement is the first step in quality improvement. Next, hospitals should focus efforts on reducing the use of the most common drugs. Eliminating just 3 drugs promethazine, diphenhydramine, and propoxyphenewould reduce the use of PIMs in 24% of elderly patients. Enlisting hospital pharmacists and electronic health records and reviewing standard order sets for elderly patients are potentially effective strategies. Finally, increasing the presence of geriatricians and hospitalists would be expected to have a modest impact.

In a representative sample of elderly inpatients, we found that almost half received a potentially inappropriate medication and that the rate of inappropriate prescribing varied widely among doctors and hospitals. Additional research is needed to distinguish which of the Beers drugs are most harmful and which patients are at highest risk. Research should also focus on understanding differences in prescribing patterns, perhaps by studying the outliers at both ends of the quality spectrum, and on techniques to minimize non‐patient‐centered variation.

References
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Article PDF
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Journal of Hospital Medicine - 3(2)
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Legacy Keywords
drug safety, geriatric patient, pharmaceuticals, quality improvement
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Medications can be considered inappropriate when their risk outweighs their benefit. The Beers list1 identifies medications that should be avoided in persons 65 years or older because they are ineffective or pose an unnecessarily high risk or because a safer alternative is available. Initially developed in 1991, the list has gained wide acceptance and has been updated twice.2, 3 In July 1999 it was adopted by the Centers for Medicare & Medicaid Services (CMS) for nursing home regulation, and in 2006 the National Committee on Quality Assurance adopted a modified version as a Health Plan Employer Data and Information Set (HEDIS) measure of quality of care for older Americans.4

A number of studies have demonstrated that inappropriate prescribing is common in the ambulatory setting,57 in nursing homes,8, 9 and in emergency departments10, 11 and that exposure to inappropriate medications is associated with increased risk of adverse drug reactions12 and hospitalization.13, 14 Initial studies of hospitalized patients1517 suggest that potentially inappropriate prescribing is also common among elderly inpatients and that reducing the misuse of psychotropic medications can prevent falls.18 We report on the incidence of and risk factors associated with potentially inappropriate prescribing in a large sample of hospitalized elders.

METHODS

Patients

We conducted a retrospective cohort study using data from 384 hospitals participating in Perspective (Premier, Inc., Charlotte, NC), a database developed for measuring quality and health care utilization. Participating hospitals represent all regions of the United States and are primarily small‐ to medium‐sized nonteaching hospitals most of which are in urban areas. Premier collects data elements from participating hospitals via a custom data extract from hospitals' decision support system. Hospitals aggregate the data elements into their decision support systems from multiple information technology systems including billing, medical records, pharmacy, and laboratory systems. In addition to the information contained in the standard hospital discharge file, Perspective includes a date‐stamped log of all billed items, including medications with dose and quantity, for individual patients.

We included patients at least 65 years old admitted between September 1, 2002, and June 30, 2005, with a principal diagnosis of acute myocardial infarction, chronic obstructive pulmonary disease, chest pain, community‐acquired pneumonia, congestive heart failure, ischemic stroke, or urinary tract infection. International Classification of Diseases, Ninth Revision (ICD‐9‐CM) codes were used to identify diagnoses. Patients cared for by an attending physician with a surgical specialty were excluded. The study protocol was approved by the institutional review board of Baystate Medical Center.

Data Elements

For each patient, Perspective contains fields for age, sex, race, marital status, insurance status, principal diagnosis, comorbidities, and specialty of the attending physician. Comorbidities were identified from ICD‐9‐CM secondary diagnosis codes and APR‐DRGs using Healthcare Cost and Utilization Project Comorbidity Software, version 3.1, based on the work of Elixhauser.19 Because almost all patients had Medicare coverage, plans were classified according to managed care status. Finally, for each patient we identified all medications administered, as well as discharge status, readmission rate, total costs, and length of stay. Hospitals were categorized by region (Northeast, South, Midwest, or West), bed size, setting (urban or rural), teaching status, and whether there were geriatricians.

Potentially Inappropriate Prescribing

Using the 2002 updated Beers criteria3 for potentially inappropriate medication (PIM) use in older adults, we identified the total number of PIMs administered to each patient during his or her hospital stay. We classified each PIM as either high or low severity based on the expert consensus expressed in the 1997 update of the Beers criteria.2 The list contains 48 PIMs and an additional 20 that should be avoided in patients with certain conditions. We did not include the second category of PIMs because we did not necessarily have sufficient patient information to make this determination. In addition, some of the standard PIMs, such as laxatives, although inappropriate for chronic outpatient use, could be appropriate in the hospital setting and were excluded from this analysis. Finally, several medications were considered inappropriate only above a given threshold (eg, lorazepam >3.0 mg/day) or for patients without a specific diagnosis (eg, digoxin >0.125 mg/day for patients without atrial fibrillation). We grouped PIMs that had similar side effects into 4 categories: sedatives, anticholinergics, causing orthostasis, or causing bleeding (Fig. 1).

Figure 1
Beers list of potentially inappropriate medications modified for hospitalized patients >65 years old.

Statistical Analysis

Summary statistics at the patient, physician, and hospital levels were constructed using frequencies and proportions for categorical data and means, standard deviations, medians, interquartile ranges, and box plots for continuous‐scale variables. Patients were identified as receiving a PIM if the drug was administered (above threshold dose where applicable) on at least 1 hospital day. We examined the association of each patient characteristic with use of any PIM, any high‐severity‐rated PIM, and each side effect category using chi‐square statistics. Kruskal‐Wallis analysis of variance was used to examine variation in hospital use rates by each hospital characteristic, and physician use rates for high‐severity PIMs by attending specialty. To examine whether it was feasible to avoid PIMs altogether, we compared individual hospitals as well as individual prescribers within their specialty, limiting the comparison to hospitals that contributed at least 100 patients and to physicians with at least 50 patients.

We developed a multivariable model for any high‐severity medication (HS‐PIM) use that included all patient, physician, and hospital characteristics except length of stay, mortality, cost, discharge status, and readmission rate. A generalized estimating equation model (SAS PROC GENMOD) with a logit link and a subcluster correlation structure was used to account for clustering at the hospital, physician, and diagnosis levels, adjusting for the clustering of primary diagnosis within physician level, nested within hospital level. Effects with P < .10 were retained in the model, and interaction effects were also evaluated for significance. Model fit was assessed using deviance and Pearson chi‐square statistics. All analyses were performed with SAS statistical software, version 9.1 (SAS Institute, Cary, NC).

RESULTS

We identified 519,853 patients at least 65 years old during the study period; 564 were excluded because of missing data for key variables or unclear principal diagnosis. An additional 25,318 were excluded because they were cared for by an attending with a surgical specialty. A total of 493,971 patients were included in the study (Table 1). Mean age was 78 years, and 24% of patients were 85 years or older. Forty‐three percent were male, 71% were white, and 39% were currently married. The most common principal diagnoses were community‐acquired pneumonia, congestive heart failure, and acute myocardial infarction. The most common comorbidities were hypertension, diabetes, and chronic pulmonary disease. Medicare was the primary payer for 91% of subjects, and 13% were in managed care plans. Most patients were cared for by internists (49%), family practitioners (18%), or cardiologists (17%). Only 1% of patients had a geriatrician as attending.

Characteristics of 493,971 Older Patients Hospitalized with 1 of 7 Common Medical Conditions
Characteristicn (%)
  • Other physician category includes 42 specialties.

Age group 
6574 years168,527 (34%)
7584 years206,407 (42%)
85+ years119,037 (24%)
Sex 
Male212,358 (43%)
Female281,613 (57%)
Race 
White351,331 (71%)
Black52,429 (11%)
Hispanic18,057 (4%)
American Indian1876 (0%)
Asian/Pacific Islander5926 (1%)
Other64,352 (13%)
Marital status 
Married/partner194,496 (39%)
Widowed155,273 (31%)
Single/separated/divorced75,964 (15%)
Other68,238 (14%)
Primary diagnosis 
Pneumonia122,732 (25%)
Heart failure109,071 (22%)
Acute MI70,581 (14%)
Ischemic stroke57,204 (12%)
Chest pain50,404 (10%)
COPD44,582 (9%)
Urinary tract infection39,397 (8%)
Comorbidities 
Hypertension310,163 (63%)
Diabetes151,755 (31%)
Chronic pulmonary disease134,900 (27%)
Fluid and electrolyte disorders128,703 (26%)
Deficiency anemias92,668 (19%)
Congestive heart failure69,201 (14%)
Hypothyroidism68,711 (14%)
Peripheral vascular disease47,244 (10%)
Depression41,507 (8%)
Other neurological disorders40,200 (8%)
Renal failure38,134 (8%)
Obesity25,143 (5%)
Payer type 
Not Managed care431,583 (87%)
Managed care62,388 (13%)
Attending physician specialty 
Internal medicine (internist)241,982 (49%)
Family/general medicine90,827 (18%)
Cardiology83,317 (17%)
Pulmonology21,163 (4%)
Hospitalist14,924 (3%)
Nephrology8257 (2%)
Neurology5800 (1%)
Geriatrics3099 (1%)
Other*24,602 (5%)
 
Mortality 
Expired28,321 (6%)
Alive465,650 (94%)
Discharge status, n (% of survivors) 
Home323,629 (66%)
Nursing care119,468 (24%)
Transfer/short‐term hospital13,531 (3%)
Hospice9022 (2%)
14‐Day readmission, n (% of survivors) 
Yes35,309 (8%)
No430,334 (92%)
Length of stay (days), median (IQR)4 (2, 7)
Total cost (dollars)$5513 ($3366, $9902)

Just under half of all patients (49%) received at least 1 PIM, and 6% received 3 or more (Table 2). Thirty‐eight percent received at least 1 drug with a high severity rating (HS‐PIM). The most common PIMs were promethazine, diphenhydramine, propoxyphene, clonidine, amiodarone, and lorazepam (>3 mg/day).

Number and Type of Potentially Inappropriate Medications (PIMs) Prescribed
 Patients, n (%)
Number of PIMs 
0254,200 (51%)
1146,028 (30%)
261,445 (12%)
322,128 (4%)
4+10,170 (2%)
Number of high‐severity‐rated PIMs 
0304,523 (62%)
1129,588 (26%)
243,739 (9%)
312,213 (2%)
4+3908 (1%)
Use of any PIM by side effect class 
Sedatives156,384 (32%)
Anticholinergic effects109,293 (22%)
Causing orthostasis43,805 (9%)
Causing bleeding14,744 (3%)
Most commonly prescribed 
Promethazine49,888 (10%)
Diphenhydramine45,458 (9%)
Propoxyphene41,786 (8%)
Clonidine34,765 (7%)
Amiodarone34,318 (7%)
Lorazepam (>3 mg/day)25,147 (5%)

Patient, Physician, and Hospital Factors Associated with PIMs

Patient, physician, and hospital characteristics were all associated with use of PIMs (Table 3). In univariate analyses, older patients were less likely to receive any class of PIM, and this difference was accentuated for HS‐PIMs. Women, American Indians, married people, and those not in managed care plans were slightly more likely to receive PIMs, whereas patients admitted with acute myocardial infarction or congestive heart failure were even more likely to receive PIMs (P < .0001 for all comparisons).

Potentially Inappropriate Medication Use by Patient Characteristic
Patient characteristicAny PIM n (row %)Any high‐severity PIM n (row %)Sedatives n (row %)Anticholinergic effects n (row %)Causing orthostasis n (row %)Causing bleeding n (row %)
  • An additional 24,602 patients (5%) seen by 42 additional physician specialties were excluded from this analysis.

  • Chi‐square tests indicated all differences by patient characteristics were significant at P < .0001 except there was no significant difference by managed care status for use rates of drugs potentially causing orthostasis or drugs potentially causing bleeding.

Overall239,771 (49%)189,448 (38%)156,384 (32%)109,293 (22%)43,805 (9%)14,744 (3%)
Age group
6574 years89,168 (53%)72,573 (43%)61,399 (36%)44,792 (27%)15,799 (9%)6655 (4%)
7584 years100,787 (49%)79,595 (39%)65,034 (32%)45,121 (22%)18,519 (9%)5727 (3%)
85+ years49,816 (42%)37,280 (31%)29,951 (25%)19,380 (16%)9487 (8%)2362 (2%)
Sex
Male100,824 (47%)79,535 (37%)63,591 (30%)42,754 (20%)17,885 (8%)5771 (3%)
Female138,947 (49%)109,913 (39%)92,793 (33%)66,539 (24%)25,920 (9%)8973 (3%)
Race
White173,481 (49%)139,941 (40%)112,556 (32%)81,097 (23%)27,555 (8%)10,590 (3%)
Black26,793 (51%)18,655 (36%)18,720 (36%)11,263 (21%)8925 (17%)1536 (3%)
Hispanic8509 (47%)6370 (35%)5549 (31%)3505 (19%)2047 (11%)648 (4%)
American Indian1091 (58%)849 (45%)818 (44%)563 (30%)190 (10%)76 (4%)
Asian/Pacific Islander2386 (40%)1896 (32%)1420 (24%)1023 (17%)519 (9%)127 (2%)
Other27,511 (43%)21,737 (34%)17,321 (27%)11,842 (18%)4569 (7%)1767 (3%)
Marital status
Married/partner96,874 (50%)77,803 (40%)63,303 (33%)45,042 (23%)16,765 (9%)5969 (3%)
Widowed74,622 (48%)58,012 (37%)48,367 (31%)33,516 (22%)13,865 (9%)4354 (3%)
Single/separated/divorced36,583 (48%)28,799 (38%)24,251 (32%)16,115 (21%)7229 (10%)2399 (3%)
Other31,692 (46%)24,834 (36%)20,463 (30%)14,620 (21%)5946 (9%)2022 (3%)
Primary diagnosis
Pneumonia56,845 (46%)46,271 (38%)35,353 (29%)25,484 (21%)9184 (7%)4155 (3%)
Heart failure56,460 (52%)42,231 (39%)34,340 (31%)22,093 (20%)10,117 (9%)1945 (2%)
Acute MI43,046 (61%)37,849 (54%)32,560 (46%)25,568 (36%)4738 (7%)2549 (4%)
Ischemic stroke25,763 (45%)17,613 (31%)18,500 (32%)8742 (15%)9644 (17%)1384 (2%)
Chest pain20,655 (41%)16,363 (32%)13,536 (27%)10,520 (21%)3474 (7%)2027 (4%)
COPD18,876 (42%)14,626 (33%)12,087 (27%)8096 (18%)3209 (7%)1139 (3%)
Urinary tract infection18,126 (46%)14,495 (37%)10,008 (25%)8790 (22%)3439 (9%)1545 (4%)
Payer type
Nonmanaged care212,150 (49%)168,013 (39%)138,679 (32%)97,776 (23%)38,341 (9%)12,868 (3%)
Managed care27,621 (44%)21,435 (34%)17,705 (28%)11,517 (18%)5464 (9%)1876 (3%)
Attending physician specialty*
Internal medicine (internist%)112,664 (47%)86,907 (36%)71,382 (30%)48,746 (20%)23,221 (10%)7086 (3%)
Family/general medicine41,303 (45%)32,338 (36%)25,653 (28%)18,274 (20%)7660 (8%)2852 (3%)
Cardiology48,485 (58%)40,752 (49%)34,859 (42%)25,792 (31%)5455 (7%)2542 (3%)
Pulmonology10,231 (48%)8105 (38%)6746 (32%)4064 (19%)1739 (8%)574 (3%)
Hospitalist7003 (47%)5443 (36%)4447 (30%)3179 (21%)1471 (10%)463 (3%)
Nephrology4508 (55%)3388 (41%)3132 (38%)2054 (25%)1326 (16%)198 (2%)
Neurology2420 (42%)1789 (31%)1625 (28%)851 (15%)699 (12%)174 (3%)
Geriatrics1020 (33%)785 (25%)596 (19%)404 (13%)196 (6%)41 (1%)

The HS‐PIM prescribing varied substantially by attending specialty (Fig. 2). Internists, family practitioners, and hospitalists all had similar median rates (33%), cardiologists had a higher median rate (48%), and geriatricians had a lower rate (24%). The most common PIM also differed by specialty: whereas promethazine was the most commonly prescribed drug across most specialties, nephrologists and neurologists used clonidine, pulmonologists used lorazepam, and cardiologists used diphenhydramine most often. Among the 8% of physicians who saw at least 50 patients, there was also great variation in each specialty (Fig. 2). Among internists and cardiologists who saw at least 50 patients, the high‐severity PIM usage rate ranged from 0% to more than 90%.

Figure 2
Distribution of physician prescribing rates for high‐severity‐rated PIM by specialty for physicians treating at least 50 hospitalized patients during the study period (N, number of physicians in each specialty). The line in the middle of each box represents the median use rate across physicians, and the box extends to the interquartile range (IQR). The lines emerging from the box extend to the adjacent values. The upper adjacent value is defined as the largest data point less than or equal to the 75th percentile plus 1.5 times the IQR; the lower adjacent value is defined as the smallest data point greater than or equal to the 25th percentile minus 1.5 IQR. Observed points more extreme than the adjacent values are individually plotted.

There was substantial variation in PIM usage among hospitals, most notably by region. The mean proportion of patients receiving PIMs ranged from 34% at hospitals in the Northeast to 55% at hospitals in the South (Table 4). Smaller hospitals and those in urban settings had slightly lower rates, as did those that had geriatricians on staff. The teaching status of the hospital had little effect. Variation at the individual hospital level was extreme (Fig. 3). Although half of all hospitals had rates between 43% and 58%, in 7 hospitals with more than 300 encounters each, PIMs were never prescribed for geriatric patients.

Figure 3
Distribution of hospital use rates for each category of PIM among hospitals with at least 100 eligible patients during the study period. Thirteen hospitals (3%) and 324 patients (<0.1%) were excluded. For interpretation of the box plots, see Figure 2.
Percentage of Patients Prescribed Potentially Inappropriate Medication (PIM) by Hospital Characteristic
 Hospitals Total = 384 n (%)Patients N = 49,3971 n (%)Any PIM Mean = 48.2 Mean (SD)Any high‐severity PIM Mean = 38.7 Mean (SD)Sedatives Mean = 30.2 Mean (SD)Anticholinergic effects Mean = 21.5 Mean (SD)Causing orthostasis Mean = 8.5 Mean (SD)Causing bleeding Mean = 3.1 Mean (SD)
  • Note: P values from analysis of variance of hospital use rates for each hospital characteristic.

  • P < .05,

  • P < .001,

  • P < .0001.

Hospital region  *****************
Midwest76 (20%)95,791 (19%)38.8 (19.7)30.0 (16.4)24.3 (13.8)15.1 (9.9)6.9 (6.3)3.1 (2.3)
Northeast47 (12%)79,138 (16%)34.1 (12.6)26.2 (11.2)19.0 (9.2)13.5 (8.1)4.9 (2.3)2.1 (1.6)
South199 (52%)260,870 (53%)54.5 (10.1)42.7 (9.6)36.0 (10.8)26.4 (8.6)10.4 (4.6)3.6 (2.5)
West62 (16%)58,172 (12%)45.8 (8.1)37.4 (7.1)27.3 (7.7)19.5 (5.7)7.4 (4.8)2.7 (1.3)
Teaching status        
Nonteaching297 (77%)324,948 (66%)47.3 (14.6)36.9 (12.3)29.8 (12.0)21.3 (9.9)8.7 (5.4)3.3 (2.4)
Teaching87 (23%)169,023 (34%)48.2 (16.0)38.8 (14.2)31.6 (14.5)22.1 (10.2)7.8 (4.4)2.7 (1.5)
Staffed beds   ***   
22200143 (37%)80,741 (16%)45.5 (16.9)35.2 (14.6)27.5 (14.0)20.1 (10.3)8.0 (6.2)3.5 (3.1)
200400137 (36%)177,286 (36%)47.7 (14.2)37.8 (12.0)30.5 (11.6)22.0 (10.0)8.4 (4.7)3.0 (1.6)
400+104 (27%)235944 (48%)50.1 (12.4)39.6 (10.6)33.5 (10.9)22.7 (9.3)9.3 (4.2)2.9 (1.4)
Population serviced     ****
Rural119 (31%)102,799 (21%)48.4 (13.0)38.3 (10.6)29.2 (11.0)23.2 (9.3)7.5 (4.0)3.7 (3.0)
Urban265 (69%)391,172 (79%)47.1 (15.7)36.9 (13.7)30.6 (13.2)20.7 (10.2)9.0 (5.6)2.9 (1.8)
Geriatrician presence        
No340 (89%)409,281 (83%)47.7 (15.3)37.6 (13.0)30.3 (12.8)21.7 (10.0)8.4 (5.3)3.2 (2.3)
Yes44 (11%)84,690 (17%)45.8 (11.4)35.5 (10.6)29.4 (10.8)19.6 (9.4)9.3 (4.3)2.9 (1.6)

Multivariable Model

In a multivariable logit model that included all patient, hospital, and physician characteristics and that accounted for clustering at the hospital, physician, and diagnosis levels, several characteristics were associated with HS‐PIM prescribing (Table 5). By far the most important predictor of use was hospital region. Compared with patients at hospitals in the Midwest, patients in the South (OR 1.63, 95% CI 1.591.67) and West (OR 1.43, 95% CI 1.381.47) were more likely and those in the Northeast were less likely (OR 0.85, 95% CI 0.830.88) to receive HS‐PIMs. Larger hospitals had higher HS‐PIM rates than smaller ones, but teaching status and rural or urban setting were not associated with HS‐PIM prescribing. The presence of geriatricians in a hospital was also associated with lower HS‐PIM prescribing for the entire hospital.

Adjusted Odds Ratio Estimates for High‐Severity PIM Use
Effect (reference)Odds ratio95% Confidence limits
Age   
6574 years1.00  
7584 years0.830.820.84
85+ years0.590.580.61
Sex   
Female1.00  
Male0.850.830.86
Race   
White1.00  
Black0.780.760.80
Hispanic0.840.810.87
American Indian0.970.881.07
Asian/Pacific Islander0.740.700.79
Other0.940.920.97
Marital Status   
Married/partner1.00  
Single/separated/divorced0.960.940.98
Widowed0.960.950.98
Other0.930.900.95
Primary diagnosis   
Pneumonia1.00  
COPD0.830.810.85
Heart failure1.141.121.16
Ischemic stroke0.840.820.86
Acute MI1.951.902.01
Urinary tract infection1.061.031.09
Chest pain0.870.840.89
Comorbidities (yes or no)   
Hypertension0.980.970.99
Diabetes0.980.971.00
Chronic lung disease1.111.101.13
Fluid and electrolyte disorders1.261.241.27
Anemia deficiencies1.171.151.18
Congestive heart failure1.341.321.37
Hypothyroidism1.131.111.15
Peripheral vascular disease1.091.061.11
Depression1.381.351.41
Neurological disorders0.890.870.91
Renal failure1.231.201.26
Obesity1.111.081.14
Payer type   
Managed care1.00  
Not managed care1.041.021.06
Attending physician specialty   
Internal medicine1.00  
Cardiology1.321.281.36
Family/general medicine0.990.971.01
Geriatrics0.690.610.78
Hospitalist0.900.840.96
Nephrology1.020.961.08
Neurology0.930.861.00
Pulmonology1.101.051.15
Setting   
Rural1.00  
Urban1.021.001.05
 
Teaching status   
Nonteaching1.00  
Teaching1.010.981.03
Number of beds   
222001.00  
2004001.081.051.11
400+1.121.091.16
Region   
Midwest1.00  
Northeast0.850.830.88
South1.631.591.67
West1.431.381.47
Geriatrician presence   
No1.00  
Yes0.930.900.95

Physician specialty was also important. Adjusting for diagnosis attenuated some of this association, but compared with internists, cardiologists (OR 1.32, 95% CI 1.281.36) and pulmonologists (OR 1.10, 95% CI 1.051.15) were still more likely, hospitalists (OR 0.90, 95% CI 0.840.96) were less likely, and geriatricians (0.69, 95% CI 0.610.78) were least likely to prescribe any HS‐PIM.

Patient factors were also associated with HS‐PIM use. Compared with patients age 6574 years, patients older than 85 years were much less likely to receive an HS‐PIM (OR 0.59, CI 0.580.61), as to a lesser extent were nonwhites compared with whites and unmarried people compared with those who were married. Compared with patients with pneumonia, those with COPD, stroke, or chest pain were less likely and those with myocardial infarction and congestive heart failure were more likely to receive HS‐PIMs. Patients with a secondary diagnosis of depression were also at high risk (OR 1.38, CI 1.351.41).

DISCUSSION

Although Americans age 65 years and older make up less than 15% of the U.S. population, they consume about one third of all prescription drugs20 and account for one third of all hospital admissions.21 Using the Beers list, numerous studies have documented high rates of potentially inappropriate prescribing for community‐dwelling elderly and nursing home patients and, in some studies, an attendant risk of falling,2224 hip fracture,25, 26 hospitalization,13 or death.14 Applying these same criteria to a large sample of medical inpatients, we found that almost half received a potentially inappropriate drug, most of high severity. Moreover, the PIM prescribing rate varied substantially by region, hospital, and attending physician specialty. Although the use of PIMs was associated with patient age, comorbidities, and primary diagnosis, these patient factors explained only a small portion of the variation in prescribing practices across groups of physicians and hospitals.

Using consensus criteria, Beers originally found that 40% of the residents in 12 nursing homes received at least 1 PIM,8 and studies of community‐dwelling elderly demonstrated rates of 21% to 37%, with little change over time.6, 27, 28 Several small studies have examined inpatient prescribing.16, 17, 29, 30 The largest17 found that only 15% of elderly Italian inpatients received a PIM. Our finding, that 49% of inpatients had received at least 1 PIM, may partially reflect the high prevalence of use among elderly US patients in nursing homes and the community.

Regional variation has been demonstrated for ambulatory patients in the US6 and Europe.31 Zhan et al. found slightly higher rates of PIM use in the Midwest and the South (23%) than in the Northeast and the West (19%). Variation in Europe was greater, with 41% of patients in the Czech Republic versus 5.8% of patients in Denmark receiving at least 1 PIM. We found that region was the strongest predictor of in‐hospital HS‐PIM use, with patients in the South most likely and patients in the Northeast least likely to receive HS‐PIMs. This variation persisted even after adjusting for differences in other patient and hospital factors, suggesting that local custom played a large role in the decision to prescribe HS‐PIMs. Moreover, because outpatient rates are more uniform, these large differences seem limited to inpatient practice.

Patient factors have also been examined. Advanced age was associated with decreased PIM use in some studies17, 28, 31 but not in others.6, 27 We found increasing age to be strongly associated with decreased PIM use, suggesting that in the hospital, at least, doctors take care to avoid prescribing certain drugs to the frail elderly. Women appear to be consistently at higher risk than men,6, 27, 28, 31 and white patients are more at risk than those of other races.6 Our finding that certain diagnoses were associated with higher or lower rates has not been reported previously. The lower rates associated with stroke and COPD suggest that prescribers were aware that these patients were at increased risk of delirium and respiratory depression. The higher rates associated with myocardial infarction may have to do with the use of standardized order sets (eg, cath lab orders) that do not consider the age of the patient going for the procedure.

Admission to a geriatric service32 and intervention by a clinical pharmacist33 have been shown to decrease PIM prescribing at discharge. We noted that patients cared for by a geriatrician had the lowest rates of PIM prescribing during hospitalization as well and that hospitals with geriatricians had lower rates overall, possibly demonstrating that geriatricians had a ripple effect on their colleagues. Hospitalists also had lower rates than internists, supporting the notion that hospitalists provide higher‐quality inpatient care.

Our study had some important limitations. First, we only had access to inpatient administrative records. Thus, we could not identify which medications were continued from home and which were begun in the hospital, nor could we know the indications for which specific drugs were prescribed or who prescribed them. Based on published outpatient rates, however, we could assume that many of the drugs were started in the hospital and that others could have been discontinued but were not. Second, the Beers list was developed by the modified Delphi method; there was little empirical evidence of the danger of specific drugs, although some classes, such as benzodiazepines, opiates and digoxin, have been associated with inpatient falls.18, 3436 Furthermore, our administrative database did not allow us to balance the risks and benefits for particular patients; hence, the medications were only potentially inappropriate, and our study did not address the consequences of such prescribing. Although some of these drugs may be appropriate under certain circumstances, it is unlikely that these circumstances would vary by 60% across geographic regions or that internists would encounter these circumstances more often than do hospitalists. Thus, although we could not identify specific patients who received inappropriate medications, we did identify certain hospitals and even whole regions of the country in which the rate of inappropriate prescribing was high. Third, the Beers list, which was developed for outpatient use, may be less relevant in the inpatient setting. However, given that inpatients have more organ dysfunction and are at higher risk of delirium and falls, it may actually be more applicable to hospitalized patients. We similarly did not distinguish between single and multiple doses because the Beers list does not make such a distinction, and there is no empirical evidence that a single dose is safe. Indeed, patients are often at highest risk of falls immediately after initiation of therapy.3739 We did, however, exclude drugs such as laxatives, which may be appropriate for brief inpatient use but not for chronic use.

Our study also had a number of strengths. The large sample size, representing approximately 5% of annual inpatient admissions in the US over 2 years, offered an instructive look at the recent prescribing patterns of thousands of US physicians. We were able to identify many patient, physician, and hospital factors associated with PIM prescribing that have not previously been reported. Some of these factors, such as advanced age and comorbid diagnoses, suggest that physicians do tailor their treatment to individual patients. Nevertheless, patient factors accounted for only a small portion of the variation in prescribing. The largest variation, associated with regional, hospital, and physician factors, highlights the opportunity for improvement.

At the same time, our findings are encouraging for 2 reasons. First, most inappropriate prescribing involved only a handful of medications, so small changes in prescribing patterns could have a tremendous impact. Second, observing the practice of individual physicians and hospitals reveals what is possible. We found that in most specialties there were physicians who rarely or never used PIMs. We also found 7 hospitals, each with at least 300 cases, where no PIMs were ever prescribed.

Where should hospitals focus their efforts to prevent inappropriate prescribing? Our data highlight the complexity of the problem, which seems daunting. PIM prescribing is spread across all specialties, including geriatrics, and although cardiologists had the highest rate of prescribing, internists, who were more numerous, accounted for a much higher overall number of potentially inappropriate prescriptions. It would be instructive to study the 7 hospitals where PIMs were never prescribed or to interview those physicians who never prescribed PIMs, but the anonymous nature of our data would not allow for this. However, our data do suggest some directions. First, hospitals should become aware of their own rates of PIM use because measurement is the first step in quality improvement. Next, hospitals should focus efforts on reducing the use of the most common drugs. Eliminating just 3 drugs promethazine, diphenhydramine, and propoxyphenewould reduce the use of PIMs in 24% of elderly patients. Enlisting hospital pharmacists and electronic health records and reviewing standard order sets for elderly patients are potentially effective strategies. Finally, increasing the presence of geriatricians and hospitalists would be expected to have a modest impact.

In a representative sample of elderly inpatients, we found that almost half received a potentially inappropriate medication and that the rate of inappropriate prescribing varied widely among doctors and hospitals. Additional research is needed to distinguish which of the Beers drugs are most harmful and which patients are at highest risk. Research should also focus on understanding differences in prescribing patterns, perhaps by studying the outliers at both ends of the quality spectrum, and on techniques to minimize non‐patient‐centered variation.

Medications can be considered inappropriate when their risk outweighs their benefit. The Beers list1 identifies medications that should be avoided in persons 65 years or older because they are ineffective or pose an unnecessarily high risk or because a safer alternative is available. Initially developed in 1991, the list has gained wide acceptance and has been updated twice.2, 3 In July 1999 it was adopted by the Centers for Medicare & Medicaid Services (CMS) for nursing home regulation, and in 2006 the National Committee on Quality Assurance adopted a modified version as a Health Plan Employer Data and Information Set (HEDIS) measure of quality of care for older Americans.4

A number of studies have demonstrated that inappropriate prescribing is common in the ambulatory setting,57 in nursing homes,8, 9 and in emergency departments10, 11 and that exposure to inappropriate medications is associated with increased risk of adverse drug reactions12 and hospitalization.13, 14 Initial studies of hospitalized patients1517 suggest that potentially inappropriate prescribing is also common among elderly inpatients and that reducing the misuse of psychotropic medications can prevent falls.18 We report on the incidence of and risk factors associated with potentially inappropriate prescribing in a large sample of hospitalized elders.

METHODS

Patients

We conducted a retrospective cohort study using data from 384 hospitals participating in Perspective (Premier, Inc., Charlotte, NC), a database developed for measuring quality and health care utilization. Participating hospitals represent all regions of the United States and are primarily small‐ to medium‐sized nonteaching hospitals most of which are in urban areas. Premier collects data elements from participating hospitals via a custom data extract from hospitals' decision support system. Hospitals aggregate the data elements into their decision support systems from multiple information technology systems including billing, medical records, pharmacy, and laboratory systems. In addition to the information contained in the standard hospital discharge file, Perspective includes a date‐stamped log of all billed items, including medications with dose and quantity, for individual patients.

We included patients at least 65 years old admitted between September 1, 2002, and June 30, 2005, with a principal diagnosis of acute myocardial infarction, chronic obstructive pulmonary disease, chest pain, community‐acquired pneumonia, congestive heart failure, ischemic stroke, or urinary tract infection. International Classification of Diseases, Ninth Revision (ICD‐9‐CM) codes were used to identify diagnoses. Patients cared for by an attending physician with a surgical specialty were excluded. The study protocol was approved by the institutional review board of Baystate Medical Center.

Data Elements

For each patient, Perspective contains fields for age, sex, race, marital status, insurance status, principal diagnosis, comorbidities, and specialty of the attending physician. Comorbidities were identified from ICD‐9‐CM secondary diagnosis codes and APR‐DRGs using Healthcare Cost and Utilization Project Comorbidity Software, version 3.1, based on the work of Elixhauser.19 Because almost all patients had Medicare coverage, plans were classified according to managed care status. Finally, for each patient we identified all medications administered, as well as discharge status, readmission rate, total costs, and length of stay. Hospitals were categorized by region (Northeast, South, Midwest, or West), bed size, setting (urban or rural), teaching status, and whether there were geriatricians.

Potentially Inappropriate Prescribing

Using the 2002 updated Beers criteria3 for potentially inappropriate medication (PIM) use in older adults, we identified the total number of PIMs administered to each patient during his or her hospital stay. We classified each PIM as either high or low severity based on the expert consensus expressed in the 1997 update of the Beers criteria.2 The list contains 48 PIMs and an additional 20 that should be avoided in patients with certain conditions. We did not include the second category of PIMs because we did not necessarily have sufficient patient information to make this determination. In addition, some of the standard PIMs, such as laxatives, although inappropriate for chronic outpatient use, could be appropriate in the hospital setting and were excluded from this analysis. Finally, several medications were considered inappropriate only above a given threshold (eg, lorazepam >3.0 mg/day) or for patients without a specific diagnosis (eg, digoxin >0.125 mg/day for patients without atrial fibrillation). We grouped PIMs that had similar side effects into 4 categories: sedatives, anticholinergics, causing orthostasis, or causing bleeding (Fig. 1).

Figure 1
Beers list of potentially inappropriate medications modified for hospitalized patients >65 years old.

Statistical Analysis

Summary statistics at the patient, physician, and hospital levels were constructed using frequencies and proportions for categorical data and means, standard deviations, medians, interquartile ranges, and box plots for continuous‐scale variables. Patients were identified as receiving a PIM if the drug was administered (above threshold dose where applicable) on at least 1 hospital day. We examined the association of each patient characteristic with use of any PIM, any high‐severity‐rated PIM, and each side effect category using chi‐square statistics. Kruskal‐Wallis analysis of variance was used to examine variation in hospital use rates by each hospital characteristic, and physician use rates for high‐severity PIMs by attending specialty. To examine whether it was feasible to avoid PIMs altogether, we compared individual hospitals as well as individual prescribers within their specialty, limiting the comparison to hospitals that contributed at least 100 patients and to physicians with at least 50 patients.

We developed a multivariable model for any high‐severity medication (HS‐PIM) use that included all patient, physician, and hospital characteristics except length of stay, mortality, cost, discharge status, and readmission rate. A generalized estimating equation model (SAS PROC GENMOD) with a logit link and a subcluster correlation structure was used to account for clustering at the hospital, physician, and diagnosis levels, adjusting for the clustering of primary diagnosis within physician level, nested within hospital level. Effects with P < .10 were retained in the model, and interaction effects were also evaluated for significance. Model fit was assessed using deviance and Pearson chi‐square statistics. All analyses were performed with SAS statistical software, version 9.1 (SAS Institute, Cary, NC).

RESULTS

We identified 519,853 patients at least 65 years old during the study period; 564 were excluded because of missing data for key variables or unclear principal diagnosis. An additional 25,318 were excluded because they were cared for by an attending with a surgical specialty. A total of 493,971 patients were included in the study (Table 1). Mean age was 78 years, and 24% of patients were 85 years or older. Forty‐three percent were male, 71% were white, and 39% were currently married. The most common principal diagnoses were community‐acquired pneumonia, congestive heart failure, and acute myocardial infarction. The most common comorbidities were hypertension, diabetes, and chronic pulmonary disease. Medicare was the primary payer for 91% of subjects, and 13% were in managed care plans. Most patients were cared for by internists (49%), family practitioners (18%), or cardiologists (17%). Only 1% of patients had a geriatrician as attending.

Characteristics of 493,971 Older Patients Hospitalized with 1 of 7 Common Medical Conditions
Characteristicn (%)
  • Other physician category includes 42 specialties.

Age group 
6574 years168,527 (34%)
7584 years206,407 (42%)
85+ years119,037 (24%)
Sex 
Male212,358 (43%)
Female281,613 (57%)
Race 
White351,331 (71%)
Black52,429 (11%)
Hispanic18,057 (4%)
American Indian1876 (0%)
Asian/Pacific Islander5926 (1%)
Other64,352 (13%)
Marital status 
Married/partner194,496 (39%)
Widowed155,273 (31%)
Single/separated/divorced75,964 (15%)
Other68,238 (14%)
Primary diagnosis 
Pneumonia122,732 (25%)
Heart failure109,071 (22%)
Acute MI70,581 (14%)
Ischemic stroke57,204 (12%)
Chest pain50,404 (10%)
COPD44,582 (9%)
Urinary tract infection39,397 (8%)
Comorbidities 
Hypertension310,163 (63%)
Diabetes151,755 (31%)
Chronic pulmonary disease134,900 (27%)
Fluid and electrolyte disorders128,703 (26%)
Deficiency anemias92,668 (19%)
Congestive heart failure69,201 (14%)
Hypothyroidism68,711 (14%)
Peripheral vascular disease47,244 (10%)
Depression41,507 (8%)
Other neurological disorders40,200 (8%)
Renal failure38,134 (8%)
Obesity25,143 (5%)
Payer type 
Not Managed care431,583 (87%)
Managed care62,388 (13%)
Attending physician specialty 
Internal medicine (internist)241,982 (49%)
Family/general medicine90,827 (18%)
Cardiology83,317 (17%)
Pulmonology21,163 (4%)
Hospitalist14,924 (3%)
Nephrology8257 (2%)
Neurology5800 (1%)
Geriatrics3099 (1%)
Other*24,602 (5%)
 
Mortality 
Expired28,321 (6%)
Alive465,650 (94%)
Discharge status, n (% of survivors) 
Home323,629 (66%)
Nursing care119,468 (24%)
Transfer/short‐term hospital13,531 (3%)
Hospice9022 (2%)
14‐Day readmission, n (% of survivors) 
Yes35,309 (8%)
No430,334 (92%)
Length of stay (days), median (IQR)4 (2, 7)
Total cost (dollars)$5513 ($3366, $9902)

Just under half of all patients (49%) received at least 1 PIM, and 6% received 3 or more (Table 2). Thirty‐eight percent received at least 1 drug with a high severity rating (HS‐PIM). The most common PIMs were promethazine, diphenhydramine, propoxyphene, clonidine, amiodarone, and lorazepam (>3 mg/day).

Number and Type of Potentially Inappropriate Medications (PIMs) Prescribed
 Patients, n (%)
Number of PIMs 
0254,200 (51%)
1146,028 (30%)
261,445 (12%)
322,128 (4%)
4+10,170 (2%)
Number of high‐severity‐rated PIMs 
0304,523 (62%)
1129,588 (26%)
243,739 (9%)
312,213 (2%)
4+3908 (1%)
Use of any PIM by side effect class 
Sedatives156,384 (32%)
Anticholinergic effects109,293 (22%)
Causing orthostasis43,805 (9%)
Causing bleeding14,744 (3%)
Most commonly prescribed 
Promethazine49,888 (10%)
Diphenhydramine45,458 (9%)
Propoxyphene41,786 (8%)
Clonidine34,765 (7%)
Amiodarone34,318 (7%)
Lorazepam (>3 mg/day)25,147 (5%)

Patient, Physician, and Hospital Factors Associated with PIMs

Patient, physician, and hospital characteristics were all associated with use of PIMs (Table 3). In univariate analyses, older patients were less likely to receive any class of PIM, and this difference was accentuated for HS‐PIMs. Women, American Indians, married people, and those not in managed care plans were slightly more likely to receive PIMs, whereas patients admitted with acute myocardial infarction or congestive heart failure were even more likely to receive PIMs (P < .0001 for all comparisons).

Potentially Inappropriate Medication Use by Patient Characteristic
Patient characteristicAny PIM n (row %)Any high‐severity PIM n (row %)Sedatives n (row %)Anticholinergic effects n (row %)Causing orthostasis n (row %)Causing bleeding n (row %)
  • An additional 24,602 patients (5%) seen by 42 additional physician specialties were excluded from this analysis.

  • Chi‐square tests indicated all differences by patient characteristics were significant at P < .0001 except there was no significant difference by managed care status for use rates of drugs potentially causing orthostasis or drugs potentially causing bleeding.

Overall239,771 (49%)189,448 (38%)156,384 (32%)109,293 (22%)43,805 (9%)14,744 (3%)
Age group
6574 years89,168 (53%)72,573 (43%)61,399 (36%)44,792 (27%)15,799 (9%)6655 (4%)
7584 years100,787 (49%)79,595 (39%)65,034 (32%)45,121 (22%)18,519 (9%)5727 (3%)
85+ years49,816 (42%)37,280 (31%)29,951 (25%)19,380 (16%)9487 (8%)2362 (2%)
Sex
Male100,824 (47%)79,535 (37%)63,591 (30%)42,754 (20%)17,885 (8%)5771 (3%)
Female138,947 (49%)109,913 (39%)92,793 (33%)66,539 (24%)25,920 (9%)8973 (3%)
Race
White173,481 (49%)139,941 (40%)112,556 (32%)81,097 (23%)27,555 (8%)10,590 (3%)
Black26,793 (51%)18,655 (36%)18,720 (36%)11,263 (21%)8925 (17%)1536 (3%)
Hispanic8509 (47%)6370 (35%)5549 (31%)3505 (19%)2047 (11%)648 (4%)
American Indian1091 (58%)849 (45%)818 (44%)563 (30%)190 (10%)76 (4%)
Asian/Pacific Islander2386 (40%)1896 (32%)1420 (24%)1023 (17%)519 (9%)127 (2%)
Other27,511 (43%)21,737 (34%)17,321 (27%)11,842 (18%)4569 (7%)1767 (3%)
Marital status
Married/partner96,874 (50%)77,803 (40%)63,303 (33%)45,042 (23%)16,765 (9%)5969 (3%)
Widowed74,622 (48%)58,012 (37%)48,367 (31%)33,516 (22%)13,865 (9%)4354 (3%)
Single/separated/divorced36,583 (48%)28,799 (38%)24,251 (32%)16,115 (21%)7229 (10%)2399 (3%)
Other31,692 (46%)24,834 (36%)20,463 (30%)14,620 (21%)5946 (9%)2022 (3%)
Primary diagnosis
Pneumonia56,845 (46%)46,271 (38%)35,353 (29%)25,484 (21%)9184 (7%)4155 (3%)
Heart failure56,460 (52%)42,231 (39%)34,340 (31%)22,093 (20%)10,117 (9%)1945 (2%)
Acute MI43,046 (61%)37,849 (54%)32,560 (46%)25,568 (36%)4738 (7%)2549 (4%)
Ischemic stroke25,763 (45%)17,613 (31%)18,500 (32%)8742 (15%)9644 (17%)1384 (2%)
Chest pain20,655 (41%)16,363 (32%)13,536 (27%)10,520 (21%)3474 (7%)2027 (4%)
COPD18,876 (42%)14,626 (33%)12,087 (27%)8096 (18%)3209 (7%)1139 (3%)
Urinary tract infection18,126 (46%)14,495 (37%)10,008 (25%)8790 (22%)3439 (9%)1545 (4%)
Payer type
Nonmanaged care212,150 (49%)168,013 (39%)138,679 (32%)97,776 (23%)38,341 (9%)12,868 (3%)
Managed care27,621 (44%)21,435 (34%)17,705 (28%)11,517 (18%)5464 (9%)1876 (3%)
Attending physician specialty*
Internal medicine (internist%)112,664 (47%)86,907 (36%)71,382 (30%)48,746 (20%)23,221 (10%)7086 (3%)
Family/general medicine41,303 (45%)32,338 (36%)25,653 (28%)18,274 (20%)7660 (8%)2852 (3%)
Cardiology48,485 (58%)40,752 (49%)34,859 (42%)25,792 (31%)5455 (7%)2542 (3%)
Pulmonology10,231 (48%)8105 (38%)6746 (32%)4064 (19%)1739 (8%)574 (3%)
Hospitalist7003 (47%)5443 (36%)4447 (30%)3179 (21%)1471 (10%)463 (3%)
Nephrology4508 (55%)3388 (41%)3132 (38%)2054 (25%)1326 (16%)198 (2%)
Neurology2420 (42%)1789 (31%)1625 (28%)851 (15%)699 (12%)174 (3%)
Geriatrics1020 (33%)785 (25%)596 (19%)404 (13%)196 (6%)41 (1%)

The HS‐PIM prescribing varied substantially by attending specialty (Fig. 2). Internists, family practitioners, and hospitalists all had similar median rates (33%), cardiologists had a higher median rate (48%), and geriatricians had a lower rate (24%). The most common PIM also differed by specialty: whereas promethazine was the most commonly prescribed drug across most specialties, nephrologists and neurologists used clonidine, pulmonologists used lorazepam, and cardiologists used diphenhydramine most often. Among the 8% of physicians who saw at least 50 patients, there was also great variation in each specialty (Fig. 2). Among internists and cardiologists who saw at least 50 patients, the high‐severity PIM usage rate ranged from 0% to more than 90%.

Figure 2
Distribution of physician prescribing rates for high‐severity‐rated PIM by specialty for physicians treating at least 50 hospitalized patients during the study period (N, number of physicians in each specialty). The line in the middle of each box represents the median use rate across physicians, and the box extends to the interquartile range (IQR). The lines emerging from the box extend to the adjacent values. The upper adjacent value is defined as the largest data point less than or equal to the 75th percentile plus 1.5 times the IQR; the lower adjacent value is defined as the smallest data point greater than or equal to the 25th percentile minus 1.5 IQR. Observed points more extreme than the adjacent values are individually plotted.

There was substantial variation in PIM usage among hospitals, most notably by region. The mean proportion of patients receiving PIMs ranged from 34% at hospitals in the Northeast to 55% at hospitals in the South (Table 4). Smaller hospitals and those in urban settings had slightly lower rates, as did those that had geriatricians on staff. The teaching status of the hospital had little effect. Variation at the individual hospital level was extreme (Fig. 3). Although half of all hospitals had rates between 43% and 58%, in 7 hospitals with more than 300 encounters each, PIMs were never prescribed for geriatric patients.

Figure 3
Distribution of hospital use rates for each category of PIM among hospitals with at least 100 eligible patients during the study period. Thirteen hospitals (3%) and 324 patients (<0.1%) were excluded. For interpretation of the box plots, see Figure 2.
Percentage of Patients Prescribed Potentially Inappropriate Medication (PIM) by Hospital Characteristic
 Hospitals Total = 384 n (%)Patients N = 49,3971 n (%)Any PIM Mean = 48.2 Mean (SD)Any high‐severity PIM Mean = 38.7 Mean (SD)Sedatives Mean = 30.2 Mean (SD)Anticholinergic effects Mean = 21.5 Mean (SD)Causing orthostasis Mean = 8.5 Mean (SD)Causing bleeding Mean = 3.1 Mean (SD)
  • Note: P values from analysis of variance of hospital use rates for each hospital characteristic.

  • P < .05,

  • P < .001,

  • P < .0001.

Hospital region  *****************
Midwest76 (20%)95,791 (19%)38.8 (19.7)30.0 (16.4)24.3 (13.8)15.1 (9.9)6.9 (6.3)3.1 (2.3)
Northeast47 (12%)79,138 (16%)34.1 (12.6)26.2 (11.2)19.0 (9.2)13.5 (8.1)4.9 (2.3)2.1 (1.6)
South199 (52%)260,870 (53%)54.5 (10.1)42.7 (9.6)36.0 (10.8)26.4 (8.6)10.4 (4.6)3.6 (2.5)
West62 (16%)58,172 (12%)45.8 (8.1)37.4 (7.1)27.3 (7.7)19.5 (5.7)7.4 (4.8)2.7 (1.3)
Teaching status        
Nonteaching297 (77%)324,948 (66%)47.3 (14.6)36.9 (12.3)29.8 (12.0)21.3 (9.9)8.7 (5.4)3.3 (2.4)
Teaching87 (23%)169,023 (34%)48.2 (16.0)38.8 (14.2)31.6 (14.5)22.1 (10.2)7.8 (4.4)2.7 (1.5)
Staffed beds   ***   
22200143 (37%)80,741 (16%)45.5 (16.9)35.2 (14.6)27.5 (14.0)20.1 (10.3)8.0 (6.2)3.5 (3.1)
200400137 (36%)177,286 (36%)47.7 (14.2)37.8 (12.0)30.5 (11.6)22.0 (10.0)8.4 (4.7)3.0 (1.6)
400+104 (27%)235944 (48%)50.1 (12.4)39.6 (10.6)33.5 (10.9)22.7 (9.3)9.3 (4.2)2.9 (1.4)
Population serviced     ****
Rural119 (31%)102,799 (21%)48.4 (13.0)38.3 (10.6)29.2 (11.0)23.2 (9.3)7.5 (4.0)3.7 (3.0)
Urban265 (69%)391,172 (79%)47.1 (15.7)36.9 (13.7)30.6 (13.2)20.7 (10.2)9.0 (5.6)2.9 (1.8)
Geriatrician presence        
No340 (89%)409,281 (83%)47.7 (15.3)37.6 (13.0)30.3 (12.8)21.7 (10.0)8.4 (5.3)3.2 (2.3)
Yes44 (11%)84,690 (17%)45.8 (11.4)35.5 (10.6)29.4 (10.8)19.6 (9.4)9.3 (4.3)2.9 (1.6)

Multivariable Model

In a multivariable logit model that included all patient, hospital, and physician characteristics and that accounted for clustering at the hospital, physician, and diagnosis levels, several characteristics were associated with HS‐PIM prescribing (Table 5). By far the most important predictor of use was hospital region. Compared with patients at hospitals in the Midwest, patients in the South (OR 1.63, 95% CI 1.591.67) and West (OR 1.43, 95% CI 1.381.47) were more likely and those in the Northeast were less likely (OR 0.85, 95% CI 0.830.88) to receive HS‐PIMs. Larger hospitals had higher HS‐PIM rates than smaller ones, but teaching status and rural or urban setting were not associated with HS‐PIM prescribing. The presence of geriatricians in a hospital was also associated with lower HS‐PIM prescribing for the entire hospital.

Adjusted Odds Ratio Estimates for High‐Severity PIM Use
Effect (reference)Odds ratio95% Confidence limits
Age   
6574 years1.00  
7584 years0.830.820.84
85+ years0.590.580.61
Sex   
Female1.00  
Male0.850.830.86
Race   
White1.00  
Black0.780.760.80
Hispanic0.840.810.87
American Indian0.970.881.07
Asian/Pacific Islander0.740.700.79
Other0.940.920.97
Marital Status   
Married/partner1.00  
Single/separated/divorced0.960.940.98
Widowed0.960.950.98
Other0.930.900.95
Primary diagnosis   
Pneumonia1.00  
COPD0.830.810.85
Heart failure1.141.121.16
Ischemic stroke0.840.820.86
Acute MI1.951.902.01
Urinary tract infection1.061.031.09
Chest pain0.870.840.89
Comorbidities (yes or no)   
Hypertension0.980.970.99
Diabetes0.980.971.00
Chronic lung disease1.111.101.13
Fluid and electrolyte disorders1.261.241.27
Anemia deficiencies1.171.151.18
Congestive heart failure1.341.321.37
Hypothyroidism1.131.111.15
Peripheral vascular disease1.091.061.11
Depression1.381.351.41
Neurological disorders0.890.870.91
Renal failure1.231.201.26
Obesity1.111.081.14
Payer type   
Managed care1.00  
Not managed care1.041.021.06
Attending physician specialty   
Internal medicine1.00  
Cardiology1.321.281.36
Family/general medicine0.990.971.01
Geriatrics0.690.610.78
Hospitalist0.900.840.96
Nephrology1.020.961.08
Neurology0.930.861.00
Pulmonology1.101.051.15
Setting   
Rural1.00  
Urban1.021.001.05
 
Teaching status   
Nonteaching1.00  
Teaching1.010.981.03
Number of beds   
222001.00  
2004001.081.051.11
400+1.121.091.16
Region   
Midwest1.00  
Northeast0.850.830.88
South1.631.591.67
West1.431.381.47
Geriatrician presence   
No1.00  
Yes0.930.900.95

Physician specialty was also important. Adjusting for diagnosis attenuated some of this association, but compared with internists, cardiologists (OR 1.32, 95% CI 1.281.36) and pulmonologists (OR 1.10, 95% CI 1.051.15) were still more likely, hospitalists (OR 0.90, 95% CI 0.840.96) were less likely, and geriatricians (0.69, 95% CI 0.610.78) were least likely to prescribe any HS‐PIM.

Patient factors were also associated with HS‐PIM use. Compared with patients age 6574 years, patients older than 85 years were much less likely to receive an HS‐PIM (OR 0.59, CI 0.580.61), as to a lesser extent were nonwhites compared with whites and unmarried people compared with those who were married. Compared with patients with pneumonia, those with COPD, stroke, or chest pain were less likely and those with myocardial infarction and congestive heart failure were more likely to receive HS‐PIMs. Patients with a secondary diagnosis of depression were also at high risk (OR 1.38, CI 1.351.41).

DISCUSSION

Although Americans age 65 years and older make up less than 15% of the U.S. population, they consume about one third of all prescription drugs20 and account for one third of all hospital admissions.21 Using the Beers list, numerous studies have documented high rates of potentially inappropriate prescribing for community‐dwelling elderly and nursing home patients and, in some studies, an attendant risk of falling,2224 hip fracture,25, 26 hospitalization,13 or death.14 Applying these same criteria to a large sample of medical inpatients, we found that almost half received a potentially inappropriate drug, most of high severity. Moreover, the PIM prescribing rate varied substantially by region, hospital, and attending physician specialty. Although the use of PIMs was associated with patient age, comorbidities, and primary diagnosis, these patient factors explained only a small portion of the variation in prescribing practices across groups of physicians and hospitals.

Using consensus criteria, Beers originally found that 40% of the residents in 12 nursing homes received at least 1 PIM,8 and studies of community‐dwelling elderly demonstrated rates of 21% to 37%, with little change over time.6, 27, 28 Several small studies have examined inpatient prescribing.16, 17, 29, 30 The largest17 found that only 15% of elderly Italian inpatients received a PIM. Our finding, that 49% of inpatients had received at least 1 PIM, may partially reflect the high prevalence of use among elderly US patients in nursing homes and the community.

Regional variation has been demonstrated for ambulatory patients in the US6 and Europe.31 Zhan et al. found slightly higher rates of PIM use in the Midwest and the South (23%) than in the Northeast and the West (19%). Variation in Europe was greater, with 41% of patients in the Czech Republic versus 5.8% of patients in Denmark receiving at least 1 PIM. We found that region was the strongest predictor of in‐hospital HS‐PIM use, with patients in the South most likely and patients in the Northeast least likely to receive HS‐PIMs. This variation persisted even after adjusting for differences in other patient and hospital factors, suggesting that local custom played a large role in the decision to prescribe HS‐PIMs. Moreover, because outpatient rates are more uniform, these large differences seem limited to inpatient practice.

Patient factors have also been examined. Advanced age was associated with decreased PIM use in some studies17, 28, 31 but not in others.6, 27 We found increasing age to be strongly associated with decreased PIM use, suggesting that in the hospital, at least, doctors take care to avoid prescribing certain drugs to the frail elderly. Women appear to be consistently at higher risk than men,6, 27, 28, 31 and white patients are more at risk than those of other races.6 Our finding that certain diagnoses were associated with higher or lower rates has not been reported previously. The lower rates associated with stroke and COPD suggest that prescribers were aware that these patients were at increased risk of delirium and respiratory depression. The higher rates associated with myocardial infarction may have to do with the use of standardized order sets (eg, cath lab orders) that do not consider the age of the patient going for the procedure.

Admission to a geriatric service32 and intervention by a clinical pharmacist33 have been shown to decrease PIM prescribing at discharge. We noted that patients cared for by a geriatrician had the lowest rates of PIM prescribing during hospitalization as well and that hospitals with geriatricians had lower rates overall, possibly demonstrating that geriatricians had a ripple effect on their colleagues. Hospitalists also had lower rates than internists, supporting the notion that hospitalists provide higher‐quality inpatient care.

Our study had some important limitations. First, we only had access to inpatient administrative records. Thus, we could not identify which medications were continued from home and which were begun in the hospital, nor could we know the indications for which specific drugs were prescribed or who prescribed them. Based on published outpatient rates, however, we could assume that many of the drugs were started in the hospital and that others could have been discontinued but were not. Second, the Beers list was developed by the modified Delphi method; there was little empirical evidence of the danger of specific drugs, although some classes, such as benzodiazepines, opiates and digoxin, have been associated with inpatient falls.18, 3436 Furthermore, our administrative database did not allow us to balance the risks and benefits for particular patients; hence, the medications were only potentially inappropriate, and our study did not address the consequences of such prescribing. Although some of these drugs may be appropriate under certain circumstances, it is unlikely that these circumstances would vary by 60% across geographic regions or that internists would encounter these circumstances more often than do hospitalists. Thus, although we could not identify specific patients who received inappropriate medications, we did identify certain hospitals and even whole regions of the country in which the rate of inappropriate prescribing was high. Third, the Beers list, which was developed for outpatient use, may be less relevant in the inpatient setting. However, given that inpatients have more organ dysfunction and are at higher risk of delirium and falls, it may actually be more applicable to hospitalized patients. We similarly did not distinguish between single and multiple doses because the Beers list does not make such a distinction, and there is no empirical evidence that a single dose is safe. Indeed, patients are often at highest risk of falls immediately after initiation of therapy.3739 We did, however, exclude drugs such as laxatives, which may be appropriate for brief inpatient use but not for chronic use.

Our study also had a number of strengths. The large sample size, representing approximately 5% of annual inpatient admissions in the US over 2 years, offered an instructive look at the recent prescribing patterns of thousands of US physicians. We were able to identify many patient, physician, and hospital factors associated with PIM prescribing that have not previously been reported. Some of these factors, such as advanced age and comorbid diagnoses, suggest that physicians do tailor their treatment to individual patients. Nevertheless, patient factors accounted for only a small portion of the variation in prescribing. The largest variation, associated with regional, hospital, and physician factors, highlights the opportunity for improvement.

At the same time, our findings are encouraging for 2 reasons. First, most inappropriate prescribing involved only a handful of medications, so small changes in prescribing patterns could have a tremendous impact. Second, observing the practice of individual physicians and hospitals reveals what is possible. We found that in most specialties there were physicians who rarely or never used PIMs. We also found 7 hospitals, each with at least 300 cases, where no PIMs were ever prescribed.

Where should hospitals focus their efforts to prevent inappropriate prescribing? Our data highlight the complexity of the problem, which seems daunting. PIM prescribing is spread across all specialties, including geriatrics, and although cardiologists had the highest rate of prescribing, internists, who were more numerous, accounted for a much higher overall number of potentially inappropriate prescriptions. It would be instructive to study the 7 hospitals where PIMs were never prescribed or to interview those physicians who never prescribed PIMs, but the anonymous nature of our data would not allow for this. However, our data do suggest some directions. First, hospitals should become aware of their own rates of PIM use because measurement is the first step in quality improvement. Next, hospitals should focus efforts on reducing the use of the most common drugs. Eliminating just 3 drugs promethazine, diphenhydramine, and propoxyphenewould reduce the use of PIMs in 24% of elderly patients. Enlisting hospital pharmacists and electronic health records and reviewing standard order sets for elderly patients are potentially effective strategies. Finally, increasing the presence of geriatricians and hospitalists would be expected to have a modest impact.

In a representative sample of elderly inpatients, we found that almost half received a potentially inappropriate medication and that the rate of inappropriate prescribing varied widely among doctors and hospitals. Additional research is needed to distinguish which of the Beers drugs are most harmful and which patients are at highest risk. Research should also focus on understanding differences in prescribing patterns, perhaps by studying the outliers at both ends of the quality spectrum, and on techniques to minimize non‐patient‐centered variation.

References
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  2. Beers MH.Explicit criteria for determining potentially inappropriate medication use by the elderly. An update.Arch Intern Med.1997;157:15311536.
  3. Fick DM,Cooper JW,Wade WE,Waller JL,Maclean JR,Beers MH.Updating the Beers criteria for potentially inappropriate medication use in older adults: results of a US consensus panel of experts.Arch Intern Med.2003;163:27162724.
  4. National Committee on Quality Assurance. Drugs to be Avoided in the Elderly. Available at: http://www.ncqa.org/Programs/HEDIS/2006/Volume2/NDC/DAE_06.xls. Accessed November 20,2006.
  5. Curtis LH,Ostbye T,Sendersky V, et al.Inappropriate prescribing for elderly Americans in a large outpatient population.Arch Intern Med.2004;164:16211625.
  6. Zhan C,Sangl J,Bierman AS, et al.Potentially inappropriate medication use in the community‐dwelling elderly: findings from the 1996 Medical Expenditure Panel Survey.JAMA.2001;286:28232829.
  7. Mort JR,Aparasu RR.Prescribing potentially inappropriate psychotropic medications to the ambulatory elderly.Arch Intern Med.2000;160:28252831.
  8. Beers MH,Ouslander JG,Fingold SF, et al.Inappropriate medication prescribing in skilled‐nursing facilities.Ann Intern Med.1992;117:684689.
  9. Perri M,Menon AM,Deshpande AD, et al.Adverse outcomes associated with inappropriate drug use in nursing homes.Ann Pharmacother.2005;39:405411.
  10. Caterino JM,Emond JA,Camargo CA.Inappropriate medication administration to the acutely ill elderly: a nationwide emergency department study, 1992–2000.J Am Geriatr Soc.2004;52:18471855.
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  16. Hanlon JT,Artz MB,Pieper CF, et al.Inappropriate medication use among frail elderly inpatients.Ann Pharmacother.2004;38(1):914.
  17. Onder G,Landi F,Cesari M,Gambassi G,Carbonin P,Bernabei R.Inappropriate medication use among hospitalized older adults in Italy: results from the Italian Group of Pharmacoepidemiology in the Elderly.Eur J Clin Pharmacol.2003;59(2):157162.
  18. Peterson JF,Kuperman GJ,Shek C,Patel M,Avorn J,Bates DW.Guided prescription of psychotropic medications for geriatric inpatients.Arch Intern Med.2005;165:802807.
  19. Elixhauser A,Steiner C,Harris DR,Coffey RM.Comorbidity measures for use with administrative data.Med Care.1998;36(1):827.
  20. Soumerai SB,Ross‐Degnan D.Inadequate prescription‐drug coverage for Medicare enrollees—a call to action.N Engl J Med.1999;340:722728.
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  25. Kamal‐Bahl SJ,Stuart BC,Beers MH.Propoxyphene use and risk for hip fractures in older adults.Am J Geriatr Pharmacother.2006;4:219226.
  26. Ensrud KE,Blackwell T,Mangione CM, et al.Central nervous system active medications and risk for fractures in older women.Arch Intern Med.2003;163:949957.
  27. Simon SR,Chan KA,Soumerai SB, et al.Potentially inappropriate medication use by elderly persons in U.S. Health Maintenance Organizations, 2000–2001.J Am Geriatr Soc.2005;53:227232.
  28. Goulding MR.Inappropriate medication prescribing for elderly ambulatory care patients.Arch Intern Med.2004;164:305312.
  29. Passarelli MC,Jacob‐Filho W,Figueras A.Adverse drug reactions in an elderly hospitalised population: inappropriate prescription is a leading cause.Drugs Aging.2005;22:767777.
  30. Raivio MM,Laurila JV,Strandberg TE,Tilvis RS,Pitkala KH.Use of inappropriate medications and their prognostic significance among in‐hospital and nursing home patients with and without dementia in Finland.Drugs Aging.2006;23:333343.
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  33. Brown BK,Earnhart J.Pharmacists and their effectiveness in ensuring the appropriateness of the chronic medication regimens of geriatric inpatients.Consult Pharm.2004;19:432436.
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  35. Gales BJ,Menard SM.Relationship between the administration of selected medications and falls in hospitalized elderly patients.Ann Pharmacother.1995;29:354358.
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References
  1. Beers MH,Ouslander JG,Rollingher I,Reuben DB,Brooks J,Beck JC.Explicit criteria for determining inappropriate medication use in nursing home residents. UCLA Division of Geriatric Medicine.Arch Intern Med.1991;151:18251832.
  2. Beers MH.Explicit criteria for determining potentially inappropriate medication use by the elderly. An update.Arch Intern Med.1997;157:15311536.
  3. Fick DM,Cooper JW,Wade WE,Waller JL,Maclean JR,Beers MH.Updating the Beers criteria for potentially inappropriate medication use in older adults: results of a US consensus panel of experts.Arch Intern Med.2003;163:27162724.
  4. National Committee on Quality Assurance. Drugs to be Avoided in the Elderly. Available at: http://www.ncqa.org/Programs/HEDIS/2006/Volume2/NDC/DAE_06.xls. Accessed November 20,2006.
  5. Curtis LH,Ostbye T,Sendersky V, et al.Inappropriate prescribing for elderly Americans in a large outpatient population.Arch Intern Med.2004;164:16211625.
  6. Zhan C,Sangl J,Bierman AS, et al.Potentially inappropriate medication use in the community‐dwelling elderly: findings from the 1996 Medical Expenditure Panel Survey.JAMA.2001;286:28232829.
  7. Mort JR,Aparasu RR.Prescribing potentially inappropriate psychotropic medications to the ambulatory elderly.Arch Intern Med.2000;160:28252831.
  8. Beers MH,Ouslander JG,Fingold SF, et al.Inappropriate medication prescribing in skilled‐nursing facilities.Ann Intern Med.1992;117:684689.
  9. Perri M,Menon AM,Deshpande AD, et al.Adverse outcomes associated with inappropriate drug use in nursing homes.Ann Pharmacother.2005;39:405411.
  10. Caterino JM,Emond JA,Camargo CA.Inappropriate medication administration to the acutely ill elderly: a nationwide emergency department study, 1992–2000.J Am Geriatr Soc.2004;52:18471855.
  11. Chin MH,Wang LC,Jin L, et al.Appropriateness of medication selection for older persons in an urban academic emergency department.Acad Emerg Med.1999;6:12321242.
  12. Chang CM,Liu PY,Yang YH,Yang YC,Wu CF,Lu FH.Use of the Beers criteria to predict adverse drug reactions among first‐visit elderly outpatients.Pharmacotherapy.2005;25:831838.
  13. Klarin I,Wimo A,Fastbom J.The association of inappropriate drug use with hospitalisation and mortality: a population‐based study of the very old.Drugs Aging.2005;22(1):6982.
  14. Lau DT,Kasper JD,Potter DE,Lyles A,Bennett RG.Hospitalization and death associated with potentially inappropriate medication prescriptions among elderly nursing home residents.Arch Intern Med.2005;165(1):6874.
  15. Edwards RF,Harrison TM,Davis SM.Potentially inappropriate prescribing for geriatric inpatients: an acute care of the elderly unit compared to a general medicine service.Consult Pharm.2003;18(1):3742, 47–39.
  16. Hanlon JT,Artz MB,Pieper CF, et al.Inappropriate medication use among frail elderly inpatients.Ann Pharmacother.2004;38(1):914.
  17. Onder G,Landi F,Cesari M,Gambassi G,Carbonin P,Bernabei R.Inappropriate medication use among hospitalized older adults in Italy: results from the Italian Group of Pharmacoepidemiology in the Elderly.Eur J Clin Pharmacol.2003;59(2):157162.
  18. Peterson JF,Kuperman GJ,Shek C,Patel M,Avorn J,Bates DW.Guided prescription of psychotropic medications for geriatric inpatients.Arch Intern Med.2005;165:802807.
  19. Elixhauser A,Steiner C,Harris DR,Coffey RM.Comorbidity measures for use with administrative data.Med Care.1998;36(1):827.
  20. Soumerai SB,Ross‐Degnan D.Inadequate prescription‐drug coverage for Medicare enrollees—a call to action.N Engl J Med.1999;340:722728.
  21. National and regional estimates on hospital use for all patients from the HCUP Nationwide Inpatient Sample (NIS). Agency for Healthcare Research and Quality (AHRQ). Available at: http://hcupnet.ahrq.gov/HCUPnet.jsp. Accessed October 12,2006.
  22. French DD,Campbell R,Spehar A,Cunningham F,Bulat T,Luther SL.Drugs and falls in community‐dwelling older people: a national veterans study.Clin Ther.2006;28:619630.
  23. Landi F,Onder G,Cesari M,Barillaro C,Russo A,Bernabei R.Psychotropic medications and risk for falls among community‐dwelling frail older people: an observational study.J Gerontol A Biol Sci Med Sci.2005;60:622626.
  24. Leipzig RM,Cumming RG,Tinetti ME.Drugs and falls in older people: a systematic review and meta‐analysis: I. Psychotropic drugs.J Am Geriatr Soc.1999;47(1):3039.
  25. Kamal‐Bahl SJ,Stuart BC,Beers MH.Propoxyphene use and risk for hip fractures in older adults.Am J Geriatr Pharmacother.2006;4:219226.
  26. Ensrud KE,Blackwell T,Mangione CM, et al.Central nervous system active medications and risk for fractures in older women.Arch Intern Med.2003;163:949957.
  27. Simon SR,Chan KA,Soumerai SB, et al.Potentially inappropriate medication use by elderly persons in U.S. Health Maintenance Organizations, 2000–2001.J Am Geriatr Soc.2005;53:227232.
  28. Goulding MR.Inappropriate medication prescribing for elderly ambulatory care patients.Arch Intern Med.2004;164:305312.
  29. Passarelli MC,Jacob‐Filho W,Figueras A.Adverse drug reactions in an elderly hospitalised population: inappropriate prescription is a leading cause.Drugs Aging.2005;22:767777.
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Issue
Journal of Hospital Medicine - 3(2)
Issue
Journal of Hospital Medicine - 3(2)
Page Number
91-102
Page Number
91-102
Publications
Publications
Article Type
Display Headline
Potentially inappropriate medication use in hospitalized elders
Display Headline
Potentially inappropriate medication use in hospitalized elders
Legacy Keywords
drug safety, geriatric patient, pharmaceuticals, quality improvement
Legacy Keywords
drug safety, geriatric patient, pharmaceuticals, quality improvement
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Copyright © 2008 Society of Hospital Medicine

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Division of General Medicine and Geriatrics, Baystate Medical Center, 759 Chestnut Street, Springfield, MA 01199
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