Background
Falls among older adults are a common and serious problem, leading to potentially severe injuries such as fractures [1‐3] and head injuries [2, 3]. People over 65 years of age have the highest risk of falling, with nearly one-quarter to one-third living in the community falling at least once per year [2, 4, 5]. Older adults with osteoporosis are particularly vulnerable to sustaining a fracture from low impact forces such as falling from a standing height, known as a “fragility fracture” [2, 6, 7]. Previous studies have shown that patients with a prevalent fragility fracture have a high risk of subsequent falls [1, 8] and recurrent fractures [1, 9] and there is a strong association between falls, fall-related fractures, and functional decline [9‐11]. Recurrent fractures within the fragility fracture population are particularly worrisome as they can result in severe morbidity and an increased mortality risk [12].
Research into the epidemiology of falls in older adults has identified a number of risk factors for falling, including advanced age [5, 13, 14], female gender [2, 15], chronic disease burden [4, 16], the use of multiple prescribed medications [17, 18], irrespective of type [19‐22], impaired balance and gait [1, 3, 20, 23], living situation/conditions (e.g., residential care, community dwellers) [3, 7, 24]; high alcohol intake [2, 3, 7] history of previous falls [1, 3, 14], low Vitamin D intake [4, 7, 25, 26], impaired cognition [3, 7, 20, 21]; and low body weight [27].
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The majority of studies examining the risk factors for falling are based on older people living in the community; however, studies of falls in participants with prevalent fragility fractures are relatively scarce despite their high risk for falls and recurrent fractures [1, 9]. In Ontario, Canada, a system-wide Fracture Screening and Prevention Program (FSPP) was established in 2007 [28] to improve the care of people who have had a fragility fracture and to facilitate interventions with the goal of preventing further fractures. About 8000 fragility fracture patients are screened and enrolled in the FSPP each year. Understanding the factors associated with falls in this population is essential to the design of appropriate fall-prevention and treatment strategies. This is an important goal because falling is a condition that should be amenable to prevention, given that there is evidence of preventability, a high rate of morbidity, and high frequency [26], although there are contradictory findings regarding whether falls prevention initiatives reduce injuries or fractures [29]. The purpose of the present study was to examine possible associated factors for being screened at high falls risk in a large fragility fracture population using a provincial database. Specifically, we sought to report the prevalence of fragility fracture patients enrolled in the FSPP who were screened at high falls risk, and to determine the characteristics associated with being screened at high falls risk.
Methods
The study population consisted of fragility fracture patients 50 years of age or older who were screened by Fracture Prevention Coordinators (FPCs) at 35 hospital fracture clinics over a 3.5 year period. To identify individuals with a fragility fracture, FPCs asked each patient how they broke their bone(s). In our Fracture Screening and Prevention Program, we consider a fragility fracture as one that occurs as a result of a fall from standing height or less [30]. We also recognize that some fractures, such as vertebral fractures, occur from no trauma at all, e.g., just bending over to pick something up. Examples of low trauma, or fragility fractures include: slip and fall on snow, ice, or a wet floor; fall out of bed or out of a chair. The FPCs facilitate guideline implementation with respect to care management after a fragility fracture; furthermore, they collect baseline and follow-up survey data for quality assurance purposes on a routine basis. As part of usual care, the FPCs collect patient data using standardized survey instruments on tablet computers, and the data are uploaded to a central repository. The approval for use of the de-identified quality assurance data for research purposes was provided by the Research Ethics Board at St. Michael’s Hospital in Toronto, Ontario (REB# 13–156).
Measures
Outcome
The outcome was based on two screening questions measuring the risk of falling. The first question asked “Have you fallen in the past year besides the fall that may have led to the current fracture(s)?”, and the second question asked “Do you have trouble getting out of a chair or feel unsteady when you walk?” These were adapted from two of three screening items in the STEADI (Stopping Elderly Accidents, Deaths & Injuries) tool from the Centers for Disease Control and Prevention [31]. Patients were considered at high falls risk if they answered “Yes” to either of these screening questions.
Sociodemographic and fracture-related characteristics
Demographic variables included age (categorized as 50–64, 65–79, 80+) and sex (male/female). Living arrangement was grouped into three categories: alone in house or apartment; with spouse, family member or roommate; non-community dwelling (nursing home, other residential facility or other living situation). Fracture location was grouped into five categories; hip, shoulder, wrist, and ankle represent the most commonly reported fracture types, while ‘other’ includes all other fractures which occurred too infrequently to be included in their own categories.
Health-related characteristics
Patients were asked if they had broken another bone since the age of 40 from a simple trip and fall, as a proxy measure for having a history of previous falls resulting in fracture. Alcohol use (drinking 3 or more alcoholic beverages a day) and vitamin D supplementation (yes/no) were also assessed. Fracture Prevention Coordinators also determined whether or not patients had any form of impairment or barrier to completing the questionnaire, including language barrier, or mental/physical impairments. The latter served as a proxy for impaired cognition because we did not specifically measure cognitive deficit in our survey. Low body weight (< 60 kg) [9] was assessed by asking patients to self-report their weight.
Patients were also asked to report if they had ever been told they had any of the following conditions: diabetes, arthritis, hearth disease (stroke, heart attack), high blood pressure, cholesterol, respiratory disease (asthma, emphysema, COPD), and cancer. A chronic disease burden variable was created by counting the number of conditions reported by each patient. The variable was categorized into four groups: 3 or more conditions, 2 conditions, 1 condition, and no condition. For each condition selected, patients were then asked to self-report if they were currently taking any medication for that condition. A variable was created counting the number of medications reported by each patient, irrespective of type, and was categorized into five groups: 4 or more medications, 3, 2, 1, and no medications. The last category included patients who were not diagnosed with any conditions and were therefore not taking any medications, in addition to those who were diagnosed with at least one condition but were not taking medications.
Analysis
Description of sample
Descriptive statistics including frequencies and proportions were calculated for the outcome variable and characteristics or covariates of interest.
Factors associated with being screened at high falls risk
Unadjusted associations between the outcome and variables of interest were examined using logistic regression. A trend test evaluating the association between count of current medications and the outcome was also performed. For this test, the former variable was coded as a continuous measure (0, 1, 2, 3 and 4+ medications) since 833 patients were taking 4 medications, and only 186 were taking more than 4 (ranging from 5 to 7). Given this small number, our continuous measure combines 5–7 medications into the 4+ group. In logistic regression, the Score test is asymptotically equivalent to the Cochran-Armitage trend test when the independent variable is continuous [32].
Multivariable associates of sociodemographic, fracture-related, and health-related characteristics were also evaluated using logistic regression. Low body weight was excluded because of a high level of missing data (nearly 20%). The chronic disease burden variable was also excluded due to potential collinearity with current medication count variable (Pearson correlation coefficient r = 0.87, p < .0001). The variable measuring the count of current medications was retained because it was deemed more important in the falls literature [19‐22]. The size and statistical significance of the effects are reported as odds ratios (OR) and 95% confidence intervals (CI). All analyses were performed using SAS 9.4 [33].
Results
From June 11, 2011 to November 5, 2014, 22,495 patients were screened and examined for eligibility by FPCs; of these, 21,980 were 50 years of age or older and had sustained a fragility fracture (confirmed eligible). In total, 21,869 patients were included in the study and analyzed because they had completed the baseline questionnaire. Patients included in the study who reported a language barrier (n = 1436) or mental/physical impairment (n = 1301) had a proxy complete the baseline questionnaire on their behalf, including all sections of the survey relevant to this study. The descriptive data for the whole sample and for the sample stratified by outcome status (screened at high falls risk) are presented in Table 1. Over one-quarter of the patients were 80 years of age or older, and 83.3% were female. Wrist fractures were the most commonly reported fracture type irrespective of whether or not patients were screened at high falls risk.
Table 1
Characteristics of fragility fracture patients stratified by outcome (screened at high falls risk)
Variable | Total, n (%) | Screened at high falls risk | |
|---|---|---|---|
Yes, n (%) n = 9735 | No, n (%) n = 12,089 | ||
Age, years | |||
50–64 | 8112 (37.1) | 2650 (27.2) | 5455 (45.1) |
65–79 | 8191 (37.5) | 3523 (36.2) | 4651 (38.5) |
80+ | 5566 (25.5) | 3562 (36.6) | 1983 (16.4) |
Sex | |||
Male | 3663 (16.8) | 1626 (16.7) | 2030 (16.8) |
Female | 18,205 (83.3) | 8109 (83.3) | 10,058 (83.2) |
Fracture location | |||
Hip | 2838 (13.0) | 1761 (18.1) | 1064 (8.8) |
Shoulder | 3419 (15.6) | 1614 (16.6) | 1801 (14.9) |
Wrist | 8227 (37.6) | 3077 (31.6) | 5134 (42.5) |
Ankle | 3101 (14.2) | 1204 (12.4) | 1893 (15.7) |
Other | 4284 (19.6) | 2079 (21.4) | 2197 (18.2) |
Living arrangement | |||
Alone in house or apartment | 5591 (25.6) | 2636 (27.1) | 2951 (24.4) |
With spouse, family member or roommate | 14,059 (64.3) | 5584 (57.4) | 8453 (69.9) |
Non-community dwelling | 1486 (6.8) | 1221 (12.5) | 252 (2.1) |
Missing, don’t know, refused | 733 (3.4) | 294 (3.0) | 433 (3.6) |
Alcohol use (more than 3/day) | |||
Yes | 782 (3.6) | 319 (3.3) | 460 (3.8) |
No | 20,962 (95.9) | 9355 (96.1) | 11,565 (95.7) |
Missing, don’t know, refused | 125 (0.6) | 61 (0.6) | 64 (0.5) |
Broke other bone since age 40 from a simple trip and fall | |||
Yes | 6215 (28.4) | 3625 (37.2) | 2579 (21.3) |
No | 15,471 (70.7) | 5982 (61.5) | 9460 (78.3) |
Missing, don’t know, refused | 183 (0.8) | 128 (1.3) | 50 (0.4) |
Taking Vitamin D supplements | |||
Yes | 14,538 (66.5) | 6555 (67.3) | 7957 (65.8) |
No | 6903 (31.6) | 2888 (29.7) | 4003 (33.1) |
Missing, don’t know, refused | 428 (2.0) | 292 (3.0) | 129 (1.1) |
Impairment or barrier | |||
Mental or physical | 1301 (6.0) | 1049 (10.8) | 243 (2.0) |
Language or other | 1436 (6.6) | 671 (6.9) | 757 (6.3) |
None | 19,132 (87.5) | 8015 (82.3) | 11,089 (91.7) |
Low body weight (< 60 kg) | |||
Yes | 5166 (23.6) | 2414 (24.8) | 2746 (22.7) |
No | 12,505 (57.2) | 5384 (55.3) | 7106 (58.8) |
Missing | 4198 (19.2) | 1937 (19.9) | 2237 (18.5) |
Chronic disease burdena | |||
3 or more conditions | 4843 (22.2) | 2919 (30.0) | 1918 (15.9) |
2 conditions | 4258 (19.5) | 2134 (21.9) | 2117 (17.5) |
1 condition | 5329 (24.4) | 2158 (22.2) | 3161 (26.2) |
No condition | 5514 (25.2) | 1538 (15.8) | 3966 (32.8) |
Missing | 1925 (8.8) | 986 (10.1) | 927 (7.7) |
Count of current medicationsa | |||
4 or more | 1019 (4.7) | 686 (7.1) | 332 (2.8) |
3 | 2379 (10.9) | 1375 (14.1) | 1000 (8.3) |
2 | 3874 (17.7) | 1973 (20.3) | 1896 (15.7) |
1 | 5384 (24.6) | 2371 (24.4) | 3003 (24.8) |
0 | 7122 (32.6) | 2270 (23.3) | 4829 (40.0) |
Missing, don’t know, refused | 2091 (9.6) | 1060 (10.9) | 1019 (8.4) |
Overall, 9735 (44.5%) patients were categorized at high falls risk, and 12,089 (55.3%) were not; outcome data were missing for 45 patients. Among those screened at high falls risk, a much higher proportion were non-community dwelling (12.5%) compared to those who were not screened at high falls risk (2.1%). A mental or physical barrier was reported by 10.8% of patients screened at high falls risk, compared with 2.0% of those who were not. Similarly, current use of medications for chronic conditions was more commonly reported by patients screened at high falls risk. Specifically, 14.1 and 7.1% reported using 3 and 4+ medications, respectively. Among patients not screened at high falls risk, 8.3 and 2.8% reported using 3 and 4+ medications, respectively.
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Factors associated with being screened at high falls risk
Factors associated with being screened at high falls risk in unadjusted and multivariable (adjusted) logistic regression analyses are listed in Table 2. In unadjusted analyses, nearly all sociodemographic, fracture-related, and health-related characteristics were significantly associated with the outcome. The odds of being screened at high falls risk was 3.7 times higher for patients 80+ years of age compared to 50–64 year olds, and 7 times higher for those in non-community dwellings compared to patients living with a spouse, family member or roommate. A similarly strong association was observed for patients with a mental or physical barrier, whose odds of being screened at high falls risk was 6 times higher compared to patients with no reported impairments or barriers.
Table 2
Factors associated with being screened at high falls risk in unadjusted and multivariable (adjusted) logistic regression analyses
Variable | Unadjusted OR (95% CI) | Adjusted OR (95% CI) |
|---|---|---|
Age, years | ||
50–64 | 1.00 | 1.00 |
65–79 | 1.56 (1.46–1.66) | 1.14 (1.06–1.23) |
80+ | 3.70 (3.44–3.97) | 1.72 (1.57–1.88) |
Sex | ||
Male | 1.00 | 1.00 |
Female | 1.01 (0.94–1.08) | 1.06 (0.97–1.15) |
Fracture location | ||
Hip | 2.76 (2.53–3.02) | 1.75 (1.58–1.95) |
Shoulder | 1.50 (1.38–1.62) | 1.26 (1.15–1.39) |
Wrist | 1.00 | 1.00 |
Ankle | 1.06 (0.98–1.16) | 1.18 (1.07–1.29) |
Other | 1.58 (1.47–1.70) | 1.35 (1.24–1.47) |
Living arrangement | ||
Alone in house or apartment | 1.35 (1.27–1.44) | 1.20 (1.11–1.28) |
With spouse, family member or roommate | 1.00 | 1.00 |
Non-community dwelling | 7.33 (6.38–8.43) | 3.42 (2.87–4.07) |
Alcohol use (more than 3/day) | ||
Yes | 0.86 (0.74–0.99) | 0.99 (0.84–1.17) |
No | 1.00 | 1.00 |
Broke other bone since age 40 from a simple trip and fall | ||
Yes | 2.22 (2.09–2.36) | 1.88 (1.75–2.01) |
No | 1.00 | 1.00 |
Taking Vitamin D supplements | ||
Yes | 1.14 (1.08–1.21) | 0.97 (0.90–1.03) |
No | 1.00 | 1.00 |
Impairment or barrier | ||
Mental or physical | 5.97 (5.18–6.89) | 2.51 (2.09–3.01) |
Language/other | 1.23 (1.10–1.37) | 0.97 (0.85–1.11) |
None | 1.00 | 1.00 |
Low body weight (< 60 kg) | ||
Yes | 1.16 (1.09–1.24) | – |
No | 1.00 | |
Chronic disease burdena | ||
3 or more conditions | 3.92 (3.61–4.26) | – |
2 conditions | 2.60 (2.39–2.83) | |
1 condition | 1.76 (1.62–1.91) | |
No condition | 1.00 | |
Count of current medicationsa | ||
4 or more | 4.40 (3.83–5.07) | 3.42 (2.95–3.97) |
3 | 2.93 (2.66–3.22) | 2.28 (2.05–2.53) |
2 | 2.22 (2.05–2.40) | 1.72 (1.57–1.88) |
1 | 1.68 (1.56–1.81) | 1.37 (1.26–1.48) |
0 | 1.00 | 1.00 |
In terms of current use of medications for chronic conditions, taking a greater number of medications was strongly associated with being screened at high falls risk (Table 2). This was further evaluated using a trend test; specifically, the Score test was significant (p < .0001), and we found an OR of 1.44 (95% CI: 1.40–1.47) (results not shown). This indicates that for every increase of one in the number of medications used, there was a 44% higher odds of being screened at high falls risk.
In the multivariable logistic regression model containing all factors of interest, we found that most variables had similar effects as in unadjusted analyses and retained statistical significance, except for alcohol use and taking vitamin D supplements. We observed a reduction in the strength of associations between some key factors and the outcome; however, these variables were still strongly associated with the outcome. Specifically, being 80+ years of age (vs. 50–64 years of age), non-community dwelling (vs. living with spouse, family member or roommate), having a mental or physical impairment (vs. none), and taking multiple medications, all remained strongly associated with being screened at high falls risk. For the latter variable, there was a statistically significant association where patients taking more medications had a higher odds of being screened at high falls risk (Table 2).
Discussion
As part of our large-scale provincial fracture screening program, using an adapted tool (STEADI) to screen for fall risk revealed that nearly 45% of our population of fragility fracture patients were screened at high falls risk. A cohort study in the United States reported nearly 38% of patients with osteoporosis were at high fall risk based on an adapted version of the STEADI algorithm [34], but we have not found a similar study focused solely on fragility fracture patients. Other studies have reported fall risk using STEADI or STEADI-related measures of fall risk in older populations, with findings ranging from 21.3% [35] to 35% at a high risk of falls [36]. However, the authors of these other studies did not indicate whether or not study participants had sustained fragility fractures.
Our results confirm that being 80+ years of age (vs. 50–64 years) is related to being screened at high falls risk. The role of advanced age in falls is a well-established finding in the literature [2, 13, 14]. However, the strength of the association between older age and being screened at high falls risk in our data was lessened in multivariable analyses. This is possibly due to the effects of fracture location in the model, specifically hip fractures, which are known to be more common amongst older individuals and be associated with subsequent falls [37, 38]. One of our unexpected findings was that sex was not statistically significantly associated with being screened at high falls risk. This is consistent with Smee et al. [39] who found that sex was not related to fall risk in community-living older adults. Similarly, Dewan et al. [1] reported that sex was not associated with subsequent falls or fragility fractures in their cohort of older patients with distal radius fracture. This was however contradictory to previous studies which reported that women were at greater risk for falls and fall injuries [2, 15].
The odds of screening at high falls risk was nearly 3.5 times higher for patients in non-community dwellings (vs. those living with a spouse, family member or roommate), even when controlling for other variables (e.g., mental or physical impairment). Rubenstein [7] reported that persons living in long-term care institutions have much higher rates of falls, and that 10–25% of such falls result in serious injuries (e.g., fracture or laceration). Furthermore, Todd and Skelton [22] reported that nursing home residents with diagnosed dementia fell twice as often as those with normal cognition. While not examined among nursing home residents specifically, our results indicate that the odds of screening at high falls risk was over 2.5 times higher in patients with mental or physical impairment compared to those without any impairment. This strong association remained even after controlling for related factors such as age, living arrangement, and medication use. Not surprisingly, cognitive impairment is strongly associated with an increased risk of falling in the literature [3, 20, 22].
Finally, we found that there was a strong association between taking more medications for chronic conditions and being screened at high falls risk. When compared to patients not taking any medications, the odds of screening at high falls risk was 3.4 times higher for those taking 4+ medications in adjusted analyses. Others have similarly found that the risk is increased significantly if a person is on more than four medications, irrespective of type [19‐22]. Indeed, a review by Zia et al. [40] concluded that polypharmacy was a significant factor in the risk of falls, regardless of whether it was defined as ≥4 or ≥ 5 medications, or whether or not fall-risk-increasing drugs were used. Furthermore, Helgadóttir et al. [17] found that an increasing number of medications increased risk of fall injury in a population-based study of Swedish people 65 years and older. However, the association was partly explained by age and sex, and there was no clear dose-response relationship.
Strengths and limitations
Strengths
This study investigated the factors associated with being screened at high falls risk in fragility fracture patients using a large, provincial database. This was an important strength as our study was based on a multicenter cohort of individuals representing the fragility fracture population in Ontario. Our work addresses a gap in the literature by focusing on participants with prevalent fragility fractures who screened positive for high falls risk. Another strength is our outcome measure, which was adapted from a validated and commonly used tool (STEADI) to measure fall risk [34, 41, 42].
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Limitations
A limitation of this study was that our analysis was cross-sectional. We therefore cannot make any statements regarding causality or in terms of predicting the subsequent risk of falling in our fragility fracture population. However, this may be an area for future research as our provincial program is in the process of incorporating actual fall events in the follow-up questionnaires administered as part of the FSPP. This could allow us to examine the prevalence of falls at follow-up and to assess risk factors predicting subsequent falls in fragility fracture patients. Furthermore, the variable measuring impairment or barrier combines mental and physical impairment into one category, because this is how the question was asked in the questionnaire. This variable was meant to be a proxy for impaired cognition; however, we do not know the extent to which patients in this group actually had a mental impairment, or even the type of mental impairment. Nonetheless, we found the strong association between mental or physical impairment and being screened at high falls risk was comparable to other studies, providing some evidence that our variable was a good proxy for cognitive impairment. Finally, participants had to recall if they had fallen in the past year, besides the fall that may have led to the current fracture(s). This type of information is subject to recall bias [43, 44], which can lead to underestimation of risk. However, as indicated in their evidence review and recommendation statements, the US Preventive Services Task Force found that history of falls was the most commonly used item in risk assessment tools, and it consistently identified persons at high risk for falls [45].
Conclusions
We found that a large proportion (nearly 45%) of prevalent fragility fracture patients in a provincial multicentre cohort was identified as being screened at high falls risk. Living in a non-community dwelling, and taking 4 or more medications were the strongest independent variables associated with being screened at high falls risk. These are potentially modifiable characteristics that should be considered when assessing falls risk in fragility fracture patients, and particularly when designing interventions for preventing subsequent falls in this population. These may include regular medication reviews, such as withdrawal of cardiovascular medications [40]. Although there is little evidence of a reduction in the risk of falls with the withdrawal or dose reduction of fall-risk-increasing medication [40], prescriptions for older patients “should be individualized and subject to frequent periodic reviews, while consistently striving to minimize the total number and amount of medications consumed by thepatient” [40]. Interventions that address the social environment for those in nursing homes should also be considered; e.g., staff ratio and staff training [14]. Ongoing work to address the higher risk of falls in the fragility fracture population is warranted, with a particular eye to addressing the needs of more vulnerable patients.
Acknowledgements
The authors gratefully acknowledge the support of Osteoporosis Canada, which implements the.
Ontario Osteoporosis Strategy Fracture Screening Prevention Program (FSPP) on behalf of the Ministry of Health and Long-Term Care. The authors also thank members of the FSPP Evaluation Team for their contributions to the program and its overall evaluation.
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Ethics approval and consent to participate
All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee (Research Ethics Board at St. Michael’s Hospital in Toronto, Ontario, REB# 13–156) and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. Informed consent was not obtained from all individual participants included in the study. Rather, we obtained approval for use of de-identified quality assurance data for research purposes from the Research Ethics Board at St. Michael’s Hospital in Toronto, Ontario (REB# 13–156).
Consent for publication
Not applicable.
Competing interests
NKR, DEB, RS, EB, TI, DL, JW, RJ, and JEMS declare that they have no competing interests.
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