Physical function assessment of older adults with lower body fractures at 3 months post-discharge from hospital.

BACKGROUND AND
PURPOSE: Physical function assessment can be performed to assess functional mobility among older adults, especially after a traumatic incident such as lower body fracture (LBF). The objective of this study was to evaluate physical function of older patients with LBF after 3 months of discharge from the hospital. PATIENTS AND METHODS: A total of 89 patients were followed up at the discharge phase. Four independent variables were tested: age, sex, type of fracture, and use of a walking aid before fracture. Mobility and strength were assessed with the Timed Up and Go (TUG) test and hand-grip strength (HGS) test, respectively.
RESULTS: The majority of the patients were ≥65 years old (64%), female (61.8%), of Chinese ethnicity (50.6%), and had a hip fracture (51.7%). The mean time for TUG test was 26.11 seconds, while mean HGS was 19.02 kg. We found significant differences in TUG test scores with respect to all independent variables tested: age (P=0.026), sex (P=0.011), fracture type (P<0.001), and use of a walking aid before fracture (P=0.004). Significant differences were also detected in HGS test scores with respect to all independent variables tested: age (P<0.001), sex (P<0.001), fracture type (P<0.001), and use of a walking aid before fracture (P=0.035).
CONCLUSION: Increasing age, female sex, having a hip fracture, and use of a walking aid before fracture predicted reduction in the physical function and strength among older adults with LBF.

Introduction

The proportion of older adults is increasing in most countries. In Malaysia, the percentage of old-age people (>65 years old) is expected to rise from 5% (2010) to 14.5% (2040). In 2016, the total fertility rate was reported as below the replacement level (1.9 babies born per woman throughout her reproductive life).1 This indicates that the population continues to grow older rapidly as fertility rates have fallen to very low levels and people tend to live longer.2 However, living longer does not mean that they are living healthier. Noncommunicable diseases are the main health concern among the older population worldwide. Osteoporosis has become one of the most common noncommunicable diseases among the aging population.3 It is characterized by low bone mass and structural deterioration of bone tissue, leading to bone fragility and ultimately fracture. Osteoporosis leads tô9 million fractures annually worldwide.4 Osteoporotic fractures may affect any part of the human skeleton except the skull. Parts such as the proximal femur (hip), distal forearm, lumbar vertebrae, and ribs are the most common sites of osteoporotic fractures.5 It has been estimated that >40% of postmenopausal women and ~25%–33% of men aged 75 years and above will eventually experience osteoporotic fractures.5,6 Among all the osteoporotic fractures, hip fracture has received the most attention. There were many reports on the personal burden of this fracture, especially in terms of limited mobility.7,8

Hip fracture is one of the lower body fractures, which can be defined as any fractures that occur at the lower body parts including pelvis, lumbar vertebrae, upper leg, lower leg, ankle, foot, and toe.9 A hip fracture is often caused by a fall which may be associated with poor postural control or reduced muscle strength in the lower extremities.10,11 Asymmetric vestibular function in the older adults may significantly contribute to falls and hip fracture.12

Physical function assessment is important for individual patients and the health care system.13,14 According to Jarnlo and Thorngren, hip fracture patients were associated with a lower mean speed at 2 years after the fracture compared to their control group.15 Additionally, it has been noted that at 12 months postfracture, <50% of hip fracture patients return to pre-fracture physical function.16,17 There are many important predictors for return to baseline physical function such as cognitive status, surgical interventions, age, other comorbid conditions, and course following surgery.18–21

Timed Up and Go (TUG) test is a common method to assess functional mobility among older adults in geriatric clinics. The test measures speed during several functional movements, such as standing up, walking, turning, and sitting down. The test is convenient to be performed in clinical settings with limited training and equipment required.22 This test is an integral measure of gait speed and balance, together with fall risk, which are the major determinants of osteoporotic fractures in clinical settings.23,24 Apart from TUG test, handgrip strength (HGS) test is recommended for the measurement of muscle strength and considered the simplest method for assessment of muscle function in clinical settings.25 In addition to assessing the strength of the upper extremities, HGS test has co-relation with the measurement of lower body strength26 and this indicates that the strength of both upper and lower body parts can be evaluated. HGS measurement is a reliable, valid, and feasible screening tool for the measurement of strength in multiple population.27 Jamar dynamometer which is a commonly used tool for HGS test is considered as a device with excellent reliability and is easy to use and recommended by several societies such as the American Society of Hand Therapists and Brazilian Society of Hand Therapists.28 Muscle function measured by this test is related to muscle mass, which is a strong determinant of bone size,29 bone volumetric density,30 and associated bone strength. Thus, an individual with decreased muscle strength is at an increased risk of fracture.

Although hip fractures represent less than half of osteoporotic fractures in the older population, there were many studies which reported solely on hip fracture. Lower body fractures have been reported to represent about one-third of all types of bone fractures.31 Thus, in our study, we included all fractures of the lower body parts and sought to assess the physical function of the patients with lower body fracture at 3 months post-discharge using TUG and HGS tests. In addition, we aimed to determine the relationship between age, sex, type of fracture, and use of a walking aid before fracture and TUG and HGS test scores. The relationships between the variables chosen may generate useful reference for clinicians in treating the patients with lower body fracture during their rehabilitation. To the best of our knowledge, this is the first detailed study to evaluate the physical function of patients with lower body fracture after discharged from hospitals in Malaysia. Other than that, this study is important due to multiracial population in Malaysia, in which the results might be different from other similar studies. Therefore, the health care system would gain benefit in improving their planning and management of patients with lower limb fracture specifically for the population in Malaysia.

Patients and methods

Study design and patients

This study was part of a vast project “Malaysia Bone Health and Osteoporosis Study” (MALBONES) which was conducted from February 2014 to February 2016. Patients admitted for lower body fractures to orthopedic wards in two hospitals in Klang Valley, Malaysia (Hospital Canselor Tuanku Muhriz [HCTM] and Hospital Kuala Lumpur [HKL]) were included based on the following inclusion criteria: 1) aged 50 and above, 2) Malaysian citizenship, and 3) any type of lower body fracture (hip, upper leg, knee, lower leg, ankle, and foot). Meanwhile, patients with psychiatric problems, Alzheimer’s disease, dementia, or pathological fractures other than osteoporosis, cancer patients, patients living outside the Klang Valley, and patients with hearing and speech problems were excluded from this study. The bases for exclusion criteria were inability to follow instructions well, to avoid bias, and to reduce dropout rate during the follow-up visit. Data collection for this study was divided into three phases: the pre-fracture phase, ward admission phase, and 3 months post-discharge phase. However, physical function assessments could only be carried out during the post-discharge phase. The minimum sample size was determined by using Green formula, N=50+8(m), where N represents “total participants of study” while m represents “independent variable”.32 In our study, four independent variables (age, sex, types of fracture, and use of a walking aid before fracture) were chosen as they were frequently used in previous physical assessment studies.24,33,34 Thus, after inputting all the values in the formula, the minimum sample required was 82 participants. By considering 30% dropout rate, the minimum sample size was calculated to be 107 participants. Written informed consent was obtained from all participants. The local research committee of Universiti Kebangsaan Malaysia and the Research Committee Kuala Lumpur Hospital (IRC-IIR/2014/011/156) had given approvals to conduct this study. This study was conducted under the guidance of the Declaration of Helsinki.

Procedures

All information related to demographic (sex, age, ethnicity, anatomy of fractured parts, fracture type) and clinical criteria (number of comorbidities, family history of osteoporosis, history of fracture) was collected while the patients were in the ward. Mobility status of the patients before and after fracture was also recorded. For assessing pre-fracture mobility status, patients were interviewed at the ward and required to report whether they have used walking aid or not before the fracture incident. The functional mobility assessment of the patients was performed with TUG test, which measures the patients’ ability to stand up from a 44 cm high armless chair, walk 3 m, turn, walk back, and sit down.22,35,36 The TUG test was carried out in postfracture patients who could walk with or without a walking aid. Patients with walking aid could use the walking aid during the test. Patients who were unable to stand on their own and need help to get up were considered unable to perform this test and were excluded. The time needed to perform the test was a TUG test score and recorded in the unit of seconds.37 Each patient had one trial prior to performing the test, and any sort of human assistance was not permitted.

As for HGS test, only the dominant hand was tested, which gave higher readings than the nondominant hand38 and because assessing both hands might take more time and energy of the patients and researcher. Patients who were unable to sit properly and perform this test according to the procedure were not allowed to participate. Jamar Plus hand dynamometer (S.I. Instruments, Hilton, SA, Australia) which was set at the second position was used for this test. The second position has been assumed to be the most reliable and consistent position and is the position advocated for routine use.25 During the test, the patient was asked to lean on a chair and sit up straight. Then, the patient was asked to hold the Jamar Plus hand dynamometer with the elbow at 90° flexion. After the patient was ready with this position, he/she was required to grip as hard as possible and the first reading was recorded. The patient was then asked to perform this test twice, and the highest score was taken as the final score for handgrip strength, recorded in the unit of kilogram. Prior to the second test, the patient was allowed to rest for 1 minute.25,39–41

Statistical analyses

Results were analyzed using SPSS software (version 22). Descriptive analysis was used to determine the frequency and percentage of mobility status of the patients, as well as to determine the minimum, maximum, and mean values of TUG and HGS test scores. The Mann–Whitney U test was conducted to determine significant difference between independent variables and the TUG test score, by means of median (IQR) value. The independent samples t-test was used to determine significant difference between independent variables and the HGS test score, which was expressed as mean ± SD. The level of significance was taken as P<0.05.

Results

At the initial phase (pre-fracture and ward admission), a total of 129 patients were recruited. At the final phase (3 months post-discharge), a total of 89 patients were left for the 3 months follow-up visit. The demographic data of the patients are shown in Table 1. Of the 40 patients who dropped out, 14 were dead, 11 withdrew from the study, and 15 could not be contacted (Table 2).

Table 1

The characteristics of the patients who remained after follow-up in this study

Characteristics	Post-discharge phase, n=89, N (%)
Sex
Male	34 (38.2)
Female	55 (61.8)
Age (mean ± SD)	69.62±10.68
Age group (years)
50–64	32 (36.0)
≥65	57 (64.0)
Ethnicity/race
Malay	33 (37.1)
Chinese	45 (50.6)
Indian	11 (12.4)
Number of comorbidities
0–2	62 (69.7)
≥3	27 (30.3)
Family history of osteoporosis
Yes	7 (7.9)
No	82 (92.1)
History of fracture
Yes	20 (22.5)
No	69 (77.5)
Anatomy of fracture parts
Hip and femur	51 (57.3)
Knee and lower leg	18 (20.2)
Ankle and foot	20 (22.5)
Fracture type
Hip fracture	46 (51.7)
Other than hip fracture	43 (48.3)

Note: Adapted from Ibrahim NI, Ahmad MS, Zulfarina MS, et al. Activities of daily living and determinant factors among older adult subjects with lower body fracture after discharge from hospital: a prospective study. Int J Environ Res Public Health. 2018;15(5):1002. Creative Commons license and disclaimer available from: http://creativecommons.org/licenses/by/4.0/legalcode.91

Table 2

Frequency and percentage of patients who succeeded for follow-up and causes for dropouts in the study

Follow-up status (3 months after discharge)	Frequency, N	Percentage (%)
Successful for follow-up visit	89	69.0
Died	14	10.9
Withdrawn from the study	15	11.6
Unable to contact	11	8.5

Note: This table was in reference to Ibrahim et al.91

Frequency and percentage of walking aid status

During pre-fracture phase, 32 (24.8%) patients used walking aids and 97 (75.2%) did not use walking aids. However, after 3 months of discharge from the hospital, the number of patients who used walking aids increased to 67 (75.3%), while the number of patients who did not use walking aids decreased to 22 (24.7%).

TUG and HGS test scores

The TUG and HGS tests were performed on patients after 3 months of hospital discharge following admission for lower body fractures. The TUG test was performed according to the procedure for 57 patients who could walk on their own, while HGS test was performed for 82 patients who could perform the test according to the procedure. The mean scores of TUG and HGS tests were 26.11 seconds and 19.02 kg, respectively. The minimum, maximum, and mean values of TUG and HGS test scores are shown in Table 3.

Table 3

The minimum, maximum, and mean values of TUGand HGStest scores

Score values	TUG test score, n=57	HGS test score, n=82
Minimum	9.0 seconds	2.0 kg
Maximum	73.0 seconds	48.7 kg
Mean	26.1 seconds	19.0 kg

Notes: Thirty-two patients were excluded from the TUG test as they were unable to stand on their own and needed help to get up. Seven patients were excluded from the HGS test as they were unable to sit properly and perform this test.

Abbreviations: HGS, handgrip strength; TUG, Timed Up and Go.

Relation between TUG and HGS test scores and independent variables (age, sex, types of fracture, and use of a walking aid before fracture)

The TUG test scores showed significant changes with respect to all independent variables: age (P=0.026), sex (P=0.011), types of fracture (P<0.001), and use of a walking aid before fracture (P=0.004). Older patients (≥65) needed more time to complete this test with a median (IQR) value of 23.75 (22) seconds compared to middle-aged patients (50–64) with 18.50 (11) seconds. In terms of sex, female patients showed a higher TUG test score with a median (IQR) of 23.20 (19) seconds compared to male patients with 17.38 (11) seconds. In terms of types of fracture, hip fracture patients required more time to complete this test compared to patients with non-hip fracture with median (IQR) values of 30.43 (29) and 16.61 (5) seconds, respectively. In terms of the use of a walking aid before fracture, patients who used walking aid before fracture required more time to complete this test than the patients who did not use walking aid before fracture, with median (IQR) values of 45.53 (39) and 19.47 (12) seconds, respectively.

Significant changes were also found in the HGS test scores with respect to all the independent variables: age (P<0.001), sex (P<0.001), types of fracture (P<0.001), and use of a walking aid before fracture (P=0.035). Middle-aged category showed higher mean scores compared to older category with a mean score of 25.34±10.22 and 15.18±7.11 kg, respectively. In terms of sex, male had a higher mean score with 26.18±9.37 kg, compared to female with a mean score of 14.20±6.47 kg. Meanwhile, the mean score of HGS test for hip fracture patients was lower with 15.12±7.82 kg, compared to patients with non-hip fracture with a mean score of 22.74±9.97 kg. In terms of walking aid use before fracture, patients who used walking aid had a lower mean score with 14.92±7.41 kg compared to patients who did not use walking aid with a mean score of 20.26±10.03 kg. Descriptive statistics according to independent variables and data of TUG test score, HGS test score, and the independent variables are tabulated in Table 4.

Table 4

Descriptive statistics according to independent variables and data of TUG test scores, HGS test scores, and the independent variables

Independent variables	TUG test, n=57			HGS test, n=82
	N (%)	Median (IQR) (seconds)	P-value	N (%)	Mean ± SD (kg)	P-value
Age (years)
50–64	27 (47.4)	18.5 (11)	0.026	31 (37.4)	25.3±10.2	<0.001
≥65	30 (52.6)	23.8 (22)		51 (62.2)	15.2±7.1
Sex
Male	28 (49.1)	17.4 (11)	0.011	33 (40.2)	26.2±9.4	<0.001
Female	29 (50.9)	23.2 (19)		49 (59.8)	14.2±6.5
Fracture type
Hip fracture	26 (45.6)	30.4 (29)	<0.001	40 (48.8)	15.1±7.8	<0.001
Non-hip fracture	31 (54.4)	16.6 (5)		42 (51.2)	22.7±9.9
Use of a walking aid before fracture
Yes	9 (15.8)	45.5 (39)	0.004	19 (23.2)	14.9±7.4	0.035
No	48 (84.2)	19.5 (12)		63 (76.8)	20.3±10.0

Abbreviations: HGS, handgrip strength; TUG, Timed Up and Go.

Discussion

In our study, more than half of the patients needed to use walking aid for mobility following lower body fracture incidents. Hip fracture, which was recorded with a higher number of cases compared to other lower body fractures, was associated with high usage of walking aids after discharge from the hospital. According to Nygard et al, most hip setting with a wheeled frame. Over time, the patients changed to non-wheeled walking aids and about 40% of the patients had not returned to their pre-fracture mobility status.42 In the current study, the percentage of patients who used walking aid increased from pre-fracture phase (24.8%) to postfracture phase (75.3%). This was parallel with the results of Laufer et al which showed that at pre-fracture phase, only 18 hip fracture patients needed to use walking aids. During the first phase (3 weeks postoperation) and second phase (3 months postoperation), all the 44 patients (100%) needed to use walking aids. Eventually at the third phase of the study (2 years postoperation), 42 patients still needed to use walking aids.43 This may indicate that hip fracture patients had a high risk of not regaining the pre-fracture mobility status. This agrees with our study in which the percentage of patients who used walking aids was increased from about 25% before fracture to about 75% after fracture.

It is postulated that if fracture stability is maintained, fracture impaction achieved by the weight-bearing phase of locomotion and fixation devices with sliding capabilities may enhance bone healing process.44 Thus, regardless of full or slight application of burden on lower body parts, early ambulation that involves the use of walking aids seems to voluntarily limit loading on the injured limb.45 In older patients, slight application of burden on lower body parts may prevent medical complications that could inhibit healing process.46,47 The increased percentage of walking aid use after fracture in our study may be useful to promote fracture healing. In addition, physicians and physiotherapists should advise older patients to perform physical activity regularly, even light walking, to speed up healing process. Several previous studies had revealed that regular physical activity has been associated with better outcomes in the post-hip fracture period.48,49

TUG is a simple and quick test, requiring no special equipment or training to assess the status of mobility and the risk of falling among the older adults. TUG test is suitable to assess less healthy older people with lower functioning, as well as to predict the ability to go outside alone safely.22,50 A study conducted by Podsiadlo and Richardson showed that health problems among the older adults had an impact on the general mobility status and the TUG test score in particular. In the study, the time taken to complete the TUG test was longer, between 10 and 240 seconds, among older people with various health problems such as vascular cataract, Parkinson’s disease, rheumatoid arthritis, post-surgery following hip, and cerebral degeneration. Podsiadlo and Richardson categorized the TUG test scores into three main groups: <10 (normal), 10–20 (good mobility, can go out alone, and no walking aid required), and 20–30 (problem in mobility, cannot go out alone, and requires walking aid).22 Our present study reported that after 3 months of lower body fracture, the mean TUG test score was 26.11 seconds, which fell into the “problematic, should not be allowed to go outside alone, and requires walking aid” category.

A study conducted by Ibrahim et al on a large sample of 2,084 older patients in Malaysia had established TUG test normative data based on cognitive status, sex, and age. The results showed that patients without mild cognitive problems had a lower mean TUG test score of <14.3 seconds for male and female. Meanwhile, for male and female patients with mild cognitive problems, the TUG test scores were <12.9 and 13.1 seconds, respectively.51 In our study, the mean TUG test score for both sexes with lower body fracture was 26.11 seconds, which was even higher than patients with mild cognitive problems. The longer time taken to complete the TUG test in our study indicated that the lower body fracture had severely affected the mobility and physical functions.

Our results also showed that the time required to complete the TUG test was longer compared to a study conducted among 62 patients undergoing hemiarthroplasty for displaced femoral neck fractures, aged between 55 and 100 years. This Canadian study showed that after 3 months of hemiarthroplasty surgery, the mean TUG test score of the patients was 17.00 seconds. In addition, this study revealed that the optimal threshold for predicting the need for a walking aid at 2 years postoperation was 58 seconds at 4 days and 26 seconds at 3 weeks.52 However, this finding could not be directly compared to the results of our study, since in our study TUG test was performed at 3 months post-discharge and included all types of lower body fractures, whereas the Canadian study had focused on hip fracture alone.

When compared to another study by Zasadzka et al, our study showed a longer mean time to complete the TUG test. The study of Zasadzka et al, which was conducted in Poland among older patients with lower extremity osteoarthritis, reported that older patients aged 60–69 years had a mean TUG test score of 12.9 seconds, while those aged 70–79 years had a mean TUG test score of 19.4 seconds.53 A longer time to complete TUG test was expected in our study as fracture of lower extremities is more serious than osteoarthritis, which might result in much worse condition and mobility status.

Several previous studies showed that a low TUG test score was closely related to low bone mineral density (BMD), increased risks of falling, and increased risk of bone fractures among the older adults.24,54 According to Bischoff et al, normal mobility of older adults aged 65–85 years could be indicated with a TUG test score of <12 seconds. As the mean TUG test score of our study was 26.11 seconds, this may indicate high risks of falling and refracture.55 Hence, these findings should be taken seriously by the community and health professionals in terms of the impacts of lower body fractures on physical and mobility functions of older patients, and precautionary actions should be taken to prevent bone refracture.

Our results showed an association of TUG test score with all independent variables tested: age, sex, types of fracture, and use of walking aid before fracture. Based on several previous studies among the older adults, increasing age was the main factor contributing to lower TUG test score.56–58 In the older adults, muscular weakness, poor balance, and neuromuscular abnormalities decrease mobility and lower the performance in daily activities and physical function.59,60

In our study, female sex showed significantly lower TUG test score compared to male, coinciding with the study of Thompson and Medley which reported that women were slower than men in TUG test (P<0.01) and the difference was much greater when using walking aid (P<0.0001). However, the participants involved were not fracture patients, but community-dwelling older adults using or not using walking aid.61 In addition, there were also other studies conducted among aging adults which showed that female sex had a lower TUG test score than men.24,51,62 However, there was no strong consensus on sex-related findings on TUG test scores, as several other studies found no association between TUG test score and sex.54,63

In terms of the types of fracture, our study showed that hip fracture patients had a significantly lower TUG test score than patients with other lower body fractures. Previous studies on hip fracture patients also coincided with our results, revealing that the types of fracture may influence health outcomes.42,57,58 However, a study conducted by Kronborg et al on hip fracture patients aged 65 years and above did not find any significant difference between the TUG test score and types of fracture.64 Nevertheless, the findings by Kronborg et al must be carefully interpreted as the sample size was small (only 36 patients).

Our study demonstrated the association between the use of walking aid before fracture and the TUG test score. Lusardi et al suggested that the use of walking aid was associated with significantly slower TUG test scores among community-dwelling people aged 66–101 years.33 This was also in accordance with the study of Cook et al which correlated slower performance in the TUG test with the use of walking aids pre- and postfracture.65

HGS test is a recommended assessment technique for the measurement of muscle strength and is the simplest method for clinical assessment of muscle function. As an assessment measure, HGS test has been shown to have predictive validity and low values are related with falls,66 disability, impaired health-related quality of life,67 and increased mortality.68,69 Grip strength can be measured quantitatively using a hand dynamometer. In our study, we used Jamar hand dynamometer which was set at the most reliable position (second position) for all participants. Handle positions 1 and 5 have been found to be significantly less reliable than the other positions, but for people with very small hands, position 1 may be appropriate.25

Several previous studies conducted among older adults revealed that lower HGS test scores were closely related to the decline in physical, social, and daily activities. In addition, low HGS test scores were also associated with low BMD, higher risk of falling, osteoporosis, and fragile bone fractures.70–75 The mean HGS test score found in our study at 3 months post-discharge was 19.02 kg, which was higher than a score of 14.50 kg reported by Taha and Sulaiman. The latter study was conducted among healthy older men and women aged 60–83 years in Malaysia with a limited sample size of only 30 subjects.76 Lam et al attempted to establish a normative data for HGS test among Malaysians aged >60 years without neurological conditions. They reported a higher mean HGS test score compared to our HGS test mean score. The mean HGS test scores for both sexes in urban area were 24.4 and 21.8 kg for the right- and left-hand side, respectively.77 Our study only tested the HGS of the dominant hand of the participants with lower body fractures. This might contribute to the different mean HGS scores.

There were statistically significant differences in the HGS test scores for all the independent variables tested in our study (age, sex, fracture type, and use of a walking aid before fracture). The HGS test score of older age category was lower than middle age category, which coincided with several previous studies. This indicated that age was a determinant factor for HGS test scores.78–81 The aging process is associated with deteriorations in functional system (deficits in balance and strength performance), neural system (loss of sensory/motor neurons), muscular system (particularly type II muscle fibers atrophy), and bones (eg, osteoporosis), which may contribute to reduction of HGS test score in older adults.82

In addition, our study was in line with several previous studies that showed sex as an important factor affecting the HGS test score. This was expected due to physiological variations, with female having significantly lower mean HGS test score compared to male.78,80,83 In general, male have consistently higher HGS test score compared to female throughout life, due to higher levels of androgenic hormones, greater muscle mass,84,85 and greater height and weight.78,86

In our study, the mean HGS test score for hip fracture patients was significantly lower than patients with other fracture types. This might be due to the fact that older population were prone to have fracture at low BMD-prone area such as the hip, proximal humerus, and vertebrae.87 According to Serdaroğlu Beyazal et al, HGS test score was significantly correlated with BMD, as postmenopausal women with osteoporosis had a lower HGS test score than postmenopausal women with normal BMD.88

According to previous studies, mobility problems in older adults were closely associated with low HGS test score. The presence of frailty and other age-related conditions such as sarcopenia and osteoporosis may worsen mobility and strength difficulties in older adults and contribute to low HGS test score.71,89,90 This was in line with our study as the dependency on walking aids before fracture was significantly associated with low HGS test score measured at 3 months post-discharge.

This study has several limitations. First, the follow-up period of 3 months for TUG and HGS assessments seems to be quite short. Ideally, the patients should be followed up at longer periods to have better assessments for reflections of mobility and strength after lower body fracture. In addition, the data on the walking aid status should be collected timely, as this may reflect the patients’ condition after the fracture. The second limitation is regarding the tests used for statistical analysis. A multivariant regression is required to control the other potential confounding factors. However, due to the dropouts and the strict procedure of both tests, we managed to obtain a limited sample size. The limited sample size did not fit with the multivariate approach which may affect the result interpretation of the constructed model. Alternatively, we performed nonparametric (Mann–Whitney U test) and parametric (independent samples t-test) tests to determine the significant differences. Preferably, a higher dropout rate for sample size calculation needs to be estimated to prevent this issue. For future studies, we will address these issues carefully.

Conclusion

This was the first study on TUG and HGS assessments of older patients with lower body fractures in Malaysia. Age, sex, types of fracture, and use of a walking aid before fracture could influence the physical function and strength of fracture patients. This could provide useful reference for the clinicians, researchers, and the community involved in the rehabilitation and treatment of older fracture patients in Malaysia and other developing countries with similar demographic profiles. Even though the outcomes can be predicted based on several previous research, this study was performed to confirm the outcome for the Malaysian population due to differences in demographic, socioeconomic, and lifestyle aspects, and thus to improve the strategy for rehabilitation among our population. In the future, this study might contribute to the implementation of patient-centered discharge planning (ie, individualized discharge plans) instead of the routine discharge care that is currently practiced in many hospitals.