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Vol. 63. Núm. 5.
Páginas 607-612 (octubre 2008)
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Vol. 63. Núm. 5.
Páginas 607-612 (octubre 2008)
Research
Open Access
Evaluation of the Health-Related Quality of Life in Elderly Patients According to the Type of Hip Fracture: Femoral Neck or Trochanteric
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Tânia Maria da Silva MendonçaI, Carlos Henrique Martins da SilvaI, Roberto Sérgio de Tavares CantoII, Nívea de Macedo Oliveira MoralesI,III, Rogério de Melo Costa PintoI,IV, Rogério de Rizo MoralesI,III
I Grupo de pesquisa QVRS, Faculdade de Medicina, Universidade Federal de Uberlândia – Uberlândia/MG, Brazil
II Serviço de Ortopedia e Traumatologia, Faculdade de Medicina, Universidade Federal de Uberlândia – Uberlândia/MG, Brazil
III Neurology Discipline, Faculdade de Medicina, Universidade Federal de Uberlândia – Uberlândia/MG, Brazil
IV Faculdade de Matemática, Universidade Federal de Uberlândia – Uberlândia/MG, Brazil. Phone: 55 34 3235.1514
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OBJECTIVE

To evaluate the effect the type of hip fracture (femoral neck or trochanteric) has on the Health-Related Quality of Life of elderly subjects.

METHODS

Forty-five patients with hip fractures (mean 74.30 ± 7.12 years), 24 with a femoral neck fracture and 21 with a trochanteric fracture, completed the 36-item Short Form Health Survey (SF-36) at baseline and four months after fracture. The Health-Related Quality of Life scores were compared according to fracture type, undisplaced and displaced femoral neck fractures, and stable and unstable trochanteric fractures.

RESULTS

Compared to baseline, all patients scored lower in the physical functioning, role limitation-physical, bodily pain and vitality categories four months after the fracture had occurred. The SF-36 scores for all the scales did not differ significantly between patients with femoral neck versus trochanteric fractures, or between patients with displaced versus undisplaced femoral neck fractures and stable versus unstable trochanteric fractures.

CONCLUSIONS

The mental and physical quality of life of elderly patients with a hip fracture is severely impaired one month after fracture, with partial recovery by the end of the fourth month. The negative impact on the Health-Related Quality of Life did not differ significantly according to fracture type.

KEYWORDS:
Elderly
Falls
Health-Related Quality of Life
Hip fracture
SF-36
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INTRODUCTION

Hip fractures are recognized as one of most serious consequences of osteoporosis, and their incidence has been used as an international index of the frequency of osteoporosis.1 Most hip fractures occur after falls, and are a considerable burden to the health care system through their association with increased mortality and morbidity.2,3 In Brazil, around 100,000 hip fractures occur annually according data from DATASUS, a Brazilian public health service. The global senior-citizen population that has experienced a hip fracture is set to reach 6.3 million in 2050.2,4 Hip fractures will then be one of the greatest challenges for society and health systems.2,3

Elderly patients’ recovery after hip fracture is traditionally evaluated by the presence of surgical complications,5 and by the magnitude of functional limitations.5–8 The proportion of elderly people who experience immobility or functional dependency to accomplish the activities of daily life rises over a period of one to two years after the hip fracture.9

Recently, there has been growing interest in investigating the effects of hip fractures and their treatment on the quality of life as perceived by the elderly patient, because knowing which aspects are the most compromised could improve health care interventions and public resource allocation.10 The assessment of the Health-Related Quality of Life (HRQOL) can also complement conventional outcome measures.11

Studies have shown an impairment in the quality of life in elderly subjects with a hip fracture in both the physical and psychosocial domains.4,8–16 HRQOL in elderly people suffering hip fractures has been evaluated at different time points during rehabilitation, and a considerable decline in HRQOL is shown during the initial phase after fracture.8–16 Between the third and fourth months after the fracture, partial recovery is observed in the physical and psychosocial factors. 9–14,17,18 However, these physical and psychosocial aspects do not fully recover, thereby perpetuating the negative effects of hip fracture on the HRQOL.8–13,15–16,19–21

Although there are substantial differences in the pathogenesis between femoral neck and trochanteric hip fractures, studies that have previously investigated the prognostic role of the hip type fracture in functional recovery have produced conflicting results.22–24 Moreover; possible differences in elderly patients’ quality of life according to the type of hip fracture have not been assessed.

The aim of this study was to determine the impact of hip fractures on HRQOL in the Brazilian elderly population, and to ascertain whether there are differences in the HRQOL according to the type of fracture.

METHODSStudy design and patients

Between June 2005 and January 2006, patients admitted for hip fracture to a university hospital in Uberlândia, Brazil were recruited for this study. The inclusion criteria were: aged 60 years or older, hospitalization due to hip fracture, surgery for either internal fixation or arthroplasty, absence of cognitive dysfunction (assessed by applying the mini-mental state examination), independent living (not institutionalized), and hindered walking capability before the fracture. Patients with major trauma, malignancy and rheumatoid arthritis, and other causes of pathologic fractures were excluded. The study was approved by the local research ethics committee, and written informed consent was obtained.

Procedures

The same investigator interviewed and evaluated all patients using a standard protocol within 48 hours after surgery. Social, demographic and residence data were obtained. The type of fracture was analyzed and recorded as a femoral neck fracture or a trochanteric fracture. Femoral neck fractures were classified as undisplaced (Garden I and II), or displaced (Garden III or IV), and trochanteric fractures as stable or unstable.

Cognitive status was assessed by applying the mini-mental state examination, which results in a score between zero and 30.25 Only patients with scores of 22 or above were included in the study.

The SF-36 was applied to the patient group within 48 hours after surgery (baseline data) and four months after admission to hospital, using a face-to-face interview.

Assessment of quality of life

HRQOL was measured using the Brazilian version of the 36-item Short Form Health Survey (SF-36).26 The SF-36 is a generic quality of life instrument, which contains 36 items that measure eight physical and mental dimensions of health: “physical functioning”, “role limitations due to physical functioning”, “bodily pain”, “general health”, “role limitations due to emotional problems”, “vitality”, “mental health”, and “social functioning”. Scores on each scale range from 0 to 100. A score of 100 indicates the highest health rating. The internal consistency reliability of the SF-36 was verified.

Statistical methods

The sociodemographic and clinical features of the patients were recorded through descriptive statistical analysis. Pearson’s chi-square test was used to compare the number of years of education and family income for the patient group according to the type of fracture.

The HRQOL was analyzed by the Friedman test ant then, with Dunn’s post-hoc test considering dependence relationships among baseline and the first and fourth months, without taking the type of fracture into account. The Mann-Whitney test was used to compare the HRQOL among patients with femoral neck fractures (unsdisplaced versus displaced) and patients with trochanteric fractures (stable versus unstable) at baseline and at the fourth month after surgery.

The independent-samples t test was used to compare the HRQOL among the patients with femoral neck and trochanteric fractures at baseline and at the fourth month after the fracture.

The reliability of the internal consistency of SF-36 was calculated for each domain using Cronbach’s alpha coefficient. Values above 0.7 in the group comparison were considered as adequate.27

RESULTS

Of the 80 patients hospitalized for hip fracture during the study period, 12 (15%) died and 23 (28.7%) exhibited cognitive dysfunction (mini-mental state examination score lower than 22). Thus, the final sample consisted of 45 elderly patients aged with mean 74.3 ± 7.12 years (62–92) at the time of fracture. Of the patients, 60% were female and 40% were male. Eighteen (40%) had no formal education. With regard to the fracture type, 24 (53.3%) were diagnosed as having a FNF (femoral neck fracture), and 21 (46.7%) as having a TF (trochanteric fracture) (Table 1).

Table 1.

Sample characteristics of 45 patients with hip fractures

Characteristics  Patients 
Age: average (SD)  74.38 (7.12) 
Hip fracture type
Femoral neck fracture (n)  24 
Garden (I and II)  14 
Garden (III and IV)  10 
Trochanteric fracture (n)  21 
Stable  12 
Unstable 
Years of education: n (%)
Illiterate  18 (40) 
1 to 4 years  6 (13.3) 
5 to 8 years  16 (35.6) 
9 to 11 years  4 (8.9) 
>11 years  1 (2.2) 
Cohabitation: n (%)
Family  28 (62.2) 
Alone  17 (37.8) 
Retired: n (%.)  34 (75.6) 

There were no significant differences in the demographic or clinical characteristics of patients with FNF versus those with TF by Pearson’s chi-square test. All of the patients were submitted to surgery 2.1 ± 0.7 days after the hip fracture. Of the 24 (53.3%) subjects with FNF, 14 (31.1%) had received internal fixation, and 10 (22.2%) received arthroplasty. The average length of the hospital stay was 10.1 ± 5.26 days for the FNF patients and 11.7 ± 7.87 days for the TF patients. The mean number of medications taken daily was 3.7 ± 1.06, and 64.4% of the patients had reported at least one fall over the past year.

The internal consistency reliability for all the SF-36 scales was adequate and Cronbach’s alpha coefficient ranged from 0.70 to 0.91.

Compared to the baseline, patients had a significantly lower score in the physical functioning, role limitation-physical, bodily pain and vitality categories at four months after fracture (Table 2).

Table 2.

SF-36 scores (median and percentiles) in patients with hip fractures at baseline, one month and four month follow-up

Scales  Baseline median (25th/75th)  One month median (25th/75th)  Four month median (25th/75th) 
Physical functioning  65a (37/85)  0b (0/0)  51c (45/56) 
Role limitation - physical  50a (0/100)  0b (0/0)  20b (10/25) 
Bodily pain  47a (35/72)  30b (12/61)  0c (0/10) 
General health  80a (50/90)  70a (50/87)  55a (45/67) 
Role limitation - emotional  100 a (33/100)  100a (16/100)  100a (100/100) 
Vitality  65a (42/85)  40b (30/65)  80c (55/90) 
Mental health  60a (40/84)  60a (28/74)  60a (45/75) 
Social functioning  75a (37/100)  25b (0/50)  68a (52/74) 

Values in a row with the same superscript letter do not differ statistically (p<0.05) at the 5% probability level according to the Friedman test with the Dunn’s post-hoc test

The HRQOL according to the SF-36 for FNF and TF at baseline and four months after discharge from hospital are presented in Table 3. Compared to the baseline, the scores for all the SF-36 scales did not differ at four months after discharge. Patients with a displaced FNF had a similar quality of life to those with an undisplaced FNF at baseline (Table 4). Patients with a displaced FNF differed significantly from those with an undisplaced FNF at four months after discharge only in one mental-related scale (vitality) (Table 4). Of the patients with TF, there were no significant differences between the means of both physical and mental-related scales before the fracture and at the four month follow-up (Table 5).

Table 3.

SF-36 scores (mean, SD) in patients with hip fractures at baseline and four month follow-up

ScalesBaselinepvalueFour monthpvalue
FNF  TF  FN 
PH  58,8 ± 28,56  55,2 ± 30,96  0,35  19,9 ± 20,06  21,2 ± 16,27  0,40 
RP  49,8 ± 42,01  48,2 ± 45,05  0,49 
BP  51,0 ± 21,79  54,8 ± 24,98  0,19  14,7 ± 24,77  49,6 ± 26,07  0,12 
GH  65,5 ± 26,06  70,2 ± 26,39  0,28  71,6 ± 22,73  73,3 ± 18,95  0,41 
VT  51,0 ± 21,79  45,9 ± 24,78  0,23  87,5 ± 26,54  98,4 ± 7,27  0,32 
RE  73,5 ± 40,51  68,8 ± 41,02  0,44  60,7 ± 21,19  58,1 ± 17,78  0,65 
MH  57,1 ± 27,89  58,4 ± 24,96  0,46  64,3 ± 18,99  65,3 ± 18,43  0,42 
SF  65,9 ± 31,81  62,0 ± 30,53  0,34  66,6 ± 29,91  71,7 ± 20,67  0,51 

PH = Physical functioning; RP = Role limitation-physical; BP = Bodily pain; GH = General Health; VT = Vitality; RE = Role Limitation-emotional; MH = Mental Health; SF = Social Functioning

Table 4.

SF-36 scores (median) in patients with undisplaced and displaced FNF at baseline and four month follow-up

Scales  Baselinepvalue  Four monthpvalue 
  displaced  undisplaced    displaced  undisplaced   
Physical functioning  67.5  60  0.42  10  20  0.08 
Role limitation, physical  25  75  0.12 
Bodily pain  41.5  46.5  0.35  41.5  52  0.12 
General health  64.5  76  0.23  72  82  0.45 
Role limitation, emotional  100  100  0.29  100  100  0,31 
Vitality  41.5  46.5  0.35  51.5  72.5  0.02 
Mental health  48  62  0.17  58  68  0.05 
Social functioning  48  81  0.05  76  75  0.29 

(-)= score equal to zero

Table 5.

SF-36 scores (median) in patients with unstable and stable TF at baseline and four month follow-up

Scales  Baselinepvalue  Four monthpvalue 
  Unstable  stable    Unstable  stable   
Physical functioning  45  80  0.008  17.5  15  20 
Role limitation, physical  50  25  0.44 
Bodily pain  32  41  0.21  52  41  0.26 
General health  77  72  0.32  74.5  82  0.47 
Role limitation, emotional  83  100  0.39  100  100  0.37 
Vitalit  32  52  0.18  60  60  0.46 
Mental health  52  56  0.29  66  68  0.47 
Social functioning  68.5  72  0.37  75  75  0.12 

(-)= score equal to zero

DISCUSSION

The current paper focuses on the effect that the types of hip fracture has on HRQOL. As in several previous studies, this study documented a significant deterioration of physical and psychosocial dimensions of the HRQOL in elderly subjects between the first and fourth months after hip fracture, with a partial recovery at the end of the fourth month. However, this observed impairment of the perceived well-being of the patient did not differ significantly between patients with femoral neck versus trochanteric fractures.

Several studies have previously indicated significant improvements over the period from three to six months after hospital discharge in functional capacity, the ability to perform activities of daily living, and for most dimensions of the HRQOL of elderly patients with uneventful surgical intervention and adequate rehabilitation following a hip fracture.17,18 However, hip fracture patients do not regain their pre-fracture well-being and functional level until one to two years after the fracture.3 Half of the previously independent patients become partly dependent, and one third became totally dependent after the injury.17,24 The effects of hip fractures on the mortality rate, the activities of daily life, and the quality of life can be even more devastating in elderly individuals who live under unfavorable socioeconomic conditions, like our patients. In our study, the observed mortality rate of nearly 30% four months after fracture was higher than expected (20%) according to previous studies.17,23,28

The negative impact on the HRQOL observed in our patients can guide programs for the rehabilitation and health care of elderly people with a hip fracture. Family caretakers and professionals must recognize not only the physical, but also the psychosocial repercussions on the elderly with a hip fracture. Physical rehabilitation programs and emotional and social support must be provided early. Several factors appear to influence the magnitude of the functional compromise of patients after hip fracture: cognitive or neurologic impairment, infections, bone mineral density, body mass index, age, and pre-fracture functional state.

No previous studies have been conducted that compare the HRQOL in these types of fractures. In general, patients with trochanteric fractures have a poorer functional prognosis compared with those with femoral neck fractures,23 whereas the elderly with femoral neck fractures exhibit earlier functional rehabilitation than those with other types of fractures.23,28

Our results indicate that FNF had a similar impact on the HRQOL to TCF. These results may seem unexpected. Two factors can explain our findings. First, besides the type of fracture, several factors appear to influence the magnitude of compromised function, such as: cognitive or neurologic impairment, infections, bone mineral density, body mass index, age and pre-fracture functional state. Di Monaco et al.24 found that women with a FT have worse functionality than those with a FNF. However, these are dependent variables, since this finding disappears when these confounding factors are adjusted by multivariate analysis.

Second, a linear correlation does not necessarily exist between functional capacity and quality of life. Functionality is an objective measure of evolution (outcome), and depends on the evaluation and perspective of health care professionals. However, quality of life refers to the perception of patients regarding their physical and psychosocial states. It is possible that objective measures of physical function will not correspond, or will not be sufficiently different to have repercussions on the quality of life. The perception of well-being and the fulfillment of desires depend on a complex network of factors in which, for instance, mental function and family and social support may be more relevant than physical function.

Further studies should be performed with a larger number of patients and a longer follow-up time to clarify whether there is indeed any difference in quality of life according to the type of hip fracture in the elderly.

Our study showed that there were no significant differences in the HRQOL burden after comparing patients with unstable/stable TFs and undisplaced/displaced FNFs, although patients with a displaced FNF had better SF-36 scores on the “vitality” scale. Tidermark18 reported that undisclosed FNF patients scored significantly better on the HRQOL as measured by the EuroQol compared to those with a displaced FNF. These results cannot be compared to those in our study since all the patients studied by Tidermark were treated with internal fixation, while our patients with undisclosed FNF were treated with internal fixation and those with disclosed FNF were treated with total hip replacement.

A prospective randomized study compared dislocated hip fractures treated with internal fixation and total hip replacement3. In this study, the patients treated with total hip replacement had fewer surgical complications, reported less pain, and had a better walking ability at a four month follow-up than patients treated with internal fixation. In the same study, the patients treated with total hip replacement had better SF-36 scores for bodily pain and vitality scales. It should be noted that the current study also found that patients who were treated with total hip replacement also scored better on the vitality scale.3

Our study has some potential limitations. First, the HRQOL was assessed in a relatively small number of patients. This was due to exclusion of subjects with cognitive impairment and to the high mortality rate at the four month follow-up. We did not take into account factors such as income, the number of co-morbidities, pre-fracture health perception, post-fracture social support, or post-fracture function, all of which could influence the magnitude of the burden of hip fractures on the HRQOL (i.e. post-fracture health perception) of our patients. Understanding which variables are the most critical for HRQOL should help to improve treatment and rehabilitation programs for these patients.

The study strengths included the prospective evaluation of consecutive patients with hip fractures from a single area in a developing country, and the fact that, to our knowledge, this study is the first to assess the effects on the HRQOL of a particular type of hip fracture.

A few methodological difficulties are inherent in evaluating the quality of life in the elderly. Understanding the questions contained in the questionnaires and the reliability of the answers may be impaired by the presence of aggravated cognitive alterations, in the case of hip fractures, or by the experience of pain, anxiety because of inevitable hospitalization, restricted mobility, or the loss of autonomy. Furthermore, unfortunately the frequency of old people who are illiterate in Brazil is high, and 40% of our patients were illiterate. In order to reduce the interference of these factors on the quality of the results presented in this study, patients with a severe cognitive deficit were excluded, and the questionnaires were applied using an interview technique carried out by a single researcher. It should be pointed out that the instrument generally proved to be adequately reliable (Cronbach’s alpha coefficient above 0.7).

The SF-36 used in the present study is a generic questionnaire for evaluating HRQOL and, therefore, does not address specific aspects of physical and psychosocial functioning. Specific quality of life instruments aimed at the elderly can yield more meaningful data concerning the degree of compromise in physical function. Unfortunately, a validated specific quality of life instrument in the elderly is not yet available for use in the Brazilian population.

Despite the limitations indicated, this study has clinical implications. Rehabilitation programs should offer objective conditions, with the goals of both recovering functional capacity and following the mental health of the elderly, independent of the type and severity of the hip fracture. Longitudinal studies with a longer follow-up time, along with generic and specific use of instruments for the elderly, are needed to evaluate the impact of hip fractures and the type of fracture on the HRQOL.

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