The eventual outcome of patients who had lower limb amputations due to peripheral vascular disease at Pelonomi Hospital, Bloemfontein


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S Afr Fam Pract
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RESEARCH

South African Family Practice 2015; 4(3):1–4
http://dx.doi.org/10.1080/20786190.2016.1248145

Open Access article distributed under the terms of the
Creative Commons License [CC BY-NC 3.0]
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The eventual outcome of patients who had lower limb amputations due to 
peripheral vascular disease at Pelonomi Hospital, Bloemfontein
C De Klerka  , G Du Plessisa, JJ Fouriea, A O’Neilla  , SJA Smitb and G Joubertc* 

a  School of Medicine, Faculty of Health Sciences, University of the Free State, Bloemfontein, South Africa
b  Department of Surgery, Faculty of Health Sciences, University of the Free State, Bloemfontein, South Africa
c  Department of Biostatistics, Faculty of Health Sciences, University of the Free State, Bloemfontein, South Africa

*Corresponding author, Email: gnbsgj@ufs.ac.za

Background: Peripheral vascular disease (PVD) presenting with irreversible lower limb pathology has a high morbidity and 
mortality rate. This study aimed to determine the outcome of patients who underwent lower limb amputations (LLAs) because 
of PVD at Pelonomi Hospital, Bloemfontein, 2008–2011.
Methods: Prospective data collection of a retrospective cohort study group was performed. Included were patients with PVD-
induced LLAs. Demographic and contact information was collected from Meditech. Living status (alive or dead) was determined 
using the Department of Home Affairs database and interviews with relatives.
Results: Of the study population (n = 224), 119 had contact information. Data of 158 people were available to determine living 
status: 71.5% had died by follow-up in 2014. Forty-nine interviews were possible, 31 patients had died, with cause of death 
reported to be primarily vascular related. The cumulative mortality showed that 16.1% died within a month and 48.4% within 
one year post-amputation. Among the 18 living amputees, 50.0% became unemployed, 77.8% used wheelchairs, 11.1% used 
crutches and 11.1% a prosthesis.
Conclusion: Lower limb amputation due to PVD is indicative of a poor prognosis. In our study only 28.5% of patients survived 
3–6 years post-amputation. Restoration to ideal mobility was achieved in a minority of cases.
Keywords

Bloemfonteinlower limb amputationspatient outcomeperipheral vascular disease

Introduction
Peripheral vascular disease (PVD) is reported to be the most 
common cause of major amputation worldwide.1 Peripheral 
vascular disease presenting with irreversible lower limb 
pathology is known to have a high rate of morbidity and 
mortality.2

In a Dutch study, Fortington et al.3 reported a 30-day mortality 
rate of 22%, one-year mortality of 44% and five-year mortality of 
77% in a cohort of 299 patients who underwent a first-time lower 
limb amputation. Cardiovascular and renal disease significantly 
increased the odds of dying. A study4 in the United Kingdom on 
339 patients undergoing lower limb amputation for PVD or 
complications due to diabetes reported mortality rates of 12.4% 
at 30  days and 35.7% at one year, with age, ASA status, out-of-
hours surgery and renal disease being associated with mortality. 
In a United States study5 on more than 186  000 patients with 
peripheral artery disease older than 65 years undergoing major 
lower limb amputation, mortality rate was reported as 13.5% at 
30 days and 48.3% at one year. Age, history of heart failure, renal 
disease and chronic obstructive pulmonary disease were 
significantly associated with mortality. A study in Johannesburg6 
(n = 73) found that older age, and smoking and alcohol use were 
associated with mortality at three months after lower limb 
amputation.

Norgren et al.2 reported the outcome of patients two years after 
they had undergone a below-knee amputation (BKA) as 40% 

having regained full mobility while 15% had a subsequent 
above-knee amputation (AKA), 15% had an additional 
contralateral amputation and 30% had passed away.

Our study was motivated by subjective observations that the 
follow-up visits of amputees to our clinics were infrequent and 
erratic.

Aim of the study
The aim of the study was to determine the outcome of patients 
who had undergone PVD-induced lower limb amputations at 
Pelonomi Hospital, Bloemfontein. Mortality was compiled as the 
cumulative mortality within a predetermined timeframe. If 
possible, the cause of death was also determined: either to be 
vascular or non-vascular related. In addition, the outcome as to 
functionality and mobility was determined with interviews 
conducted with the patient or family involved.

Materials and methodology

Study design
This was a retrospective cohort study with prospective data 
collection.

Patient Characteristics
Included in the study were all patients who had PVD-induced 

http://orcid.org/0000-0002-9233-1012
http://orcid.org/0000-0003-2211-5637
http://orcid.org/0000-0002-3728-6925
mailto:gnbsgj@ufs.ac.za


2 S Afr Fam Pract 2017; 4(3):1–4

lower limb amputations, including BKA or AKA from January 
2008 to December 2011.

Measurements
In 2014, theatre lists of all surgeries between January 2008 and 
December 2011 at the Departments of Surgery and Orthopaedics 
were provided by Pelonomi Hospital. The lists contained 
information on patient numbers and procedures performed. The 
patient numbers of those with lower limb amputation were 
entered into the Meditech database to obtain electronic medical 
records, contact information and basic demographic data.

Patients were assigned unique study numbers and relevant data 
were captured on data forms. Data collected included patient 
profile (age and gender) and status of the patient (alive or dead). 
If the patient was deceased, the time and possible cause of death 
were recorded. If the patient was alive, mobility of the patient 

(whether walking with prosthesis or a crutch, bedridden or in a 
wheelchair) as well as a change in employment history were 
recorded.

Patients with available contact information were phoned by the 
research assistant for the purpose of scheduling an interview. To 
determine living status (alive or dead), the identity (ID) numbers 
of patients (when available) were entered into the database of 
the Department of Home Affairs.7

A pilot study was performed using 10 randomly selected patients 
with lower limb amputation to test the study methodology. No 
changes had to be made. The results obtained during the pilot 
study were included in the main study.

Ethical considerations
The study protocol was approved by the Ethics Committee of the 
Faculty of Health Science, University of the Free State (UFS). 
Permission to access patient records was given by the Clinical 
Head of Pelonomi Hospital. Participation in the interviews by 
either the patients or the next of kin was voluntary. Detailed 
information regarding the study and participation was provided 
by the research assistant and thus informed verbal consent was 
obtained.

Data analysis
Results were summarised by frequencies and percentages 
(categorical variables) and means, standard deviations or 
percentiles (numerical variables). Analysis was performed by the 
Department of Biostatistics, UFS.

Results

Study population
The study population consisted of 224 patients. The age of the 

Figure 1: Breakdown of patients with lower limb amputation during the study period January 2008 to December 2011.
Note: *Blocks indicated in bold are those patients for whom mortality information could be obtained.

Figure 2: Cumulative mortality over a two-year period post-amputation 
(n = 31).



S Afr Fam Pract 3

patients ranged from 24 to 93  years with a median age of 
64  years. The population consisted of 42.4% female and 57.6% 
male patients. Patients with AKAs represented 46.9% of the study 
population compared with 53.1% BKAs.

The follow-up of the study population is depicted in Figure 1. For 
only 49 (21.9%) patients was an interview possible. For 109 
patients (n = 44 + 65, 48.7%) the database of the Department of 
Home Affairs was the only available source to determine living 
status.

The response rate of patients (n = 119) with contact information 
per study year was 52.3% (2008), 75.0% (2009), 48.1% (2010) and 
51.6% (2011).

Mortality
Data (ID and/or interviews) of 158 people (n = 65 + 44 + 49, see 
Figure 1) were available to determine living status. Of those 
patients, 113 (71.5%) had died by the time of follow-up in 2014. 
The percentage who had died by 2014 per year of amputation 
was as follows: 2008 85.3%, 2009 80.0%, 2010 70.5% and 2011 
63.3%. From the 49 interviews with the patients or next of kin, it 
was found that 31 patients had died. Figure 2 shows that for 
these 31 patients mortality was 16.1% within a month and 48.4% 
within one year after the amputation, cumulatively. Causes of 
death (n = 31) were reported to be 71.0% vascular related, 12.9% 
non-vascular related and 16.1% unknown.

Living amputees
Under this category only 18 interviews were available: 50.0% 
(n  =  9) patients lost their work after the amputation, of whom 
seven patients regarded the amputation as the cause of their 
unemployment. None of them were later re-employed. The 
majority of the 18 patients (77.8%) used wheelchairs and the 
remaining 22.2% were divided equally between either using 
crutches or walking with a prosthesis. No one was bedridden.

Discussion
In this study, no evidence of an ID number or any contact details 
could be found in the files of 17.8% of the population that 
underwent lower limb amputation. Incorrect and invalid data 
not only hamper treatment efforts, but may negatively affect the 
patient.

It was expected that the telephone response rate would increase 
over time due to greater availability and affordability of cell 
phones. However, the response rate was erratic. Of those with 
available contact numbers only 41.2% could be reached. It is 
unclear how the large number of untraceable patients would 
affect the results. Given that 71.5% of the study population had 
died by follow-up in 2014, it may be possible that most of the 
patients with contact numbers but not responding to calls had 
passed away.

This study population had a median age of 64  years, which is 
older than the mean of 52.9 years for surviving and 58.5 years for 
the non-surviving patients reported in Johannesburg,6 but 
younger than the mean of 74.1  years and median of 73  years 
reported by Fortington et al.3 and Scott et al.,4 respectively. Males 
were in the majority in our study (57.6%), as was the case in the 
above three studies, which reported the percentage of males 
ranging from 60% to 70% of patients.3,4,6 Norgren et al.2 reported 
that the prevalence of PVD is slightly greater in men.

In our study, the follow-up mortality rate of 71.5% post-

amputation was high. Fortington et al.3 reported 77% of patients 
having died by five years post-amputation, compared with our 
figure for amputations conducted in 2009 of 80.0%. Norgren et 
al.2 reported the mortality rate in patients with diagnosed critical 
limb ischaemia as 55% at five years and 90% at 10  years. The 
mortality rate in the study by Nehler et al.8 was 45% at three years 
compared with our figure of 63.3% for amputations performed 
in 2011.

Information regarding date of death and cause of death could 
only be determined telephonically by interviews with next of kin 
and not via the Department of Home Affairs database. These self-
reported data must be viewed with caution. The majority of 
deaths were reported to be vascular related. Irreversible 
vasculopathy of the lower limb affects vital organs in a similar 
way. Norgren et al.2 stated that coronary artery disease is by far 
the most common cause of death among patients with PVD (40–
60%). Cerebral artery disease accounted for 10–20% of the 
deaths; other vascular events such as ruptured aortic aneurism 
caused approximately 10% of deaths.

Other factors, apart from vascular disease, could play a part in 
the high mortality. Due to their age, these patients are prone to 
age-related diseases. Other factors that were not measured in 
this study include physical impairment with the resulting loss of 
income, which may have led to poor socio-economic conditions, 
and unavailability or physical challenges of using a wheelchair or 
prosthesis, which may have resulted in a sedentary lifestyle with 
associated morbidity and mortality.

The majority of living amputees who had lost their jobs blamed 
it on the amputation. None of them were re-employed; however, 
this could be expected considering their median age of 64 years.

Nehler et al.8 found that among the surviving patients (at 
17  months) 46% were non-ambulatory. Information from only 
8% of the study population was available to determine the 
method of mobility in our study. This response rate was too low 
to make a reliable conclusion as to the true state of mobility.

Norgren et al1 have reported that PVD is ‘under-recognised by 
physicians … suboptimally treated’ and that the public also has 
poor knowledge regarding this condition. The impact of these 
factors in our setting needs investigation.

Conclusion
Lower limb amputation due to PVD is indicative of a poor 
prognosis. In our study only 28.5% of lower limb amputees 
survived three to six years post-amputation. Restoration to ideal 
mobility was achieved in a minority of cases.

Recommendations
It is imperative that cardiovascular risk factors of amputees 
should be addressed aggressively. It is equally important that 
amputees are supported with a comprehensive mobilisation and 
rehabilitation programme.

Acknowledgements – The authors would like to thank Mrs E. 
Martins, research assistant at Department of Surgery, UFS, for 
doing the telephone interviews as well as Mr F.C. van Rooyen, 
Department of Biostatistics, Faculty of Health Sciences, University 
of the Free State, for statistical assistance.Ms T. Mulder, medical 
editor, School of Medicine, University of the Free State, is thanked 
for technical and editorial preparation of the manuscript.



4 S Afr Fam Pract 2017; 4(3):1–4

ORCID
C De Klerk   http://orcid.org/0000-0002-9233-1012
A O’Neill   http://orcid.org/0000-0003-2211-5637
G Joubert   http://orcid.org/0000-0002-3728-6925

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2.  Norgren L, Hiatt WR, Dormandy JA, et al. Inter-society 
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7.  Department of Home Affairs, South Africa. Available from: http://
www.dha.gov.za.

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Received: 08-07-2016 Accepted: 01-10-2016

http://orcid.org
http://orcid.org/0000-0002-9233-1012
http://orcid.org
http://orcid.org/0000-0003-2211-5637
http://orcid.org
http://orcid.org/0000-0002-3728-6925
http://dx.doi.org/10.1016/j.ejvs.2010.05.005
http://dx.doi.org/10.1016/j.ejvs.2010.05.005
http://dx.doi.org/10.1016/j.ejvs.2006.09.024
http://dx.doi.org/10.1016/j.ejvs.2006.09.024
http://dx.doi.org/10.1016/j.ejvs.2013.03.024
http://dx.doi.org/10.1016/j.ejvs.2013.03.024
http://dx.doi.org/10.1111/anae.12532
http://dx.doi.org/10.1111/anae.12532
http://dx.doi.org/10.1016/j.ahj.2012.12.002
http://dx.doi.org/10.1016/j.ahj.2012.12.002
http://www.dha.gov.za
http://www.dha.gov.za
http://dx.doi.org/10.1016/S0741-5214(03)00092-2
http://dx.doi.org/10.1016/S0741-5214(03)00092-2

	Introduction
	Aim of the study

	Materials and methodology
	Study design
	Patient Characteristics
	Measurements
	Ethical considerations
	Data analysis

	Results
	Study population
	Mortality
	Living amputees

	Discussion
	Conclusion
	Recommendations

	Acknowledgements – 
	References