South African Orthopaedic Journal

ARTHROPLASTY

DOI 10.17159/2309-8309/2021/v20n1a1Khan S et al. SA Orthop J 2021;20(1)

Citation: Khan S, Wadee N, 
Burger M, Ferreira N, Jordaan 
K. Prevalence of pathological 
neck of femur fractures in 
patients undergoing arthroplasty 
at a tertiary referral hospital. 
SA Orthop J 2021;20(1):16-20. 
http://dx.doi.org/10.17159/2309-
8309/2021/v20n1a1

Editor: Dr David North, Paarl 
Hospital, Western Cape, South 
Africa

Received: August 2020

Accepted: October 2020

Published: March 2021

Copyright: © 2021 Khan S. 
This is an open-access article 
distributed under the terms 
of the Creative Commons 
Attribution Licence, which permits 
unrestricted use, distribution and 
reproduction in any medium, 
provided the original author and 
source are credited.

Funding: No funding was secured 
for this study.

Conflict of interest: The authors 
declare they have no conflicts 
of interest that are directly or 
indirectly related to the research.

Abstract
Background
This study aimed to determine the prevalence of pathological neck of femur (NOF) fractures 
at a tertiary referral hospital through histological examination of specimens in all NOF fracture 
patients undergoing hip arthroplasty. A secondary aim was to determine whether the current 
practice of sending all femoral heads for histological evaluation, to avoid missing unsuspected 
malignancies, is financially warranted. 

Methods
A retrospective folder review of patients who underwent arthroplasty for NOF fractures was 
conducted. Patients with suspected pathological fractures were managed by the divisional Bone 
Tumour Unit while fragility traumatic fractures were managed by the Arthroplasty Unit. All femoral 
heads were sent for histological analysis regardless of suspicion of pathological fracture. Quotes 
from the public and private sector were sought to determine cost implications of sending femoral 
head specimens for histology 

Results
A total of 311 patients were included. Of these, 11 patients (4%) had suspected pathological 
fractures, with fragility/traumatic fractures being diagnosed in the remaining 300 patients (97%). 
Histology results were available for 195 patients (63%), including all the patients with suspected 
pathological fractures. No unexpected malignant histological results were observed, while nine 
of the suspected pathological fracture group had pathological fractures, confirmed with histology. 

Conclusion
Pathological lesions were identified in 3% of patients undergoing arthroplasty for NOF fractures in 
our population, which is higher than other reports in the literature. Routine histological screening 
of femoral heads to exclude pathological fracture might not be necessary and cost effective, as 
pathological lesions can accurately be identified by clinical and radiographic evaluation. 

Level of evidence: Level 4

Keywords: femoral head histology, pathological fracture, neck of femur fracture, metastases, 
hip arthroplasty

Prevalence of pathological neck of femur fractures in patients 
undergoing arthroplasty at a tertiary referral hospital 
Suhayl Khan , Naweed Wadee , Marilize Burger , Nando Ferreira* , Jacobus Jordaan

Division of Orthopaedic Surgery, Department of Surgical Sciences, Faculty of Medicine and Health Sciences, Stellenbosch University, Cape Town, South Africa

*Corresponding author: nferreira@sun.ac.za

Introduction
Femoral neck fractures pose a significant burden to the healthcare 
system in developed and developing countries, with the annual in-
cidence expected to increase in the coming years.1 The reason for 
this increase is suggested to be decreasing global mortality rates 
and the ageing populations’ subsequent risk for osteoporosis.2 
Over 84% of elderly patients with femoral neck fractures are re-
ported to have underlying osteoporosis.3 Osteoporotic or fragility 
femoral neck fractures result in significant morbidity and mortality. 
Most patients never achieve pre-fracture functional status after 
surgical intervention,4 and up to 33% die within the first 12 months 
post-operatively.5 

A small minority of patients sustain femoral neck fractures 
because of underlying pathological lesions.6 Pathological fractures 

may be caused by any bone lesion (benign, primary malignant or 
metastatic), but metastatic bone tumours and multiple myeloma 
are far more prevalent than other primary bony malignancies in 
the elderly population.7 The American Cancer Association expects 
around 1.8 million new cancer cases to be diagnosed in 2020.8 
There is also a steady decrease in mortality rate of 1.5% per year 
in patients with cancer and, as the population’s life expectancy 
increases, there is an increased prevalence of bony metastases 
with subsequent risk of pathological fractures.9

Breast, thyroid, kidney, lung and prostate primary malignancies 
have a predilection for bony metastases, though any primary 
malignancy can metastasise to bone.10 The vertebral column is 
most commonly affected by bony metastases while the proximal 
femur is the most common site for metastases to the appendicular 
skeleton.11 This, along with the strong deforming forces across 

http://dx.doi.org/10.17159/2309-8309/2021/v20n1a1
http://dx.doi.org/10.17159/2309-8309/2021/v20n1a1
https://orcid.org/0000-0002-5664-6658
https://orcid.org/0000-0002-4204-6686
https://orcid.org/0000-0003-2831-4960
https://orcid.org/0000-0002-0567-3373
https://orcid.org/0000-0002-6150-9463


Page 17Khan S et al. SA Orthop J 2021;20(1)

the hip joint, disproportionately predisposes the proximal femur to 
pathological fractures. Fifty per cent of pathological fractures occur 
at the femoral neck, 20% at the intertrochanteric area, and the 
remaining 30% in the rest of the femur.11

There are two studies in the English literature documenting 
the prevalence of pathological neck of femur (NOF) fractures. 
Ramisetty et al., in their review of 2 223 consecutive NOF frac-
tures, conducted in Birmingham, England, reported ten patients 
(0.004%) with pathological fractures.6 This figure, however, does 
not represent true prevalence as only 90 of the 2 223 patients 
in their cohort had histological evaluation. Davis et al. in their 
retrospective review at a level 1 trauma centre in California, 
United States of America, evaluated 850 consecutive femoral 
neck fracture patients, and found no unexpected malignancy in 
any of the 466 (54.8%) specimens which were sent for histological 
evaluation.12 Similarly, true prevalence of pathological fractures in 
this study cannot be deduced as 45.2% of femoral heads were 
not sent for histological analysis, and hence missed pathological 
fractures cannot be definitively excluded. 

True incidence of pathological femoral neck lesions in patients 
undergoing elective arthroplasty of the hip, in stark contrast, 
has been extensively researched.13-16 However, there is no clear 
consensus on whether it is necessary from an economic standpoint 
to send all resected specimens for histological examination in 
these patients.15,16

The aim of this study was to determine the prevalence of 
pathological NOF fractures at a tertiary referral hospital between 
2014 and 2016 through histological specimens in all NOF fracture 
patients presenting for hip arthroplasty. The secondary aim was to 
determine if the current practice of sending all femoral heads for 
histological evaluation, to avoid missing unsuspected malignancies, 
is warranted, and to explore the financial cost involved. 

Methods 
A retrospective, observational review of case notes, imaging studies 
and histological results of all patients who underwent arthroplasty 

for NOF fractures between January 2014 and December 2016 was 
conducted. 

As per institutional protocol, on admission all patients were divided 
into two groups depending on suspicion of pathological or fragility/
traumatic NOF fractures according to clinical and radiographic 
findings. Patients with suspected pathological fractures were 
subsequently managed by the divisional Bone Tumour Unit 
while fragility and traumatic NOF fractures were managed by the 
Arthroplasty Unit (Figure 1). Clinical features raising concern of 
possible pathological fractures included: i) antecedent hip pain,  
ii) atraumatic mechanism of injury and iii) a history of malignancy. 
Radiological features suggestive of pathological fractures included 
atypical fracture patterns (e.g. transverse fractures with minimal 
trauma) or any bony lesions (e.g. lytic, permeative, moth-eaten 
lesions) at the fracture site or any other bone on the radiograph. 

Patients were identified from records from both units. All patients 
that underwent a head-sacrificing procedure were included in the 
study while patients who received arthroplasty for reasons other 
than NOF fractures and patients treated with internal fixation were 
excluded. There was no exclusion for age. 

All resected femoral heads were sent for histology regardless 
if malignancy was suspected or not (Figure 1) as per our current 
standard of care for these fractures. For the fragility/traumatic 
fracture group, the type of hip reconstruction following head 
resection was selected on an individualised approach but was 
based on the National Institute of Health and Care Excellence 
(NICE) guidelines. Cognitively sound community ambulators who 
are anaesthetically medically fit are offered total hip arthroplasty 
over hemiarthroplasty.17 

Patients who presented with a suspicious fracture without a 
known primary malignant lesion were investigated in order to find 
the primary lesion and exclude a primary malignancy of bone and 
were then offered surgery. Patients with known metastasis (and 
those where the primary malignant lesion causing metastasis was 
found) were offered bipolar hemiarthroplasty with long cemented 
stems to prevent periprosthetic fracture. Primary implants used 
for fragility/traumatic group fractures were the DePuy Johnson 
& Johnson Corail Pinnacle system. Primary implants used for 

Figure 1. Flow diagram of patients presenting with neck of femur fractures

Patients presenting with femur neck fracture

HistologyBone Tumour Unit Arthroplasty Unit

Suspected pathological fracture Suspected fragility/traumatic fracture

Clinical evaluation
• History of malignancy or metastases
• Constitutional symptoms 
• Atraumatic mechanism of injury
• Antecedent hip pain 

Radiological evaluation
Radiological features of pathological/fragility fracture  



Page 18 Khan S et al. SA Orthop J 2021;20(1)

pathological fractures were Stryker Exeter V40 long femoral stems 
with bipolar hemi-arthroplasty heads. 

To determine the financial implications of sending femoral 
heads for pathological examination, The National Laboratory 
Health Service, which provides histopathological examination for 
specimens in the state sector, as well as Pathcare, which services 
the private sector, provided quotes in November 2019 of routine 
processing of these specimens. 

Data was analysed using STATISTICA v13. Continuous demo-
graphic data (age) is reported as a mean and standard deviation 
together with 95% confidence intervals (CI). Categorical data is 
described as frequencies and/or counts. 

Results 
A total of 311 patients who underwent arthroplasty for NOF 
fractures were included in this study. The cohort comprised 215 
women (69%) and 96 men (31%) with a mean age of 73.4 years  
± 12.6 (95% CI 72–74.).

A total of 11 of 311 patients (4%) were admitted with suspected 
pathological fractures, based on clinical and/or radiological 
suspicion with fragility/traumatic fractures being diagnosed in the 
remaining 300 patients (97%). Histology results were available 
for 195 patients (63%) including all of the patients with suspected 
pathological fractures, and 184 of the suspected traumatic/fragility 
fractures. 

Nine of the suspected 11 patients were histologically confirmed 
to have a malignancy (Table I), all of which were secondary to 
metastatic disease or multiple myeloma, with no primary sarcomas 
diagnosed. Of these, four out of nine (44%) patients presented with 
an unknown primary malignancy and required a thorough clinical 
examination and basic haematological (tumour markers, myeloma 
workup) and radiological (CT chest/abdomen/pelvis) investigations 
to identify the primary malignancy prior to surgery. The histology 
from the resected femoral specimens for these patients confirmed 
the respective primary malignancy after initial workup. 

Breast and lung carcinoma were the most common source 
of the primary malignancies, accounting for six of the nine 
pathological fractures (three each). Multiple myeloma, renal and 
prostate carcinoma accounted for the other three patients (Table I,  
Figure 2). 

The first of the two suspected pathological fracture patients who 
did not have a pathological lesion on histology was a 68-year-
old male known with prostate cancer and who had a suspicious 
femoral neck lytic lesion on radiographs, not in keeping with the 
blastic metastasis usually associated with prostate cancer. After 
MRI (hip), CT (chest, abdomen and pelvis) and bone scan were 
non-contributory, the lytic lesion was biopsied to exclude a primary 
bony sarcoma or second primary malignancy. The biopsy showed 

no signs of pathological fracture and he subsequently received 
a total hip replacement. Histological evaluation of the resected 
femoral head confirmed the absence of any pathological lesions.

The second patient was a 47-year-old HIV-positive female 
with a large breast mass with skin involvement. This was her 
index presentation to any healthcare facility for the breast mass. 
Radiographs revealed a subcapital NOF fracture and suspicious per 
trochanteric lytic lesion. She was assumed to have a pathological 
fracture secondary to metastasis from breast cancer and hence 
received a long-cemented stem bipolar hemiarthroplasty. Biopsy of 
the breast mass was done concurrently, and she was subsequently 
discharged to the care of the breast surgical oncology unit for 
further management. The breast biopsy confirmed malignancy 
(invasive carcinoma); however, histology of the femoral head did 
not show any pathology. 

Three of the nine (33%) patients with pathological fractures 
presented with antecedent hip pain, five (56%) with a known 
primary malignancy, three (33%) with known metastatic disease, 
and two (22%) with an atraumatic mechanism of injury. All nine 
patients had radiographic features of pathological fractures  
(Figure 3). 

Histological results were available for 184 (of 300) patients in 
the fragility/trauma group. There were no unexpected malignant 
histological results found in this group. In 116 patients no 

Table I: Patients with pathological findings on histology
Age 

(years)
Sex

Known 
primary

Known 
metastases

X-ray features of 
malignancy

Atraumatic 
mechanism of injury

Antecedent 
hip pain

Histology results

65 Female No No Lytic No No Metastatic lung carcinoma

67 Female No No Sclerotic Yes No Metastatic lung carcinoma

75 Female Yes Yes Permeative No No Metastatic breast carcinoma

54 Female Yes Yes Lytic No Yes Metastatic breast carcinoma

51 Female No No Permeative No Yes Metastatic lung carcinoma

87 Male Yes No Sclerotic No No Metastatic prostate carcinoma

54 Female No No Lytic No No Multiple myeloma

72 Female Yes Yes Lytic No No Metastatic renal carcinoma

54 Female Yes No Lytic Yes Yes Metastatic breast carcinoma

Figure 2. Percentage of primary malignancies responsible for metastatic 
lesions

Breast 
33%

Lung 
33%

Renal 
11%

Prostate 
11%

Myeloma 
11%



Page 19Khan S et al. SA Orthop J 2021;20(1)

histological results could be found. The reason these 116 excised 
femoral heads were not histologically analysed as per institutional 
protocol was difficult to define retrospectively. Lost specimens, 
problems with transport of specimens from theatre to the pathology 
lab, human error, resulting in the specimens not being ordered are 
all considerations. 

All but one of the patients with pathological fractures were treated 
with a long-cemented stem bipolar hemiarthroplasty. This patient 
returned two weeks post-surgery with a periprosthetic fracture 
below the implant that required revision. There was no major intra-
operative or immediate post-operative morbidity or mortality related 
to cementation in patients who received long cemented stems for 
pathological fractures.

The approximate cost of a single femoral head histological 
examination in the private healthcare sector and the state 
healthcare system was ZAR 1 956 (US$ 134) and ZAR 540  
(US$ 37) respectively.

Discussion
The aim of the study was to establish the prevalence of pathological 
fractures at our institution and to determine the financial implications 
of sending all femoral heads for histological examination. 

The first main finding of this study was that all pathological 
femoral neck fractures were secondary to metastatic disease and 
represented 3% of patients in the total cohort (9 of 311), or 5% (9 of 
195) of those with confirmed histology findings. This is considerably 
higher than that reported by Davis et al. (0.9%)12 and Ramisetty et 
al. (0.45%).6 No conclusive reason can be given for this disparity 
in prevalence without further comparative studies. It could be 
explained by the lower number of femoral heads sent for histological 
examination (52% and 4% respectively), perhaps resulting in 
missed pathological fractures. More likely, it represents the delayed 

presentation due to health-seeking behaviour18 and 
lack of comprehensive screening programmes for 
cancer;19 hence the delay in treatment, increasing 
the prevalence of metastatic disease in the South 
African context. The patients with pathological 
fractures presented at a younger age (mean  
63 years) than those with fragility fractures (mean 
73 years), and this should be considered when 
treating these patients.

In view of the fact that there were no missed 
pathological fractures, and that nine of 11 patients 
with pathological lesions were correctly identified 
on clinical features and radiographic findings in 
our series, sending all femoral heads routinely 
seems unnecessary. Almost half of the pathological 
fractures in the current series presented without a 
known primary malignancy, and in all these cases 
the primary was preliminarily identified using 
Rougraff et al.’s20 rudimentary diagnostic approach 
comprising basic blood tests and a computed 
tomography scan of the chest, abdomen and 
pelvis. Three of the four unknown primary tumours 
were of lung origin, in keeping with the nature of 
bronchogenic malignancies as they have few 
clinical symptoms initially and metastasise early, 
with metastatic lesions often the first manifestation 
of the disease.21 There were no pathological 
fractures due to bony sarcomas consistent with the 
rarity of primary malignant bony lesions in elderly 

patients.22 All four patients who presented with metastases of an 
‘unknown primary’ had a first histological diagnosis made on their 
femoral head specimens, as this preceded biopsy from the area of 
primary malignancy. This highlights the importance of pathological 
examination of the femoral heads from suspected lesions.

There is controversy in the literature regarding the use of 
short uncemented or longer cemented stems for patients with 
pathological fractures. Short uncemented stems weigh the risk of 
prosthetic loosening or periprosthetic fracture in the future, with the 
immediate risk of intra-operative haemodynamic instability or death 
with bone cement implantation syndrome associated with longer 
cemented stems.11,22 In the current series we did not experience 
any cementation-related complications in patients who received 
long cemented stems for pathological fractures.

A secondary aim was to determine the cost implications of 
sending all femoral heads for histological evaluation. In this 
study, femoral head histology (n=195) amounted to between 
ZAR 105 300 (US$ 7 274) and ZAR 381 420 (US$ 26 322) over 
the three-year period. As we were able to accurately exclude 
malignancy using clinical and radiographic criteria, sending only 
the suspicious femoral heads (n=11) for histological examination 
would have resulted in a reduced cost of between ZAR 99 360 
(US$ 6 864) and ZAR 359 904 (US$ 24 838). As femoral neck 
fracture incidence is increasing globally,1 and considering financial 
constraints on the healthcare system, judicious use of resources 
is imperative. Subsequently, the findings of this study confirm the 
recommendation that clinicians should consider sending only the 
suspected pathological fractures for histological evaluation. 

The limitations of this study include its retrospective nature 
and the fact that not all femoral heads were sent for pathological 
examination. We are therefore not able to definitively exclude 
pathological fractures for all patients, although we report a higher 
percentage than previous studies. 

Figure 3. Anteroposterior radiographs of patients from our study presenting with pathological 
fractures with the source of the primary malignancy denoted below each image



Page 20 Khan S et al. SA Orthop J 2021;20(1)

Conclusion
Pathological lesions were identified only in a small percentage 
of patients undergoing arthroplasty for NOF fractures in our 
population, albeit higher than other studies in the literature. Routine 
histological screening of femoral heads to exclude pathological 
fracture might not be necessary, as pathological lesions can 
accurately be identified by clinical and radiographic evaluation. 

Ethics statement
The authors declare that this submission is in accordance with the principles laid down 
by the Responsible Research Publication Position Statements as developed at the 
2nd World Conference on Research Integrity in Singapore, 2010.
Prior to commencement of the study ethical approval was obtained from the following 
ethical review board: Health Research Ethics Committee, Stellenbosch University, 
Project ID 8744 and ethics reference number S18/10/264. All procedures were 
in accordance with the ethical standards of the responsible committee on human 
experimentation (institutional and national) and with the Helsinki Declaration of 1975, 
as revised in 2008. Informed written consent was not obtained from all patients for 
being included in the study.

Declaration
The authors declare authorship of this article and that they have followed sound 
scientific research practice. This research is original and does not transgress 
plagiarism policies.

Author contributions 
SK: Data capture, manuscript preparation
NW: Data capture, manuscript preparation
MB: Data analysis, manuscript revision
NF: Study conceptualisation, data capturing, study design, manuscript revision
KJ: Study conceptualisation, data capturing, study design, manuscript revision

References
1. Johnell O, Kanis J. Epidemiology of osteoporotic fractures. Osteoporos Int. 

2005;16(suppl. 2):6-10. https://doi.org/10.1007/s00198-004-1702-6. 
2. Thorngren KG, Hommel A, Norrman PO, Thorngren J, Wingstrand H. 

Epidemiology of femoral neck fractures. Injury. 2002;33(suppl 3):C1-7. http://
www.ncbi.nlm.nih.gov/pubmed/12423584.

3. Cummings SR, Browner W, Cummings SR, et al. Bone density at various 
sites for prediction of hip fractures. Lancet. 1993;341(8837):72-75. https://doi.
org/10.1016/0140-6736(93)92555-8.

4. Compston JE, McClung MR, Leslie WD. Osteoporosis. Lancet. 
2019;393(10169):364-76. https://doi.org/10.1016/S0140-6736(18)32112-3.

5. Guzon-Illescas O, Perez Fernandez E, Crespí Villarias N, et al. Mortality after 
osteoporotic hip fracture: Incidence, trends, and associated factors. J Orthop 
Surg Res. 2019;14(1):1-9. https://doi.org/10.1186/s13018-019-1226-6.

6. Ramisetty NM, Pynsent PB, Abudu A. Fracture of the femoral neck, the 
risk of serious underlying pathology. Injury. 2005;36(5):622-26. https://doi.
org/10.1016/j.injury.2004.08.034.

7. Torbert JT, Lackman RD. Chapter 2 Pathological Fractures. In: Pignolo 
RJ, Keenan MA, Hebela NM, editors. Fractures in the elderly. Aging 
Medicine. Springer Science+Business Media; 2011. p. 43-54. https://doi.
org/10.1007/978-1-60327-467-8. 

8. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2020. CA Cancer J Clin. 
2020;70(1):7-30. https://doi.org/10.3322/caac.21590.

9. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2018. CA Cancer J Clin. 
2018;68(1):7-30 https://doi.org/10.3322/caac.21442. 

10. Damron TA, Sim FH. Surgical treatment for metastatic disease of the pelvis 
and the proximal end of the femur. J Bone Jt Surg Am. 2000;49:461-70. http://
www.ncbi.nlm.nih.gov/pubmed/10829199.

11. Swanson KC, Pritchard DJ, Sim FH. Abstract. The surgical treatment of 
metastatic disease of the femur. J Am Acad Orthop Surg. 2000;56(3):335-39. 
http://www.ncbi.nlm.nih.gov/pubmed/10974383.

12. Davis JA, Rohlfing G, Sagouspe K, Brambila M. Assessing the value of routine 
pathologic examination of resected femoral head specimens after femoral neck 
fracture. J Am Acad Orthop Surg. 2019;27(14):e664-8. https://doi.org/10.5435/
jaaos-d-17-00901.

13. Fornasier VL, Battaglia DM. Finding the unexpected: Pathological examination 
of surgically resected femoral heads. Skeletal Radiol. 2005;34(6):321-28. 
https://doi.org/10.1007/s00256-004-0820-8.

14. Lin MM, Goldsmith JD, Resch SC, DeAngelis JP, Ramappa AJ. Histologic 
examinations of arthroplasty specimens are not cost-effective: A retrospective 
cohort study. Clin Orthop Relat Res. 2012;470(5):1452-60. https://doi.
org/10.1007/s11999-011-2149-7.

15. Liow MHL, Agrawal K, Anderson DW, et al. Unsuspected malignancies in 
routine femoral head histopathologic examination during primary total hip 
arthroplasty: cost-effectiveness analysis. J Arthroplasty. 2017;32(3):735-42. 
https://doi.org/10.1016/j.arth.2016.08.017

16. Rubin G, Krasnyansky S, Gavish I, et al. Meta-analysis of unexpected findings 
in routine histopathology during total joint replacement. Isr Med Assoc J. 
2011;13(2):80-83.

17. National Institute of Health and Care Excellence. Hip fracture: Management. 
BMJ. 2011;342:d2108. https://doi.org/10.1136/bmj.d2108.

18. Moodley J, Cairncross L, Naiker T, Momberg M. Understanding pathways to 
breast cancer diagnosis among women in the Western Cape Province, South 
Africa: A qualitative study. BMJ Open. 2016;6(1):1-7. https://doi.org/10.1136/
bmjopen-2015-009905.

19. Rayne S, Schnippel K, Kruger D, Benn CA, Firnhaber C. Delay to diagnosis 
and breast cancer stage in an urban south african breast clinic. South African 
Med J. 2019;109(3):159-63. https://doi.org/10.7196/SAMJ.2019.v109i3.13283.

20. Rougraff BT, Kneisl JS, Simon MA. Skeletal metastases of unknown origin. A 
prospective study of a diagnostic strategy. J Bone Jt Surg. 1993;75(9):1276-81. 
https://doi.org/10.2106/00004623-199309000-00003.

21. Li J, Zhu H, Sun L, Xu W, Wang X. Prognostic value of site-specific metastases 
in lung cancer: A population based study. J Cancer. 2019;10(14):3079-86. 
https://doi.org/10.7150/jca.30463.

22. Takagi T, Katagiri H, Kim Y, et al. Skeletal metastasis of unknown primary 
origin at the initial visit: A retrospective analysis of 286 cases. PLoS One. 
2015;10(6):1-18. https://doi.org/10.1371/journal.pone.0129428.


	_Hlk33642667