Effects of Surgical Intervention for Bone Metastases on Survival in Patients with Advanced Cancer: A Nationwide Population-Based Cohort Study.

PURPOSE: With recent advances in surgical techniques and instruments, orthopedic surgeons are better equipped to treat metastatic bone disease. There has also been considerable progress in the non-surgical treatment of cancers, specifically in improving the survival rate of patients with advanced cancer. However, it remains unclear whether surgical resection of a metastatic bone lesion poses additional risk to the survival of patients with advanced cancer. PATIENTS AND METHODS: This study utilized data from the National Health Insurance Research Database (NHIRD) in Taiwan between 2000 and 2015. Patients aged ≥18 years, who had been recently diagnosed with bone metastases (BM), were enrolled and assigned to either the surgery or non-surgery groups. The demographic characteristics were analyzed, and the adjusted hazard ratios (aHR) of mortality were calculated using Cox regression analysis.
RESULTS: Of the 4,549,226 individuals in the inpatient database of the NHIRD, 83,536 patients with BM were enrolled in this study. Among them, 8802 underwent surgical resection for skeletal metastatic lesion and 66,098 did not. Altogether, 28,691 patients died, including 2798 (31.8%) in the surgery group and 25,893 (39.2%) in the non-surgery group. The aHR for mortality was 0.7-fold lower in the surgery group (p < 0.001).
CONCLUSION: This study demonstrates that surgical resection of metastatic bone lesions did not pose any additional risk to survival outcomes. Thus, we believe that surgery, if indicated, could have a competitive role in the management of metastatic bone disease.

Introduction

Bone metastases (BM) is a devastating condition that adversely affects the lives of patients with advanced cancer. Patients may experience limitations in the activities of daily living, decreased quality of life (QOL), threat to survival, and increased medical expenses. Management of skeletal metastatic disease has attracted increasing attention in the last few years. In the past, 50% of patients with cancer would die within 6 months of surgery owing to a pathologic fracture or paraplegia due to spinal metastases.1 Most surgeons hesitate to perform surgical resection for cancer patients with BM despite the poor QOL, owing to comorbidities and limited life expectancy. Currently, with the advancement of surgical techniques and instruments, orthopedic surgeons are better equipped to restore function in cancer patients with skeletal complications. Further, systemic treatment of cancers, such as chemotherapy and targeted therapy, has contributed to the increased survival rate of patients with advanced cancer. Recently, the number of breast and colorectal cancer survivors has increased globally. In numerous countries, the 5-year survival rate for prostate cancer is > 95%.2

Better management of the primary cancer increases the survival rate of patients; hence, there is an increased demand for surgical intervention to treat metastatic bone lesions. However, the risks and possible complications associated with surgery may have a negative effect on the patient’s health. It is also unclear whether surgical resection of metastatic bone lesions is an additional risk factor in the overall survival outcomes of patients with advanced cancer. In fact, the reported survival rates vary widely between different studies because of the difference in primary tumor selection.3,4 Studies that have demonstrated survival rates of patients presenting with BM from a variety of primary tumors with short-term follow-up also showed heterogeneous results.5,6 Thus, this study aimed to conduct a long-term investigation on the difference in mortality rates between patients who underwent surgical resection for skeletal metastases and those who did not, while considering sex, age, comorbidities, and use of bone resorption inhibitors (BRIs).

Patients and Methods

Database

We analyzed all the inpatient data included in Taiwan’s National Health Insurance Research Database (NHIRD), which was established in 1995. The health insurance system in Taiwan enrolls > 99% of the population (around 23,000,000 insurants per year). Cancer with BM was considered to be in the advanced stage; therefore, most patients were hospitalized for medical treatment. The study data was obtained from January 1, 2000 (index date) to December 31, 2015. The composition and characteristics of the individuals were normally distributed.

Study Design, Patients, and Ethics

We used the International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM) coding system to identify diagnoses and related procedures. BM was defined as ICD-9-CM code 198.5, corresponding to the following ICD-9-CM codes for primary cancer, eg, ICD-9-CM: 162 for lung cancer, ICD-9-CM: 174 for breast cancer, and ICD-9-CM: 185 for prostate cancer. Patients with BM before the index date, those who were lost to follow-up, those with unknown sex information, and pediatric patients (< 18 years old) were excluded from the study. Surgical resection for skeletal metastases was defined using the National Health Insurance order code, 64204B and 64205B for wide excision of malignant bone tumors. The use of BRIs, such as zoledronic acid, pamidronate disodium, clodronate tetrahydrate, and denosumab, was also analyzed. The utilization of NHIRD data was legally authorized and complies with relevant data protection and privacy regulations. The study protocol was approved by Institutional Review Board of the Tri-Service General Hospital (approval No. B202005037).

Comorbidities

The following comorbidities and associated complications were assessed using the corresponding ICD-9-CM codes: hypertension (HTN, ICD-9-CM: 401–405), diabetes mellitus (DM, ICD-9-CM: 250), chronic obstructive pulmonary disease (COPD, ICD-9-CM: 490–496), chronic kidney disease (CKD, ICD-9-CM: 585), ischemic heart disease (IHD, ICD-9-CM: 410–414), congestive heart disease (CHD, ICD-9-CM: 428–429), stroke (ICD-9-CM: 430–438), pneumonia (ICD-9-CM: 480–486), injury (ICD-9-CM: 800–999), hyperthyroidism (ICD-9-CM: 242), liver disease (ICD-9-CM: 571), depression (ICD-9-CM: 296.2–296.3, 300.4, 311), and sepsis (ICD-9-CM: 003.1, 036.1, 038). All presented ICD-9-CM codes and National Health Insurance order codes are displayed in the appendix ().

Statistics

Statistical analysis was performed using SPSS software, version 22 (IBM Corp., Armonk, N.Y., USA). The chi-square and Fisher’s exact tests were used to compare categorical variables and the t-test was used to compare continuous variables between the surgery and non-surgery groups. Kaplan–Meier curve analysis and the Log rank test was employed to demonstrate the cumulative risk of mortality. The adjusted hazard ratios (aHRs) of mortality and other covariates of interest were calculated using multivariate Cox regression analysis. A p-value < 0.001 was considered statistically significant.

Results

Of the 4,549,226 individuals in the inpatient database of NHIRD, 83,536 patients with BM were enrolled in this study. On applying the exclusion criteria, 8636 patients were excluded. Thus, 74,900 patients were selected for subsequent analysis; all were at least 18 years old and had BM that was recently diagnosed between 2000 and 2015. Among these, 8802 patients underwent surgical resection for skeletal metastatic lesion and 66,098 did not. At the end of the follow-up period, a total of 28,691 patients died: 2798 (31.8%) in the surgery group and 25,893 (39.2%) in the non-surgery group. The research algorithm is presented in Figure 1.

Figure 1

Flowchart of the study design and participant selection.

The final study participants were divided into two groups: “surgery” and “non-surgery.” Patient characteristics included sex, age, the location of BM, length of hospital stay, adjunctive radiotherapy and chemotherapy, distribution of hospital levels, comorbidities, and the use of BRIs (Table 1). Most patients with BM (> 50%) were aged ≥ 65 years in both the surgery and non-surgery groups. We divided the patients into the following three age subgroups: 18–44 years, 45–64 years, and ≥ 65 years; the distribution of patients in each subgroup was similar in both groups. However, patients in the surgery group were significantly older. There were more male patients than female patients enrolled in this study (52.4% versus 47.6%) and in the non-surgery group (53.2% versus 46.8%); however, the number of male patients was lower than that of female patients in the surgery group (46% versus 54%). According to the location of BM, we also divided the patients into the following three subgroups: axial skeleton, appendicular skeleton, and multiple sites. There was significant difference in the composition between the surgery and non-surgery groups. The non-surgery group included more patients with multiple sites of BM than the surgery group (90.8% versus 65.5%). Several differences in the accompanying comorbidities were found: the prevalence of HTN, DM, IHD, CHD, injury, liver disease, and depression was higher in the surgery group, while that of pneumonia was higher in the non-surgery group. No significant difference in the prevalence of COPD, CKD, stroke, hyperthyroidism, and sepsis was observed. Overall, accompanying comorbidities were more prevalent in the surgery group. The proportion of patients using BRIs (except for denosumab) was significantly higher in the non-surgery group.

Table 1

Patient Characteristics Based on the Longitudinal Health Insurance Database

Patient	Total		With Surgery		Non- Surgery		pa
Characteristics	n	%	n	%	n	%
Total	74,900		8802	11.8	66,098	88.2
Mortality							< 0.001
Without	46,209	61.7	6004	68.2	40,205	60.8
With	28,691	38.3	2798	31.8	25,893	39.2
Sex							< 0.001
Male	39,225	52.4	4052	46.0	35,173	53.2
Female	35,675	47.6	4750	54.0	30,925	46.8
Age (years)	65.94 ± 14.29		67.45 ± 14.55		65.74 ± 14.25		< 0.001
18–44	6,318	8.4	688	7.8	5630	8.5
45–64	27,115	36.2	2867	32.6	24,248	36.7
≥ 65	41,467	55.4	5247	59.6	36,220	54.8
Location of BM							<0.001
Axial	8687	10.0	2374	28.0	6313	8.1
Appendicular	1437	1.7	546	6.4	891	1.1
Multiple	76,345	88.3	5553	65.5	70,792	90.8
Length of hospital days	12.9 ± 13.2		11.9 ± 12.9		13.1 ± 13.3		< 0.001
RT/CT							< 0.001
Without	18,092	20.9	1436	16.9	16,656	21.4
With	68,377	79.1	7037	83.1	61,340	78.6
Hospital levels
Medical center	40,195	46.5	3913	46.2	36,282	46.5	0.78
Regional hospital	36,838	42.6	3640	43.0	33,198	42.6
District hospital	9436	10.9	920	10.9	8516	10.9
HTN							< 0.001
Without	66,928	89.4	7204	81.8	59,724	90.4
With	7972	10.6	1598	18.2	6374	9.6
DM							< 0.001
Without	67,250	89.8	7596	86.3	59,654	90.3
With	7650	10.2	1206	13.7	6444	9.7
COPD							0.11
Without	71,143	95.0	8330	94.6	62,813	95.0
With	3757	5.0	472	5.4	3285	5.0
CKD							0.30
Without	70,781	94.5	8297	94.3	62,484	94.5
With	4119	5.5	505	5.7	3614	5.5
IHD							< 0.001
Without	72,391	96.7	8391	95.3	64,000	96.8
With	2509	3.3	411	4.7	2098	3.2
CHD							< 0.001
Without	72,862	97.3	8495	96.5	64,367	97.4
With	2038	2.7	307	3.5	1731	2.6
Stroke							0.01
Without	72,691	97.1	8500	96.6	64,191	97.1
With	2209	2.9	302	3.4	1907	2.9
Pneumonia							< 0.001
Without	60,898	81.3	7477	84.9	53,421	80.8
With	14,002	18.7	1325	15.1	12,677	19.2
Injury							< 0.001
Without	70,630	94.3	7600	86.3	63,030	95.4
With	4270	5.7	1202	13.7	3068	4.6
Hyperthyroidism							0.73
Without	74,817	99.9	8794	99.9	66,023	99.9
With	83	0.1	8	0.1	75	0.1
Liver disease							< 0.001
Without	69,755	93.1	8041	91.4	61,714	93.4
With	5145	6.9	761	8.6	4384	6.6
Depression							< 0.001
Without	74,384	99.3	8714	99.0	65,670	99.4
With	516	0.7	88	1.0	428	0.6
Sepsis							0.004
Without	64,578	86.2	7676	87.2	56,902	86.1
With	10,322	13.8	1126	12.8	9196	13.9
Zoledronic acid							< 0.001
Without	52,415	70.0	6386	72.6	46,029	69.6
With	22,485	30.0	2416	27.4	20,069	30.4
Pamidronate disodium							< 0.001
Without	53,614	71.6	6791	77.2	46,823	70.8
With	21,286	28.4	2011	22.8	19,275	29.2
Clodronate Tetrahydrate							< 0.001
Without	52,635	70.3	6654	75.6	45,981	69.6
With	22,265	29.7	2148	24.4	20,117	30.4
Denosumab							0.47
Without	52,286	69.8	6174	70.1	46,112	69.8
With	22,614	30.2	2628	29.9	19,986	30.2

Note: aChi-square/Fisher’s exact test for categorical variables and t-test for continuous variables. A p-value < 0.001 was considered statistically significant.

Abbreviations: BM, bone metastases; RT, chemotherapy; CT, chemotherapy; DM, diabetes mellitus; CHD, congestive heart disease; CKD, chronic kidney disease; COPD, chronic obstructive pulmonary disease; HTN, hypertension; IHD, ischemic heart disease.

The follow-up period from surgery to death ranged from 1 to 15 years. Kaplan–Meier curves of survival for the surgery and non-surgery groups are shown in Figure 2. A significant difference in survival was noted based on the Log rank test (p < 0.001). Most deaths that occurred during the study period were within 5 years of surgery, and particularly within the first year. The number of surgeries for BM by years of follow-up are shown in Figure 3. It exhibits an upward trend over the study period. After adjustment for sex, age, and comorbidities using multivariate Cox regression analysis, the aHRs of surgery, sex, age subgroups, and comorbidities were identified (Table 2). The aHR of mortality was significantly lower in the surgery group than in the non-surgery group (aHR = 0.7, p < 0.001). As expected, old age and comorbidities were associated with a higher aHR or mortality. None of the BRIs had significant influence on the aHR of mortality.

Figure 2

Kaplan–Meier curves for cumulative survival and the Log rank test. The inpatients with bone metastases were aged ≥ 18 years and stratified by whether they underwent surgery.

Figure 3

The number of surgeries done for BM by years of follow-up presents an upward trend.

Table 2

Factors for Mortality Based on Multivariate Cox Regression Analysis

Variables	Crude HR	Adjusted HRa	95% CI	95% CI	p
Surgery
With/Without	0.64	0.70	0.67	0.73	< 0.001
Sex
Male/Female	1.40	1.40	1.37	1.44	< 0.001
Age (years)
45–64/18–44	1.01	1.02	0.97	1.06	0.453
≥ 65/18–44	1.18	1.16	1.11	1.22	< 0.001
HTN
With/Without	1.44	1.54	1.52	1.57	< 0.001
DM
With/Without	1.65	1.77	1.74	1.81	< 0.001
COPD
With/Without	1.69	1.67	1.64	1.71	< 0.001
CKD
With/Without	1.08	1.30	1.04	1.93	0.005
IHD
With/Without	1.52	1.61	1.56	1.66	< 0.001
CHD
With/Without	1.76	1.86	1.80	1.92	< 0.001
Stroke
With/Without	1.64	1.73	1.68	1.79	< 0.001
Pneumonia
With/Without	2.43	2.26	2.22	2.29	< 0.001
Injury
With/Without	1.48	1.54	1.50	1.57	< 0.001
Hyperthyroidism
With/Without	1.38	1.44	1.27	1.74	0.002
Liver disease
With/Without	1.94	1.88	1.84	1.92	< 0.001
Depression
With/Without	1.61	1.72	1.61	1.84	< 0.001
Sepsis
With/Without	2.52	2.31	2.27	2.35	< 0.001
Zoledronic acid
With/Without	0.56	0.85	0.40	1.38	0.44
Pamidronate disodium
With/Without	0.84	1.03	0.57	1.60	0.57
Clodronate Tetrahydrate
With/Without	0.68	0.88	0.30	1.41	0.45
Denosumab
With/Without	0.90	1.27	0.71	1.77	0.60

Note: aAdjusted for the variables listed in the table. A p-value < 0.001 was considered statistically significant.

Abbreviations: HR, hazard ratio; CI, confidence interval; DM, diabetes mellitus; CHD, congestive heart disease; CKD, chronic kidney disease; COPD, chronic obstructive pulmonary disease; HTN, hypertension; IHD, ischemic heart disease.

We also performed a stratified analysis for sex, age subgroups, each comorbidity, and certain cancers to compare the aHRs of mortality between the surgery and non-surgery groups (Table 3). Results were comparable between all age subgroups, sexes, and when the analysis was restricted to certain comorbidities and cancers. Patients with skeletal metastases who underwent surgical resection were at no extra risk of death when compared with those who did not.

Table 3

Factors for Mortality Stratified by Sex, Age Groups, Comorbidities, and Certain Cancers Based on Multivariate Cox Regression Analysis

Surgery
Stratified	Adjusted HRa	95% CI	95% CI	p
Total	0.70	0.67	0.73	< 0.001
Sex
Male	0.74	0.71	0.77	< 0.001
Female	0.66	0.64	0.69	< 0.001
Age group (years)
18–44	0.66	0.64	0.69	< 0.001
45–64	0.67	0.65	0.70	< 0.001
≥ 65	0.73	0.70	0.76	< 0.001
HTN	0.77	0.74	0.80	< 0.001
DM	0.86	0.83	0.89	< 0.001
COPD	0.77	0.74	0.81	< 0.001
CKD	0.82	0.79	0.86	< 0.001
IHD	0.82	0.79	0.85	< 0.001
CHD	0.75	0.72	0.78	< 0.001
Stroke	0.71	0.68	0.74	< 0.001
Pneumonia	0.76	0.73	0.79	< 0.001
Injury	0.84	0.80	0.87	< 0.001
Hyperthyroidism	0.95	0.91	0.99	0.034
Liver disease	0.79	0.76	0.82	< 0.001
Depression	0.79	0.76	0.82	< 0.001
Sepsis	0.93	0.89	0.97	0.011
Lung cancer	0.74	0.68	0.80	< 0.001
Female breast cancer	0.79	0.72	0.86	< 0.001
Prostate cancer	0.69	0.61	0.79	< 0.001

Notes: aAdjusted for the listed variables. A p-value < 0.001 was considered statistically significant.

Abbreviations: HR, hazard ratio; CI, confidence interval; DM, diabetes mellitus; CHD, congestive heart disease; CKD, chronic kidney disease; COPD, chronic obstructive pulmonary disease; HTN, hypertension; IHD, ischemic heart disease.

Discussion

In this study, we performed a large-scale investigation using data from the NHIRD. The results demonstrated that the overall mortality is lower in the surgery group than in the non-surgery group; moreover, the surgery group is associated with a significantly lower risk of mortality (aHR = 0.7) than the non-surgery group after adjustment for sex, age, and comorbidities. The stratified analysis in our study also demonstrated that the risk of mortality in the surgery group decreased consistently in certain cancers and each comorbidity subgroup, except in those of hyperthyroidism and sepsis. These findings could be attributed to the following: first, the goals of surgery for BM include local tumor control, providing structural stability, and restoration of function; therefore, patients in the surgery group may have had a better QOL and ability to perform daily functions, which possibly protected them from the risk of mortality due to diseases other than their primary cancer. Second, the patients possibly had good control of the primary malignancy and a relatively healthy status. Thus, they were willing to undergo surgery, or were suitable for surgery, thereby leading to a better prognosis. The location of BM also played a significant role. Surgeons tend to operate on lesions that are solitary, surgically accessible, and could cause less morbidity post-operatively. Up to 98.9% of patients in the non-surgery group had BM of the axial skeleton or multiple sites, while that for patients in the surgery group was 93.5%. Hence, there may have been a bias in selection. Even so, with the advancement of medical instruments and surgical techniques, the location of lesions may not be a limiting factor. The trend of surgery for BM has increased steadily in the present study (Figure 3). In our study, comorbidities (except for pneumonia and sepsis) were more prevalent in the surgery group. Additionally, the average age of the patients in the surgery group was higher than that of those in the non-surgery group. There was no evidence that patients in the surgery group had better health status than those in the non-surgery group.

There have been numerous studies attempting to investigate the prognostic factors among patients with BM and identify candidates suitable for surgery. In a previous prospective study, pathological fracture, visceral metastases, hemoglobin < 7 mmol/L, and lung cancer were identified as independent negative prognostic factors for 1-year survival. Myeloma was the only positive factor identified, based on the skeletal metastasis registry of the Scandinavian Sarcoma Group.6 Recently, non-surgical treatments, such as targeted therapy (eg, gefitinib for epidermal growth factor receptor mutant non-small cell lung cancer), have improved the survival of cancer patients,7 with pertuzumab and trastuzumab increasing the median overall survival of patients with HER2-positive metastatic breast cancer.8 Evidence of prolonged survival time after surgery may change the attitude of both surgeons and patients towards surgical intervention, leading to an increased demand for surgery, particularly in cases with BM. Although a cure for metastatic bone disease remains a challenge, our study shows that surgery produces promising results.

Surgical strategies for BM must be individualized. For spinal metastases of breast cancer or prostate cancer, hormone therapy or radiotherapy is usually the first line of treatment before surgery.9,10 However, total en bloc spondylectomy may be beneficial when the lesion is solitary, and a long survival time is expected.11 Nonetheless, operative methods for spinal metastases differ according to the sites and sizes of metastases. After the axial skeleton, the pelvic bone is the second most common site of BM.12 Pelvic bone surgery is a demanding operation both for the surgeons and the patients. A retrospective study of 83 patients who underwent surgery for metastases to the pelvis concluded that primary cancer type, serum albumin level, and visceral metastases influence survival.13 Considering that no standard procedures have been established, en bloc resection is generally performed with the intent to reduce tumor burden and cure patients with solitary metastases at accessible sites. Moreover, surgery is also beneficial for the repair of mechanical instability, pain relief, and the improvement of limb function and QOL in pathological long bone fractures.14,15 However, a retrospective study showed that the surgical outcomes, including blood loss, period of hospitalization, and recovery of function, are better for at-risk fractures than for pathologic fractures.16 Operative methods include internal fixation and prosthesis replacement.

Studies have shown that BRIs provide clinical benefits to patients with BM.17,18 To date, zoledronic acid is the most promising bisphosphonate, while denosumab is another potent agent that prevents bone destruction. However, these agents are associated with adverse events, such as osteonecrosis of the jaw, renal toxicities, and hypocalcemia.19,20 In our study, the proportion of patients using zoledronic acid, pamidronate disodium, and clodronate tetrahydrate was significantly lower in the surgery group than in the non-surgery group; however, there was no difference in the use of denosumab between the groups. This finding could be attributed to the requirement of BRIs in the non-surgery group since most patients had multiple BMs that could not be resolved by surgery, while most patients in the surgery group had solitary or oligometastatic disease. Moreover, surgery for BM may decrease the need for BRIs. Nevertheless, the administration of BRIs did not show a significant influence on mortality after adjustment for age, sex, surgery, and comorbidities.

This study has several limitations. First, the severity of the patients’ disease could not be determined from the database. Even among patients with the same primary tumor and BM, the severity may still differ, particularly since some patients may have solitary BM while others may have multiple BM, with or without visceral metastases. Thus, this study focused on all-cause mortality rather than cancer-related mortality to minimize the confounding effect of these variables. Second, other treatments performed for BM, such as radiotherapy, chemotherapy, targeted therapy, and local ablation/cryoablation, might have influenced patient survival. Based on the results, the percentage of patients receiving radiotherapy or chemotherapy was higher in the surgery group than in the non-surgery group (83.1% versus 78.6%). The trends for cancer management were multidisciplinary. However, it was difficult to match individual courses of treatment in this study. We therefore selected lung, breast, and prostate cancer as subgroups, which are known for their strong association with BM. Most patients within the same cancer subgroup might have undergone similar non-surgical treatments (eg, chemotherapy and hormonal therapy) in the therapeutic protocols. There was no significant difference in the distribution of hospital levels between both groups, implying that the quality of treatment and care might be similar. Third, the socioeconomic and educational status of patients were not recorded in the database. Thus, we were unable to determine the extent to which this confounding factor influenced our results, given that the cost associated with surgical treatment is high. Nevertheless, most medical procedures were included in the National Health Insurance of Taiwan and were thus affordable (universal health coverage in Taiwan is > 99%).21 Finally, surgical outcomes were not only related to survival but also the health status of the survivors, including post-operative morbidities, the length of hospital stay, and discharge destination. In the present study, it was difficult to define post-operative complications in the database owing to the variety in timing, situation, duration, and influence. Coincidentally, the discharge destination code had not been established in the database. However, during the study period, the surgery group did not surpass the non-surgery group in the average length of hospital stay. It seemed that surgery had not elongated hospital stay, despite possible surgical complications. These focused issues require further investigation in the future studies.

Conclusion

To the best of our knowledge, this is the first nationwide cohort study investigating the effect of surgical intervention for BM on mortality in advanced cancer. Unique strengths of the study are the inclusion of a demographically broad population, a follow-up period substantially longer than that in previously published outcome studies, and an insight into the effect of surgical intervention for BM stratified by various subgroups.

This study, involving a large cohort of cancer patients with BM, revealed that surgical treatment had not resulted in any additional risk on survival, regardless of age, sex, certain cancer types, and comorbidities. Further, this study has the potential to reduce the use of BRIs. Although there are multiple factors that can influence the survival rate of cancer patients with BM, we believe surgical resection could have a competitive role in the management of metastatic bone disease if applied properly, and the management of BM will continue to improve.