According to the National Comprehensive Cancer Network (NCCN) clinical practice guidelines,¹ local treatment is recommended when curative treatment is possible for CRLMs since it can greatly improve overall survival (OS). However, the number of colorectal liver metastases (CRLMs) is usually regarded as a contraindication for hepatectomy.^2,3 Multiple liver lesions directly reflect a higher tumour burden and further remarkably increase the technical difficulty and feasibility of curative treatment. However, with the increase in tumour response rates due to the popularity of systemic chemotherapy and targeted drugs^4–10 and the introduction of ablative technologies,¹¹ an increasing number of patients with initially unresectable liver metastases have the chance to achieve curative treatment of CRLM. In current clinical practice, patients with initially unresectable CRLMs are routinely recommended to undergo conversion treatment with the intent of curative treatment.^12–14

During recent decades, the cut-off value of the number of CRLMs that can be operable has also increased.^2,11,15,16 In the late 1980s, hepatectomy was considered difficult for patients with more than 3 liver metastases. However, the boundary for the number of liver metastases for resectability reached 5 in 2009.² A recent article proposed that patients with fewer than 10 liver metastases can undergo surgery for removal.¹⁶ As a result, the current clinical practice guidelines have excluded the tumour number from the constantly evolving criteria.^14,17

Although previous studies have discussed the role of radical local treatment in the prognosis of patients with a large number of CRLMs, they failed to exclude patients with extrahepatic metastases but instead regarded extrahepatic metastasis only as a risk factor. Moreover, the characteristics and treatment methods of patients with extrahepatic metastases are different from those of patients who have only liver metastases.^18–20 Therefore, it is doubtful that radical local treatment would still be the primary treatment option for patients with more than 10 initially unresectable metastases only in the liver after conversion therapy. This has motivated us to investigate the long-term survival benefit of these patients receiving conversion therapy. The purpose of this study was to evaluate the prognostic value of radical local treatment after first-line systemic treatment in patients with at least 10 liver-only metastases. Additionally, we aimed to determine the prognostic risk factors in these patients.

We analysed the clinical information of 229 consecutive CRLM patients who were confirmed to have initially unresectable CRLMs from December 2012 to January 2020 at Sun Yat-sen University Cancer Center. The criteria for selecting the subjects were as follows: (1) histologically diagnosed with colorectal adenocarcinoma, (2) metastases limited to the liver, (3) at least a 3-month follow-up period after first-line systemic treatment, and (4) no previous liver resection or interventional therapy. An electronic medical record system was used to obtain the clinical information and follow-up results of the patients. Informed consent was obtained from all patients whose clinical data were used. This study was approved by the Institutional Research Ethics Committee of Sun Yat-sen University Cancer Center (approval number: B2020-309-01).

The treatment strategy and operability of the liver metastases of each patient were determined according to the final agreement of the multidisciplinary team (MDT), consisting of members from the Departments of Colorectal Surgery, Hepatobiliary Surgery, Medical Oncology, Medical Imaging and Invasive Technology. Tumour response or progression after first-line treatment was evaluated based on the response evaluation criteria in solid tumours (RECIST).²¹ Conversion therapy was defined as initially unresectable liver metastasis converted to R0 resectable lesion after systemic chemotherapy. Successful conversion outcome refers to initially unresectable liver metastases becoming resectable after first-line systemic treatment with the patient showing no evidence of disease (NED) owing to radical local treatment, including surgery and radiofrequency ablation (RFA), while conversion failure outcome refers to liver metastases remaining unresectable after first-line systemic treatment, with the patient unable to receive curative local treatment. Hepatectomy resection was conducted only when the patient met the following criteria²⁰: (1) at least one of three liver veins was preserved; (2) more than 30%–40% remnant liver volume was preserved; and (3) the resection margin was at least 1 mm.

All patients were followed up every 3 months for the first 2 years after hepatectomy and then semi-annually until 5 years. Follow-up was conducted by well-trained nurses. Blood levels of carcinoembryonic antigen (CEA) were measured in each clinical review. Computed tomography (CT) imaging of the chest, abdomen and pelvis was performed at 3, 6, 12, 18 and 24 months and then annually thereafter. Liver magnetic resonance imaging (MRI) was carried out to identify suspicious lesions shown on CT or in cases with negative CT results and elevated levels of CEA. OS was calculated from hepatectomy to death of any cause or the last follow-up, while progression-free survival (PFS) was defined as the interval between hepatectomy and recurrence, death or last follow-up for patients with conversion and between first-line chemotherapy and disease progression, death or last follow-up for patients without conversion. The last follow-up visit took place in April 2021.

Statistical analyses were carried out with IBM SPSS Statistics 24 software (IBM), GraphPad Prism version 6.01 (GraphPad Software, Inc.,) and R software packages. Values are presented as the median (range) and percentage. The Kaplan–Meier (K–M) method with the log-rank test was used to compare PFS and OS. Parameters showing statistical significance in terms of conversion failure, OS and PFS in univariate logistic and Cox models were further analysed by multivariate logistic and Cox models. Odds ratios (ORs), hazard ratios (HRs) and 95% confidence intervals (CIs) were subsequently calculated. All statistical tests used in this study were two-sided, and a p value < 0.05 was considered statistically significant.

Table 1 presents an overview of the patient characteristics. Among 229 initially unresectable colorectal liver metastasis patients, 165 were males, 64 were female, and the median age was 56 (interquartile range (IQR) 47–62). The median number and IQR of CRLMs for patients with <10 CRLMs and ≥10 CRLMs were 4 (3,6) and 15 (12,27), respectively. All of the patients received first-line chemotherapy with a median course of 8 (IQR 6–10), and 164 (71.6%) patients received targeted therapy. After first-line chemotherapy, 112 (48.9%) patients achieved a partial response (PR), 63 (27.5%) patients achieved stable disease (SD), and 54 (23.6%) patients achieved progressive disease (PD). As a result, 105 (45.9%) patients received curative local treatment, including 38 (16.6%) patients who simply underwent hepatectomy and 67 (29.3%) patients who underwent hepatectomy combined with RFA.

TABLE 1 Patient demographics, tumour characteristics, and treatment in the total study population

Abbreviations: CEA, carcinoembryonic antigen; CRLM, colorectal liver metastases; FUDR HAI, fluorodeoxyuridine administered via hepatic arterial infusion; IQR, interquartile range; PD, progressive disease; PR, partial response; RECIST, response evaluation criteria in solid tumours; SD, stable disease.

As shown in Table 2, compared to patients with <10 CRLMs, a larger proportion of patients with ≥10 CRLMs had synchronous CRLMs (96.3% vs. 87.7% p = 0.036), bilobar disease (98.1% vs. 62.3% p < 0.001), and PD after systemic therapy (32.7% vs. 15.6%, p = 0.006) and underwent more than 8 courses of chemotherapy (46.7% vs. 31.1% p = 0.022). In addition, a lower proportion of patients with ≥10 CRLMs had successful conversion outcomes than patients with <10 CRLMs (42.7% vs. 56.6%, p = 0.001, Figure 1).

TABLE 2 Clinical characteristics of the patients stratified by a cut-off colorectal cancer liver metastasis number of 10

Abbreviations: CEA, carcinoembryonic antigen; CRLM, colorectal liver metastasis; FOLFOXIRI, folinic acid, 5-fluorouracil, oxaliplatin and irinotecan; FUDR HAI, fluorodeoxyuridine administered via hepatic arterial infusion; PD, progressive disease; PR, partial response; RECIST, response evaluation criteria in solid tumours; SD, stable disease.

^aData were available for 180 patients.

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FIGURE 1. The conversion condition of patients with [less than]10 or ≥10 colorectal cancer liver metastases

With a median follow-up time of 20 months (25%–75% quartiles: 14–32 months), 75 (32.8%) patients were alive with NED, 121 (52.8%) patients were alive with PD, and 33 (14.4%) patients experienced cancer-related mortality. Patients with <10 CRLMs had significantly higher 2-year OS rates than those with ≥10 CRLMs [77.2% (95% CI, 69.2–86.0%) vs. 52.7% (95% CI, 42.6–65.2%), p = 0.004] (Figure 2A). The univariable and multivariable Cox analyses identified ≥10 CRLMs as an independent predictor of OS (HR 1.629; 95% CI 1.007–2.636; p = 0.043) (Table S1). Among the patients with successful conversion outcomes, those with <10 CRLMs showed significantly higher 2-year OS rates than those with ≥10 CRLMs (89.9% [95% CI, 82.5–98.0%] vs. 58.2% [95% CI, 42.2–80.4%], P = 0.008) (Figure 2B). Among patients with conversion failure outcomes, patients with either <10 CRLMs or ≥ 10 CRLMs had similar 2-year OS rates (58.9% [95% CI, 45.2–76.7%] vs. 49.6% [95% CI, 37.5–65.7%]; P = 0.540) (Figure 2C). Among the patients with ≥10 CRLMs, those with successful or failed conversion had comparable 2-year OS rates (58.2% [95% CI, 42.2–80.4%] vs. 49.6% [95% CI, 37.5–65.7%], p = 0.160) (Figure 3A) and PFS rates (7.5% [95% CI, 3.0–18.9%] vs. 10.0% [95% CI, 2.9–34.7%], p = 0.640] (Figure 3B). Among the patients with <10 CRLMs, those with a successful conversion outcomes had significantly higher 2-year OS rates than patients with failed conversion (89.9% [95% CI, 82.5–98.0%] vs. 58.9% [95% CI, 45.2–76.7%], p < 0.001) (Figure 3C); however, these two groups of patients had comparable PFS rates (30.2% [95% CI, 19.4–46.9%] vs. 20.7% [95% CI, 11.5–37.4%], p = 0.150) (Figure 3D).

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FIGURE 2. Comparison of overall survival (OS) after first-line systemic therapy among all patients, patients with conversion success and patients with conversion failure. (A) Comparison of OS in the colorectal cancer liver metastases (CRLM) [less than]10 and CRLM ≥ 10 groups among all patients. (B) Comparison of OS in the CRLM[less than]10 and CRLM≥10 groups among patients with successful conversion outcomes. (C) Comparison of OS in the CRLM[less than]10 and CRLM≥10 groups among patients with failed conversion outcomes

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FIGURE 3. Comparison of overall survival (OS) and progression-free survival (PFS) after first-line systemic therapy among patients with [less than]10 or ≥10 colorectal cancer liver metastases (CRLMs). (A) Comparison of OS in the conversion success and conversion failure groups among patients with ≥10 CRLMs. (B) Comparison of PFS in the conversion success and conversion failure groups among patients with ≥10 CRLMs. (C) Comparison of OS in the conversion success and conversion failure groups among patients with [less than]10 CRLMs. (D) Comparison of PFS in the conversion success and conversion failure groups among patients with [less than]10 CRLMs

Table 3 presents the summary statistics for the univariate and multivariate logistic regression analyses. Univariate logistic analysis showed that baseline clinical N stage 1–2 (p = 0.016), ≥8 first-line chemotherapy courses (p = 0.002), and SD or PD after systemic treatment (p < 0.001) were strongly associated with conversion failure. Multivariate logistic analysis indicated that baseline clinical N stage 1–2 (OR 4.821; 95% CI 1.107–20.990; p = 0.036), ≥8 first-line chemotherapy courses (OR 3.847; 95% CI 1.388–10.665; p = 0.010), and a RECIST response of SD or PD (OR 7.408; 95% CI 2.803–19.575; p < 0.001) were still independent predictive factors for conversion failure.

TABLE 3 Univariate and multivariate logistic regression analyses of risk factors for conversion failure in patients with ≥10 colorectal liver metastases

Abbreviations: CEA, carcinoembryonic antigen; CI, confidence interval; OR, odds ratio; PD, progressive disease; PR, partial response; RECIST, response evaluation criteria in solid tumours; SD, stable disease.

Tables 4 and 5 summarise the univariate and multivariate Cox analyses of OS and PFS for patients with ≥10 CRLMs. Univariate analysis showed that primary tumour location in the right colon (p = 0.006), baseline clinical T stage 4 (p = 0.005), baseline clinical N stage 1–2 (p = 0.041), and a RECIST response of SD or PD (p = 0.001) were closely related to unfavourable OS, while the use of targeted therapy (p = 0.003) was beneficial to OS. In addition, primary tumour location in the right colon (p = 0.028) and SD or PD after systemic treatment (p = 0.017) were closely related to unfavourable PFS, while ≥8 first-line chemotherapy courses (p = 0.043) and the use of targeted therapy (p = 0.044) were beneficial to PFS.

TABLE 4 Univariate and multivariate Cox analyses of risk factors for overall survival in patients with ≥10 colorectal liver metastases

Abbreviations: CEA, carcinoembryonic antigen; CI, confidence interval; HR, hazard ratio; PD, progressive disease; PR, partial response; RECIST, response evaluation criteria in solid tumours; SD, stable disease.

TABLE 5 Univariate and multivariate Cox analyses of risk factors for progression-free survival in patients with ≥10 colorectal liver metastases

Abbreviations: CEA, carcinoembryonic antigen; CI, confidence interval; HR, hazard ratio; PD, progressive disease; PR, partial response; RECIST, response evaluation criteria in solid tumours; SD, stable disease.

Multivariate analysis revealed that primary tumour location in the right colon (HR 2.206; 95% CI 1.163–4.184; p = 0.015) and a RECIST response of SD or PD (HR 2.053; 95% CI 1.047–4.023; p = 0.036) were independent predictive factors for unfavourable OS, while the use of targeted therapy (HR 0.488; 95% CI 0.263–0.904; p = 0.022) was an independent predictive factor for favourable OS. In addition, SD or PD after systemic treatment (HR 1.944; 95% CI 1.212–3.118; p = 0.006) and ≥8 first-line chemotherapy courses (HR 0.605; 95% CI 0.381–0.960; p = 0.033) were independent predictive factors for unfavourable and favourable PFS, respectively.

The number of liver metastases has always been regarded as a risk factor against surgical resection,^2,3 but with improvements in surgical technology, the introduction of ablative technologies, and the increased popularity of preoperative chemotherapy and targeted drugs, the tumour response rate has been greatly improved, and an increasing number of patients with multiple liver metastases can receive curative treatment.^4–11 Our data showed that the OS of patients with or without successful conversion outcomes could not be distinguished among patients with ≥10 CRLMs but that the OS of patients with <10 and ≥10 CRLMs could be distinguished among those who had successful conversion outcomes.

The conversion rate of patients with ≥10 CRLMs was significantly lower than that of patients with <10 CRLMs (43.4% vs. 57.3% p = 0.001), which was in line with our expectations because patients with a higher number of CRLMs usually progress to the late stage of the disease, and the tumour burden is much higher in these patients than in those with a lower number of CRLMs. To ensure that there is no residual tumour tissue at the surgical margin, patients with ≥10 CRLMs often have more liver volume to be resected; however, liver resection requires a certain proportion of the liver volume to be preserved, so these patients have a lower probability of conversion.²² A previous study tried to improve the response rate by various means, including using new drugs, combining different regimens⁴ and introducing targeted therapy,^5,6 and the conversion rate increased accordingly. Cox multivariate analysis showed that a RECIST response of SD or PD and no use of targeted drugs were significantly associated with poor PFS and OS, suggesting that tumour response is a good predictor of prognosis, which is consistent with the previous studies.^3,14,16,23

Our results showed that the prognosis of patients with ≥10 CRLMs with successful conversion outcomes was similar to that of patients with failed conversion outcomes, which was inconsistent with the findings of a previous study.¹⁶ There may be have several explanations for this. First, our patients suffered from initially unresectable liver metastases. As a result, the operation of these patients was still more difficult than that of patients in the previous study, which might result in more postoperative complications.²⁴ In addition, patients with ≥10 CRLMs usually have many small nodules that are difficult to detect by CT and MRI.¹⁶ Even if so-called R0 or R1 resection is achieved, macroscopic tumours that cannot be detected can recur after resection. Moreover, chemotherapy for patients with ≥10 CRLMs will be more aggressive to meet the operation conditions, which might damage the liver without a nidus. It is worth mentioning that a large number of liver metastatic nodules indicates that the primary tumours are more aggressive, they often have worse pathological types, and some patients do not show good regression after chemotherapy, which leads to a poor prognosis.²⁵

From the results of multivariate analysis, whether patients received targeted therapy was an independent prognostic protective factor for patients with >10 metastases. This suggests that targeted therapy should be added when possible to the initial treatment plan for these patients, so effective systemic therapy should be performed in accordance with ESMO or NCCN guidelines.^14,26 Our findings also reveal that although a large number of metastases is not an absolute no-go area for NED, local treatment cannot effectively prolong the PFS of patients with >10 metastases, even after conversion therapy achieves resectable criteria, and the survival benefit of these patients is limited. This result demonstrates that local treatment may not be the only option we pursue. We believe that local treatment may be an option for this type of patient, but this needs to be carefully considered in combination with the patient's physical condition, tumour biological behaviour, and treatment willingness. In addition, our study showed that patients with more than 10 metastases and no local treatment had a very high chance of postoperative recurrence, which was accompanied by a worse prognosis. Therefore, the postoperative treatment strategy for such patients should be different from that of patients with <10 CRLMs. For patients with more than 10 CRLMs, adjuvant chemotherapy of sufficient duration and intensity should be ensured after surgery, and more frequent follow-up should be performed to detect recurrent lesions in time and receive the best treatment as soon as possible.

This study does have some limitations. First, the present study was a single-centre, retrospective study, which means that further validation of our hypothesis in other institutions is necessary. Second, RAS and BRAF are established prognostic factors; however, we failed to include them in our study due to the insufficient collection of this information. Moreover, the present study analysed only the short-term outcomes of patients with more than 10 initially unresectable CRLMs, so additional studies focusing on long-term survival are needed. In addition, since the proportion of patients with ≥10 CRLMs was relatively small, this population is highly selective, and we cannot ensure that identical outcomes would be observed in a less selective patient population.

The OS for patients with and without successful conversion outcome cannot be distinguished among patients with ≥10 CRLMs. Therefore, conversion therapy with the intent to perform radical local treatment may not be suitable for patients with 10 or more liver metastases from colorectal cancer.

We greatly appreciate the help from all of our colleagues in the Department of Colorectal Surgery at Sun Yat-sen University Cancer Center who were involved in administering the treatments in the current study.

None of the authors have conflicts of interest or financial ties to disclose.

JH Peng, JZ Lin and ZL Hou designed the study; H Sun, WL Zhang, ZG Hong acquired the data; H Sun and WL Zhang conducted the statistical analyses; JH Peng, H Sun and WL Zhang drafted the manuscript. All authors contributed to the interpretation of the results and critical revision of the manuscript for important intellectual content and approved the final version of the manuscript.

The datasets used and analysed during the current study are available from the corresponding author on reasonable request. The authenticity of this article has been validated by uploading the key raw data onto the Research Data Deposit public platform(www.researchdata.org.cn)with the approval RDD number of RDDA2022862738.