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This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

Colorectal cancer (CRC) is the third leading cause of cancer-related death in developed countries [1]. The liver is the commonest site of distant spread of CRC, and liver metastases occur in up to 60% of those patients [2, 3].

Surgical treatment is the cornerstone of management of CRC, apart from staging. Nevertheless, some authors believe in a promoting effects of surgery on tumor spread stating that manipulation of the tumor and its vessels may promote tumor spillage, production of growth factors, and reduction of the release of antiangiogenic factors [4, 5]. On the contrary, other authors suggest that removal of at least great majority of tumor burden may reduce proinflammatory effects and the release of circulating malignant cell leading to a better control of metastasizing cells from host immunity [6, 7]. Due to the technical and technological improvements in liver surgery and perioperative care, hepatic resection has become at least a part of the standard of care in metastatic CRC. Indications to liver resection have been widened along the past 3 decades maintaining acceptable morbidity and mortality rates [8]. Nowadays, patients are considered suitable for surgery if all the disease can be resected with negative margins and preserving an adequate liver remnant [9, 10]. Unfortunately, only about 25% of the patients affected meets these criteria [3]. Moreover, a multimodality and multidisciplinary evaluation and treatment, when appropriate, is of paramount importance in this selected group of metastatic patients in order to provide the best chances of cure [11, 12].

In patients fit for surgery, resection may provide 5-year survival rates of 40–74% [9, 11, 12], 10-year survival rates of 16–23%, and a cure rate of 20% [10] compared to a 5-year survival rate of about 5% in case of palliative treatments [3]. On the other hand, recurrence rate is reported to be high (60–80%) with a 10–15% of early recurrence and disease-specific deaths [8].

In order to help in the selection of the more appropriate treatment, some prognostic factors in patients suffering from CRC and metastatic CRC have been identified [2, 3, 8, 10]. The aim of this study is to verify and analyze different factors which may affect disease-free survival (DFS) and overall survival (OS). They are either related to the patient, to the primitive CRC, or liver metastasis in the selected group of patients who underwent liver resection for first and isolated recurrence of colorectal cancer. Its perspective is the identification of the subgroups of patients who could benefit more from surgical resection in order to improve patient selection and the choice of adequate timing for liver resection within a multimodality treatment.

2. Materials and Methods

2.1. Study Design and Patients

From February 2006 to February 2018, all the patients affected by “liver only” first metastasization from CRC who underwent potentially curative surgical resection at the Hepatobiliary Surgery Unit of Careggi Teaching Hospital were included in the study. Patients undergoing intraoperative radiofrequency ablation (RFA) with a curative intent were also included. Patients with a primary rectal squamocellular carcinoma were excluded. Preoperative workup included triple phase-contrast enhanced computed tomography (CT) scan and pancolonoscopy. Liver volume assessment was performed when indicated. Magnetic resonance and positron emission tomography (PET) scan were used to rule out doubtful cases. Intraoperative ultrasound sonography (IOUS) was routinely used during liver surgery. Follow-up was done according to a standardized scheduled program including CT scan or abdominal ultrasound, colonoscopy, and blood test examination. It could be modified according to oncologist’s indications. Retrieval of follow-up data was completed including the revision of any available medical records and phone call interviews.

Day of liver surgery was chosen as reference date. Disease-free interval was considered as the time between liver surgery and the diagnosis of any site of recurrence of disease or until the date of death while overall survival was considered as time between the liver surgery and the date of death or the last visit for alive patients. Recurrences were treated with surgery, chemotherapy, radiotherapy, percutaneous treatment, combinations of them, or best supportive care as appropriate.

According to timing of metastasis presentation/treatment, patients were divided into 3 groups: “synchronous combined surgery” that included patients who underwent combined surgery for primary tumor and liver metastasis, “synchronous bowel first” that included patients with metastatic disease from the beginning of their neoplastic history but liver metastases were not treated during colorectal surgery, and “metachronous” that included patients who developed liver metastasis after colorectal cancer surgery. The decision to perform combined or delayed surgery in synchronous presentation with or without any perioperative chemotherapy was discussed during Hospital Tumor Board meetings. Patient’s conditions (i.e., comorbidities, bowel obstruction) and wishes, number, dimension, and position of the liver metastases at preoperative examination (confirmed or not at surgery time) were taken into account. Right colon comprehended lesions located from the cecum to transverse; left colon included also lesions located in the rectum. In univariate analysis, converted procedures were grouped with open surgery because this study is not an “intention-to-treat” analysis. Peritoneal resection was defined as any resection of the anterior aspect of the peritoneum macroscopically adherent/infiltrated by the primary tumor. Major hepatectomies were defined as resection of at least 3 segments according to Brisbane’s classification [13]. Postoperative complications occurred after hepatic resections were evaluated if classified as at least grade 3 or 4 according to Clavien-Dindo classification [14]. Chemotherapy before and after liver surgery was considered if administered to the patient despite the interruption of the initially scheduled program. The lesion size (maximum diameter for both primary and metastatic tumors) and number of hepatic metastases resected were retrieved from histopathological response. T stage was classified according to American Joint Committee on Cancer (AJCC) TNM staging system, 7th edition definition [15]. Positive liver margins were defined in presence of neoplastic cells within the surface of resected liver.

2.2. Analysis

Patients’ data were prospectively collected into a database which was retrospectively reviewed. Continuous variables were reported as median and range while categorical variables were reported as frequency and percentage. Differences between the three groups were analyzed using the Kruskal-Wallis test for continuous variables, while categorical variables were compared using the $χ^{2}$ or Fisher exact test when appropriated. Statistical significance was defined as $p$ value ≤ 0.05.

For univariate analysis, estimate of DFS and OS rates was calculated according to the Kaplan-Meier methods and compared using log-rank test. Hazard ratios (HR) and their 95% confidence intervals (CI) were calculated by means of the Cox proportional hazard model. The multivariate Cox regression model was used to evaluate the independent effect on DFS and OS of any factors whose $p$ value was ≤0.15 at the univariate analysis. Parameters related to the histopathological response on liver specimens (i.e., number of resected lesions, maximum diameter, and liver margin status) were not considered in multivariate analysis because of their unavailability in the 7 patients who underwent intraoperative curative RFA alone in order to avoid their exclusion from this analysis.

Data were analyzed using the statistical software SAS version 9.2 (SAS Corporation, Cary, NC).

3. Results and Discussion

3.1. Results

3.1.1. Patient Characteristics

Overall, 70 patients were included in the study. Median follow-up was 37 months (range 1–119). In particular, median follow-up among survivors was 48 months (range 2–116). Analyzed patient characteristics are displayed in Table 1. Patients undergoing combined surgery were 25, a two-step surgery was performed in 14 patients, and metachronous presentation of metastases was seen in 31 patients. Age, sex, and primary tumor distribution were similar within these three groups. Chemotherapy before liver surgery was administered in a very low percentage (8%) of “combined surgery” group ( $p < 0.0001$ ).

Table 1

Patients’ characteristics.

	Synchronous combined surgery ( $n = 25$ ) (35.7%)	Synchronous “bowel first” ( $n = 14$ ) (20%)	Metachronous ( $n = 31$ ) (44.3%)	Total ( $n = 70$ )	$p$ value
Age (years, range)	68 (34–85)	75 (46–82)	70 (52–85)	69.5 (34–85)	0.730
Sex ( $n$ , %)					0.683
Male	15 (60%)	9 (64.3%)	16 (51.6%)	40 (57.1%)
Female	10 (40%)	5 (35.7%)	15 (48.4%)	30 (42.9%)
Bowel obstruction ( $n$ , %)	5 (20%)	7 (50%)	7 (22.6%)	19 (27.1%)	0.097
Site of primary tumor ( $n$ , %)					0.343
Right colon	8 (32%)	2 (14.3%)	11 (35.5%)	21 (30%)
Left colon	17 (68%)	12 (85.7%)	20 (64.5%)	49 (70%)
CHT before liver surgery	2 (8%)	11 (78.6%)	20 (64.5%)	33 (47%)	<0.0001

CHT = chemotherapy.

Perioperative results are shown in Table 2. Open surgery technique ( $p = 0.006$ ) and minor/parenchymal-sparing liver resection ( $p = 0.024$ ) were more frequently applied in “combined surgery” group. ASA score and postoperative complication distribution in the 3 groups were similar with an overall median rate of severe complications after liver surgery of 14.3%. A statistically significant difference in the 3 groups was found for the administration of chemotherapy after liver surgery ( $p = 0.032$ ) with the lowest percentage (28.6%) in “bowel first” group.

Table 2

Perioperative results.

	Synchronous combined surgery ( $n = 25$ ) (35.7%)	Synchronous “bowel first” ( $n = 14$ ) (20%)	Metachronous ( $n = 31$ ) (44.3%)	Total ( $n = 70$ )	$p$ value
Colorectal surgery
Technique ( $n$ , %)					0.006
Open	15 (60%)	5 (35.7%)	7 (22.6%)	40 (57.1%)
Minimally invasive	5 (20%)	9 (64.3%)	17 (54.8%)	31 (44.3%)
Converted	5 (20%)	0	7 (22.6%)	12 (17.1%)
Peritoneal resection ( $n$ , %)	2 (8%)	1 (7.1%)	2 (6.4%)	5 (7.1%)	1.00
Liver surgery
ASA ( $n$ , %)					0.522
1	3 (12%)	1 (7.1%)	2 (6.4%)	6 (8.6%)
2	7 (28%)	4 (28.6%)	11 (35.5%)	22 (31.4%)
3	11 (44%)	6 (42.9%)	17 (54.8%)	34 (48.6%)
4	4 (16%)	3 (21.4%)	1 (3.2)	8 (11.4)
Type of surgery ( $n$ , %)					0.024
Minor/wedge	22 (88%)	7 (50%)	17 (54.8%)	46 (65.7%)
Major	3 (12%)	4 (28.6%)	10 (32.3%)	17 (24.3%)
RFA	0	3 (21.4%)	4 (12.9%)	7 (10%)
Surgery duration (min, range)	300 (170–145)	242.5 (175–369)	230 (50–315)	255 (50–450)	<0.0001
Complications (CD III-IV) ( $n$ , %)	3 (12%)	3 (21.4%)	4 (12.9%)	10 (14.3%)	0.743
CHT after liver surgery ( $n$ , %)	18 (72%)	4 (28.6%)	17 (54.8%)	39 (55.7%)	0.032

ASA = American Society of Anesthesiologists; Minor/wedge = minor hepatectomies/hepatic wedge resections; Major = major hepatectomies; RFA = radiofrequency ablation; CD III-IV = Clavien-Dindo classification grade III-IV; CHT = chemotherapy.

Analyzed histopathological results are shown in Table 3. T4 stage ( $p = 0.065$ ) and bigger primary tumors ( $p = 0.024$ ) were more frequently ( $p = 0.065$ ) found in “bowel first” group. Lower median number ( $p = 0.334$ ) and smaller size of liver metastases were reported in “combined surgery” group specimens (24 mm versus 35 mm in the other 2 groups, $p = 0.005$ ). Higher frequency of positive liver margins ( $p = 0.015$ ) was found in “bowel first” group. Tumor grading was not evaluated since almost all the patients presented a G2 primary tumor. KRAS or BRAF evaluation was not available in 55.7% of the patients; consequently, this variable was not analyzed. However, 24 patients had a RAS wild-type while 15 patients presented a RAS mutation.

Table 3

Histopathological results.

	Synchronous combined surgery ( $n = 25$ ) (35.7%)	Synchronous “bowel first” ( $n = 14$ ) (20%)	Metachronous ( $n = 31$ ) (44.3%)	Total ( $n = 70$ )	$p$ value
Colorectal specimen
Size (mm, range)	35 (17–130)	54 (25–90)	35 (4–82)	40 (4–130)	0.024
T stage $^{*}$ ( $n$ , %)					0.065
1-2	2 (8%)	4 (28.6%)	5 (16.1%)	11 (15.7%)
3	22 (88%)	8 (57.1%)	26 (83.9%)	56 (80%)
4	1 (4%)	2 (14.3%)	0	3 (4.3%)
Nodes harvested ( $n$ , range)	17 (7–76)	25 (6–48)	26 (9–50)	22 (6–76)
Positive nodes ( $n$ , range)	2 (0–10)	3.5 (0–17)	1 (0–12)	2 (0–17)	0.217
Mucinous histotype	3 (12%)	1 (7.1%)	9 (29%)	13 (18.6%)	0.159
Liver specimen	$n = 25$	$n = 11$	$n = 27$	$n = 63$
Resected lesions ( $n$ , range)	1 (1–11)	2 (1–6)	1 (1–4)	1 (1–11)	0.334
Size (mm, range)	24 (4–50)	35 (15–80)	35 (12–110)	30 (4–110)	0.005
Positive margins ( $n$ , %)	0	3 (27.3%)	1 (3.7%)	4 (6.35)	0.015

$^{*}$ T stage according to TNM definition AJCC 7th edition.

3.1.2. Factors Associated with Disease-Free Survival (DFS) and Overall Survival (OS)

Recurrence after liver surgery was documented in 46 patients (66%). Early recurrence (within 6 months) occurred in 15 patients (21.4%), recurrence rate within the first year was 37% (26 patients), and no other recurrences were found after the third year from liver surgery. Median time between recurrence and death was 29 months (range 1–89 months). Ninety-day mortality was 1.4%.

Overall, 1-, 3-, and 5-year DFS rates were 59%, 17%, and 16%, respectively, with a median DFS rate of 15.2 months (95% CI 11.2–21.5). Overall, 1-, 3-, and 5-year OS rates were 94%, 68%, and 53%, respectively, with a median OS rate of 62.7 months (95% CI 43.7–67.8).

Results of univariate analysis of factors associated with DFS and OS are shown in Table 4.

Table 4

Univariate analysis of factors associated with disease-free and overall survival.

	$n$	DFS					OS
	$n$	1 y (%)	3 y (%)	5 y (%)	Median (months, CI)	$p$ value	1 y (%)	3 y (%)	5 y (%)	Median (months, CI)	$p$ value
Timing of metastases presentation/treatment						<0.0001					0.085
Synchronous combined	25	52	24	20	14.4 (7.2–27.8)		92	66	48	45.3 (31–NE)
Synchronous “bowel first”	14	16	0	0	6 (2–11.4)		84	45	22	23.6 (11.8–70.9)
Metachronous	31	83	19	19	23.5 (14–28.8)		100	78	67	65.7 (58.2–77.2)
Age						0.648					0.552
<65	21	57	14	14	15.2 (7.2–22.1)		100	69	69	67.5 (23.6–77.9)
≥65	49	59	19	16	16.2 (10.4–23.5)		91	68	46	53 (37.9–65.7)
Sex						0.574					0.929
Male	40	59	14	11	16.4 (8.9–21.7)		95	75	57	64.2 (44.4–NE)
Female	30	58	22	22	14 (8.3–23.7)		93	58	49	38.1 (27.1–119.3)
Bowel obstruction						0.860					0.985
No	51	59	17	15	16.4 (10.4–21.7)		92	69	52	62.6 (43.7–70.9)
Yes	19	56	17	0	12.7 (4.2–28.7)		100	64	57	65.7 (21.7–119.3)
Site of primary tumor						0.488					0.661
Right colon	21	60	20	20	16.2 (8.5–29.4)		90	53	41	37.9 (17.1–77.2)
Left colon	49	58	16	13	15.2 (9.4–19.2)		96	74	60	64.7 (44.4–67.8)
CHT before liver surgery						0.080					0.531
No	37	62	23	20	19.2 (8.5–28.7)		92	71	52	62.6 (37.9–77.2)
Yes	33	54	10	10	12.7 (9.4–18)		97	63	58	62.7 (31.1–70.9)
Colorectal surgery
Technique						0.885					0.058
Open and converted	39	60	15	15	16.2 (8.9–24.8)		92	61	44	45.3 (31.3–67.1)
Minimally invasive	31	57	20	16	15.2 (8.3–23.5)		97	78	72	NE (43.7–NE)
Peritoneal resection						0.414					0.026
No	65	60	17	15	16.4 (11.8–21.7)		97	72	56	62.7 (44.3–67.8)
Yes	5	40	20	20	3.3 (1.3–NE)		60	20	20	12.4 (1.3–NE)
Liver surgery
ASA						0.003					0.036
1-2	28	73	38	33	21.5 (12.4–67.8)		92	79	62	67.8 (45.3–NE)
3	34	52	6	6	12.6 (7.2–22.4)		97	67	54	62.6 (32–67.1)
4	8	38	0	0	10.9 (1.3–19.2)		88	38	25	20.5 (1.3–NE)
Type of surgery						0.060					0.024
Minor/wedge	46	59	22	19	18 (10.4–27.8)		93	69	57	65.7 (43.7–NE)
Major	17	69	13	13	14 (6–21.5)		94	54	34	37.9 (14–62.7)
RFA	7	29	0	0	5 (1.5–18)		100	86	86	62.6 (12.4–119.3)
Surgery duration						0.999					0.945
<255 min	34	67	13	13	18 (12–25)		94	71	55	64.7 (38.1–67.8)
≥255 min	36	51	21	18	12.4 (8.5–21.7)		94	65	51	62.6 (31.1–70.9)
Complications (CD III-IV)						0.441					0.721
No	60	59	18	16	16.2 (10.4–22.1)		95	68	53	62.6 (38.1–67.5)
Yes	10	58	12	12	12.6 (1.3–30.9)		89	67	53	77.2 (9.2–77.2)
CHT after liver surgery						0.028					0.047
No	31	48	14	9	12 (5–18.1)		90	61	43	53 (19.2–70.9)
Yes	39	67	20	20	18 (11.8–27.8)		97	72	50	67.1 (44.4–70.9)
Colorectal specimen
Size						0.510					0.188
≤33 mm	26	60	8	8	18 (8.9–21.7)		100	79	57	62.7 (45.3–70.9)
34–49 mm	20	69	24	16	23.5 (7.3–29.4)		95	72	64	65.7 (32–119.3)
≥50 mm	24	48	22	22	11.8 (6–15.2)		87	51	40	37.9 (12.6–67.8)
T stage						0.002					0.347
1-2	11	51	10	10	12.4 (5–21.6)		90	68	28	53 (6–77.2)
3	56	62	19	17	16.6 (11.8–23.5)		96	68	59	64.7 (43.7–67.7)
4	3	0	0	0	3 (2–3.3)		50	50	50	40 (9.2–70.9)
Positive nodes						0.098					0.018
0	25	75	21	21	20.3 (12.4–28.8)		96	86	65	67 (53–119.3)
1–3	21	54	21	16	14.4 (5.8–28.7)		100	83	64	64.7 (37.9–70.9)
4+	24	46	10	10	10.4 (3.6–16.6)		87	37	31	21.7 (14–77.2)
Mucinous histotype						0.940					0.286
No	57	58	17	15	58.2 (38–67)		96	68	50
Yes	13	60	17	17	(9–119.3)		84	67	67
Liver specimen
Resected lesions						0.0001					0.066
1	35	73	26	22	21.6 (15.2–28.7)		91	74	56	64.7 (43.7–77.2)
2-3	20	63	16	16	14.4 (7.3–23.5)		95	60	54	62.7 (21.7–NE)
4+	8	13	0	0	5.7 (1.9–8.5)		100	43	14	27.1 (13.9–38.1)
Size						0.199					0.088
I tertile	20	55	20	15	17.2 (8.5–25)		90	73	50	60.4 (31.3–67.5)
II tertile	22	73	25	25	22.5 (12–28.8)		95	75	60	NE (32–NE)
III tertile	21	57	11	11	12.6 (5–24.8)		94	45	39	31.5 (14–70.9)
Margin status						0.032					0.859
Negative	59	63	20	18	16.5 (12–23.5)		100	66	50	58.2 (37.9–67.5)
Positive	4	38	0	0	4.8 (2–15.2)		93	50	50	47.2 (23.6–70.1)

NE = not evaluable; CHT = chemotherapy; ASA = American Society of Anesthesiologists; Minor/wedge = minor hepatectomies/hepatic wedge resections; Major = major hepatectomies; RFA = radiofreqency ablation; CD III-IV = Clavien-Dindo classification grade III-IV. T stage according to TNM definition AJCC 7th edition.

Disease presentation and treatment timing (Figure 1) significantly affected DFS ( $p < 0.0001$ ) but not OS ( $p = 0.085$ ). Metachronous group had a median DFS of 23.5 months compared to 14.4 months of DFS for “combined surgery” group and 6 months for “bowel first” group. Compared to “combined surgery group”, “bowel first” group had an HR of 3.9 (95% HR CI 1.8–8.2) for DFS.