The Systemic Immune-Inflammation Index is an Independent Predictor of Survival in Breast Cancer Patients.

PURPOSE: The current investigation examines the potential clinical value and prognostic significance of a systemic immune-inflammation index (SII) in patients with breast cancer. PATIENTS AND METHODS: A total of 477 individuals underwent neoadjuvant chemotherapy, and 308 individuals did not at our center between January 1998 and December 2016 were selected. An optimized SII threshold was generated using a receiver operating characteristic curve (ROC). The relationship between various factors and breast cancer in predicting disease-free survival (DFS) and overall survival (OS) were analyzed.
RESULTS: The SII < 560 group (Low SII group) and SII ≥ 560 group (High SII group) are divided according to the threshold value. SII was an independent predictor for breast cancer DFS and OS based on univariate and multivariate analyses. Low SII patients had higher mean DFS and OS in contrast to those in the high SII groups (46.65 vs 27.37 months and 69.92 vs 49.53 months). Those in the low SII cohort who also had early or advanced breast cancer, different molecular subtypes, and with or without lymph vessel invasion all had higher mean survival time of DFS and OS in contrast to those with raised SII values (P<0.05). The mean DFS and OS durations also varied based on different Miller and Payne grades (MPG) (P <0.005), and different response groups (P<0.05).
CONCLUSION: SII can be used as an easily accessible and minimally invasive potential prognostic factor in individuals with breast cancer and may also guide clinicians in treating and prognosticating patients with breast cancer.

Introduction

Breast cancer is perhaps the most frequently encountered malignant tumor around the world. Breast cancer significantly impacts patient quality of life while also posing as a major public health problem.1 GLOBOCAN 2018 reports that there are more than 2 million new cases of breast cancer and 600,000 deaths from breast cancer each year. The incidence of breast cancer has been on the rise annually, and the age of onset has been getting progressively younger.2 Data from National Cancer Center shows that there are 545.29 new cases in every 100,000 people in China every year. Breast cancer has been on the rise, especially in the developing coastal cities, with incidences higher amongst the urban compared to the rural populations. It is estimated that there will be as many as 100 new cases of breast cancer in every 100,000 people amongst postmenopausal women in the future.3 Some studies have pointed out that some immunological indicators (such as PD1, PD-L1, etc.) and histopathological indicators (such as ER, PR, HER2, Ki67, etc.) are closely associated with breast cancer prognosis. However, the acquisition of these indicators is costly and takes very long to be processed, thus greatly limiting their application in clinical treatment.4–7 The tumor microenvironment strongly features inflammation, with minor changes in inflammatory cell profiles having the ability to affect tumor development and progression, including the proliferation, invasion, migration and metastasis of tumor cells.8,9 Recent clinical and epidemiological studies have also found that the inflammatory response shares a certain relationship with breast cancer, and may potentially be targeted for tumor treatment or quantified as a prognostic indicator.10,11 Peripheral venous blood parameters, such as platelet (P), monocyte (M), lymphocyte (L), neutrophil (N), and its derivatives in PLR (platelet/lymphocyte ratio), NLR (neutrophil/lymphocyte ratio), MLR (monocyte/lymphocyte ratio), and LMR (lymphocyte/ monocyte ratio) were previously found to be prognostic in breast cancer patients.12–17 Breast cancer is currently diagnosed based on the gold standard of a combination of core needle biopsy (CNB) and pathological examination, assisted by breast imaging techniques of breast ultrasound, mammography, and magnetic resonance (MR). However, relatively speaking, the peripheral blood examination has the characteristics of simplicity, convenience, strong reproducibility, low cost, and better accessibility. Therefore, our study aims to determine and characterize the value of the prognostic factor of components of the peripheral blood count examination that are relevant to breast cancer,

Materials and Methods

Study Population

A total of 477 patients with neoadjuvant chemotherapy (NACT) and 308 patients who did not receive preoperative chemotherapy who were treated between January 1998 and December 2016 were selected. All included patients underwent a routine examination and examination on admission, a comprehensive assessment of their condition, and provided informed signed consent. All patients had a histopathological diagnosis of breast cancer. TNM stage was determined using the 8th edition American Joint Committee on Cancer (AJCC) and the Union for International Cancer Control (UICC).18,19

Inclusion and Exclusion Criteria

The inclusion criterion was as follows: 1) Breast cancer was confirmed by CNB and pathological examination; 2) Zubrod-Ecog-WHO (ZPS) between 0 and 2 and Karnofsky Performance Scores (KPS) ≥80; 3) Expected to survive more than 3 months; 4) Surgically treated; 5) Admission examination showed no obvious abnormalities in liver, kidney, lung, heart, brain, and bone marrow; 6) Inpatient medical records and postoperative follow-up data were complete.

The following was our exclusion criteria: 1) The possibility of distant organ metastasis was not able to be excluded on imaging examinations such as abdominal B-ultrasound, chest Computed Tomography (CT), and breast MRI, or the breast tumor was not able to be resected due to the definite presence of metastasis; 2) Patients who received anti-tumor therapy, such as radiotherapy, chemotherapy, and targeted therapy; 3) The presence of serious comorbidities that were refractory to treatment such as hypertension, heart disease, and diabetes; 4) Advanced breast cancer, including breast cancer ulcers, inflammatory breast cancer, and infected tumors; 5) Blood transfusion history within one month before receiving NACT; 6) Patients who were poorly compliant and not cooperative with treatment.

Chemotherapy Regimen

Patients with neoadjuvant chemotherapy were included with anthracyclines and/or taxanes, such as AC regimen, ACF regimen, CT regimen, ACT regimen, AT regimen, TP regimen.

Peripheral Venous Blood Collection Method

Patients consented to the collection of peripheral venous blood samples, which were collected using a vacuum anticoagulant tube and analyzed by the laboratory of our hospital. The white blood cell, neutrophils, hemoglobin, lymphocytes, monocytes, platelets, and other hematological parameters in the peripheral venous blood were analyzed. The SII was derived using the following formula: (neutrophil count × platelet count)/lymphocyte count.

Evaluation Assays

Tumor size, the depth of invasion, and the extent of lymph node metastasis were determined by breast ultrasound, mammography, and MRI. Tumor size was derived using the largest diameter as the diameter of the tumor. The 8th edition of AJCC and UICC was used to guide TNM staging.18,19 The main pathological types of breast cancer are invasive lobular or ductal carcinomas. Molecular classification of breast cancer commonly used are Luminal A-type, Luminal B HER2-positive type, Luminal B HER2-negative type, HER2 overexpression type, and triple-negative type.20 The Miller and Payne grade (MPG) histological grade was used to evaluate the reduction of tumor cells after neoadjuvant chemotherapy, which was divided into 5 grades.21 The tumor lesions after neoadjuvant chemotherapy treatment were evaluated according to the RECIST criteria that had been published and implemented in 2000.22 The histological classification of breast cancer is based on the Nottingham System (Scarff-Bloom-Richardson grading system by Elston and Ellis).23 Chemotherapy toxicity and adverse reactions were evaluated based on the National Cancer Institute Common Toxicity Criteria (NCI-CTC).24

Follow-Up

Follow-up was performed according to the NCCN (2020) guidelines: all patients were evaluated 3-monthly for the first 1–2 years, 6-monthly for the following 3–5 years, then annually until death. Disease-free survival (DFS) was defined as the duration between the first postoperative day to the detection of tumor recurrence, distant metastasis, or death from other causes. The time from the first day after surgery until the last follow-up or death was defined as Overall Survival (OS).

Statistical Analysis

All statistical analyses were carried out using the SPSS 17.0 (version 17.0; SPSS Inc., Chicago, IL, USA) and GraphPad Prism Software (Version 8.0; GraphPad Inc., La Jolla, CA, USA) program. ROCs were utilized to identify critical optimal threshold values of related variables, and the accuracy of prognosis was evaluated by the area under the curve (AUC). The number of cases (%) was incorporated in describing qualitative data, and the χ2 test or Fisher’s exact test was used for comparison between groups. Overall survival time was evaluated using the Kaplan-Meier assay. The survival rate between various groups was compared using the Log Rank method. Univariate and multivariate Cox Proportional Hazards Regression Models were used to analyze relevant prognostic factors. The relationships between various parameters and breast cancer prognosis were described using hazard ratios (HRs) and 95% confidence intervals (CIs). Statistical significance was determined with a two-tailed P value of less than 0.05.

Results

Demographic and Clinicopathologic Characteristics of All Breast Cancer Patients

The optimal cutoff value of SII was 560 based on ROC curve analysis. All patients were grouped into either the low (< 560) or the high SII group (> 560). All enrolled patients were female who were between 22 to 82 years of age (median age 47 years). BMI ranged from 16.36 to 38.19, with a median BMI of 24. 493 patients were premenopausal patients (62.80%), and 292 patients were postmenopausal (37.20%). ABO blood group distribution showed that there were 214 cases of type A (27.26%), 262 cases of type B (33.38%), 234 cases of type O (29.81%), and 75 cases of type AB (9.55%). 416 cases (52.99%) had left breast cancer, and 369 cases (47.01%) had right breast cancer. All patients received surgical treatment. 606 cases (77.20%) underwent total resection of breast cancer, and 179 cases (22.80%) underwent breast-conserving surgery. Based on the histological classification of breast cancer, there were 133 cases of grade I (16.94%), 431 cases of grade II (54.90%), and 221 cases of grade III (28.15%). Based on clinicopathological stages, there were 92 cases of stage I (11.72%), 382 cases of stage II (48.66%), and 311 cases of stage III (39.62%) prior to treatment. There were 516 cases (65.73%) who received postoperative chemotherapy and 269 cases (34.27%) who did not. There were 483 cases (61.53%) who received endocrine therapy after breast cancer surgery and 302 cases (38.47%) who did not. There were 202 cases (25.73%) who received targeted therapy after breast cancer surgery, while 583 cases (74.27%) did not. The clinical data of 785 breast cancer patients are shown in Table 1.

Table 1

Demographic and Clinicopathologic Characteristics of 785 Patients with Breast Cancer

Parameters	N	SII 785				N	SII 477				N	SII 308
Cases (n)	785	Low SII 398	High SII 387	χ2	P value		Low SII 217	High SII 260	χ2	P value		Low SII 181	High SII 127	χ2	P value
Age (years)				2.794	0.095				1.973	0.160				1.172	0.279
<47	386(49.17%)	184(46.23%)	202(52.20%)			230(48.22%)	97(44.70%)	133(51.15%)			156(50.65%)	87(48.07%)	69(54.33%)
≥47	399(50.83%)	214(53.77%)	185(47.80%)			247(51.78%)	120(55.30%)	127(48.85%)			152(49.35%)	94(51.93%)	58(45.67%)
Marital status				0.756	0.385				1.772	0.183				0.039	0.843
Married	756(96.31%)	381(95.73%)	375(96.90%)			457(95.81%)	205(94.47%)	252(96.92%)			299(97.08%)	176(97.24%)	123(96.85%)
Unmarried	29(3.69%)	17(4.27%)	12(3.10%)			20(4.19%)	12(5.53%)	8(3.08%)			9(2.92%)	5(2.76%)	4(3.15%)
Occupation				3.256	0.196				1.158	0.560				4.290	0.117
Mental worker	358(45.61%)	181(45.48%)	177(45.74%)			238(49.90%)	105(48.39%)	133(51.15%)			120(38.96%)	76(41.99%)	44(34.65%)
Manual worker	125(15.92%)	72(18.09%)	53(13.70%)			66(13.84%)	34(15.67%)	32(12.31%)			59(19.16%)	38(20.99%)	21(16.54%)
Others	302(38.47%)	145(36.43%)	157(40.57%)			173(36.27%)	78(35.94%)	95(36.54%)			129(41.88%)	67(37.02%)	62(48.82%)
Weight (Kg)				0.097	0.755				0.006	0.940				0.209	0.647
<62.00	383(48.79%)	192(48.24%)	191(49.35%)			235(49.27%)	107(49.31%)	128(49.23%)			148(48.05%)	85(46.96%)	63(49.61%)
≥62.00	402(51.21%)	206(51.76%)	196(50.65%)			242(50.73%)	110(50.69%)	132(50.77%)			160(51.95%)	96(53.04%)	64(50.39%)
Height (m)				0.492	0.483				0.161	0.688				0.049	0.825
<1.60	337(42.93%)	166(41.71%)	171(44.19%)			218(45.70%)	97(44.70%)	121(46.54%)			119(38.64%)	69(38.12%)	50(39.37%)
≥1.60	448(57.07%)	232(58.29%)	216(55.81%)			259(54.30%)	120(55.30%)	139(53.46%)			189(61.36%)	112(61.88%)	77(60.63%)
BMI				1.069	0.301				0.072	0.789				1.238	0.266
<24.00	391(49.81%)	191(47.99%)	200(51.68%)			245(51.36%)	110(50.69%)	135(51.92%)			146(47.40%)	81(44.75%)	65(51.18%)
≥24.00	394(50.19%)	207(52.01%)	187(48.32%)			232(48.64%)	107(49.31%)	125(48.08%)			162(52.60%)	100(55.25%)	62(48.82%)
Menarche age (year)				0.370	0.543				0.606	0.436				0.081	0.776
<14	308(39.24%)	152(38.19%)	156(40.31%)			196(41.09%)	85(39.17%)	111(42.69%)			112(36.36%)	67(37.02%)	45(35.43%)
≥14	477(60.76%)	246(61.81%)	231(59.69%)			281(58.91%)	132(60.83%)	149(57.31%)			196(63.64%)	114(62.98%)	82(64.57%)
Menopause				7.033	0.008				10.533	0.001				0.632	0.427
No	493(62.80%)	232(58.29%)	261(67.44%)			280(58.70%)	110(50.69%)	170(65.38%)			213(69.16%)	122(67.40%)	91(71.65%)
Yes	292(37.20%)	166(41.71%)	126(32.56%)			197(41.30%)	107(49.31%)	90(34.62%)			95(30.84%)	59(32.60%)	36(28.35%)
ABO blood type				1.347	0.853				0.754	0.945				2.030	0.930
A	214(27.26%)	103(25.88%)	111(28.68%)			132(27.67%)	56(25.81%)	76(29.23%)			82(26.62%)	47(25.97%)	35(27.56%)
B	262(33.38%)	135(33.92%)	127(32.82%)			145(30.40%)	67(30.88%)	78(30.00%)			117(37.99%)	68(37.57%)	49(38.58%)
O	234(29.81%)	124(31.16%)	110(28.42%)			146(30.61%)	68(31.34%)	78(30.00%)			88(28.57%)	56(30.94%)	32(25.20%)
AB	75(9.55%)	36(9.05%)	39(10.08%)			54(11.32%)	26(11.98%)	28(10.77%)			21(6.82%)	10(5.52%)	11(8.66%)
Tumor site				0.494	0.482				0.304	0.581				4.478	0.034
Right	369(47.01%)	192(48.24%)	177(45.74%)			233(48.85%)	103(47.47%)	130(50.00%)			136(44.16%)	89(49.17%)	47(37.01%)
Left	416(52.99%)	206(51.76%)	210(54.26%)			244(51.15%)	114(52.53%)	130(50.00%)			172(55.84%)	92(50.83%)	80(62.99%)
Clinical T stage				25.424	<0.0001				12.659	0.013				5.295	0.258
T1	168(21.40%)	91(22.86%)	90(23.26%)			65(13.63%)	35(16.13%)	30(11.54%)			103(33.44%)	56(30.94%)	47(37.01%)
T2	413(52.61%)	230(57.79%)	171(44.19%)			226(47.38%)	113(52.07%)	113(43.46%)			187(60.71%)	117(64.64%)	70(55.12%)
T3	131(16.69%)	57(14.32%)	73(18.86%)			115(24.11%)	49(22.58%)	66(25.38%)			16(5.19%)	8(4.42%)	8(6.30%)
T4	73(9.30%)	20(5.03%)	53(13.70%)			71(14.88%)	20(9.22%)	51(19.62%)			2(0.65%)	0(0.00%)	2(1.57%)
Clinical N stage				22.656	0.0002				7.165	0.127				7.192	0.126
N0	299(38.09%)	178(44.72%)	122(31.52%)			73(15.30%)	39(17.97%)	34(13.08%)			226(73.38%)	139(76.80%)	87(68.50%)
N1	233(29.68%)	115(28.89%)	117(30.23%)			164(34.38%)	78(35.94%)	86(33.08%)			69(22.40%)	37(20.44%)	32(25.20%)
N2	160(20.38%)	75(18.84%)	85(21.96%)			151(31.66%)	70(32.26%)	81(31.15%)			9(2.92%)	5(2.76%)	4(3.15%)
N3	93(11.85%)	30(7.54%)	63(16.28%)			89(18.66%)	30(13.82%)	59(22.69%)			4(1.30%)	0(0.00%)	4(3.15%)
Clinical TNM stage				21.459	<0.0001				6.364	0.042				5.348	0.069
I	92(11.72%)	54(13.57%)	38(9.82%)			14(2.94%)	8(3.69%)	6(2.31%)			78(25.32%)	46(25.41%)	32(25.20%)
II	382(48.66%)	218(54.77%)	164(42.38%)			168(35.22%)	88(40.55%)	80(30.77%)			214(69.48%)	130(71.82%)	84(66.14%)
III	311(39.62%)	126(31.66%)	185(47.80%)			295(61.84%)	121(55.76%)	174(66.92%)			16(5.19%)	5(2.76%)	11(8.66%)
Neoadjuvant Chemotherapy
Chemotherapy regimen									10.210	0.037
EC/ECF						28(5.87%)	19(8.76%)	9(3.46%)
CT/ECT						27(5.66%)	15(6.91%)	12(4.62%)
ET						223(46.75%)	100(46.08%)	123(47.31%)
TP						141(29.56%)	54(24.88%)	87(33.46%)
Others						58(12.16%)	29(13.36%)	29(11.15%)
Response									8.767	0.067
CR						7(1.47%)	7(3.23%)	0(0.00%)
PR						312(65.41%)	137(63.13%)	175(67.31%)
SD						151(31.66%)	70(32.26%)	81(31.15%)
PD						7(1.47%)	3(1.38%)	4(1.54%)
Miller and Payne grade									3.781	0.436
1						22(4.61%)	10(4.61%)	12(4.62%)
2						126(26.42%)	53(24.42%)	73(28.08%)
3						177(37.11%)	86(39.63%)	91(35.00%)
4						62(13.00%)	23(10.60%)	39(15.00%)
5						90(18.87%)	45(20.74%)	45(17.31%)
Pathological response									0.333	0.564
pCR						72(15.09%)	35(16.13%)	37(14.23%)
non-pCR						405(84.91%)	182(83.87%)	223(85.77%)
Post-chemotherapy regimen				8.417	0.135				5.448	0.364				16.380	0.006
EC/ECF	125(15.92%)	65(16.33%)	60(15.50%)			43(9.01%)	17(7.83%)	26(10.00%)			82(26.62%)	48(26.52%)	34(26.77%)
CT/ECT	125(15.92%)	61(15.33%)	64(16.54%)			30(6.29%)	13(5.99%)	17(6.54%)			95(30.84%)	48(26.52%)	47(37.01%)
ET	97(12.36%)	62(15.58%)	35(9.04%)			37(7.76%)	22(10.14%)	15(5.77%)			60(19.48%)	40(22.10%)	20(15.75%)
TP	61(7.77%)	29(7.29%)	32(8.27%)			39(8.18%)	21(9.68%)	18(6.92%)			22(7.14%)	8(4.42%)	14(11.02%)
Others	108(13.76%)	51(12.81%)	57(14.73%)			81(16.98%)	33(15.21%)	48(18.46%)			27(8.77%)	18(9.94%)	9(7.09%)
NO	269(34.27%)	130(32.66%)	139(35.92%)			247(51.78%)	111(51.15%)	136(52.31%)			22(7.14%)	19(10.50%)	3(2.36%)
Type of surgery				1.520	0.218				2.168	0.141				0.708	0.400
Mastectomy	606(77.20%)	300(75.38%)	306(79.07%)			406(85.12%)	179(82.49%)	227(87.31%)			200(64.94%)	121(66.85%)	79(62.20%)
Breast-conserving surgery	179(22.80%)	98(24.62%)	81(20.93%)			71(14.88%)	38(17.51%)	33(12.69%)			108(35.06%)	60(33.15%)	48(37.80%)
Tumor size (cm)				4.234	0.120				2.696	0.260				3.422	0.181
≤2cm	437(55.67%)	223(56.03%)	214(55.30%)			263(55.14%)	127(58.53%)	136(52.31%)			174(56.49%)	96(53.04%)	78(61.42%)
>2 and <5cm	299(38.09%)	157(39.45%)	142(36.69%)			172(36.06%)	75(34.56%)	97(37.31%)			127(41.23%)	82(45.30%)	45(35.43%)
≥5cm	49(6.24%)	18(4.52%)	31(8.01%)			42(8.81%)	15(6.91%)	27(10.38%)			7(2.27%)	3(1.66%)	4(3.15%)
Histologic type				2.483	0.289				2.799	0.247				0.947	0.623
Ductal	758(96.56%)	388(97.49%)	370(95.61%)			461(96.65%)	212(97.70%)	249(95.77%)			297(96.43%)	176(97.24%)	121(95.28%)
Lobular	13(1.66%)	4(1.01%)	9(2.33%)			7(1.47%)	1(0.46%)	6(2.31%)			6(1.95%)	3(1.66%)	3(2.36%)
Others	14(1.78%)	6(1.51%)	8(2.07%)			9(1.89%)	4(1.84%)	5(1.92%)			5(1.62%)	2(1.10%)	3(2.36%)
Histologic grade				4.510	0.105				2.337	0.311				3.021	0.221
I	133(16.94%)	64(16.08%)	69(17.83%)			108(22.64%)	47(21.66%)	61(23.46%)			25(8.12%)	17(9.39%)	8(6.30%)
II	431(54.90%)	233(58.54%)	198(51.16%)			244(51.15%)	119(54.84%)	125(48.08%)			187(60.71%)	114(62.98%)	73(57.48%)
III	221(28.15%)	101(25.38%)	120(31.01%)			125(26.21%)	51(23.50%)	74(28.46%)			96(31.17%)	50(27.62%)	46(36.22%)
Pathological TNM classification
Pathological T stage				4.487	0.344				4.005	0.405				3.399	0.493
Tis/T0	92(11.72%)	47(11.81%)	45(11.63%)			88(18.45%)	43(19.82%)	45(17.31%)			4(1.30%)	4(2.21%)	0(0.00%)
T1	302(38.47%)	155(38.94%)	147(37.98%)			190(39.83%)	92(42.40%)	98(37.69%)			112(36.36%)	63(34.81%)	49(38.58%)
T2	326(41.53%)	171(42.96%)	155(40.05%)			149(31.24%)	65(29.95%)	84(32.31%)			177(57.47%)	106(58.56%)	71(55.91%)
T3	45(5.73%)	18(4.52%)	27(6.98%)			34(7.13%)	12(5.53%)	22(8.46%)			11(3.57%)	6(3.31%)	5(3.94%)
T4	20(2.55%)	7(1.76%)	13(3.36%)			16(3.35%)	5(2.30%)	11(4.23%)			4(1.30%)	2(1.10%)	2(1.57%)
Pathological N stage				9.373	0.052				9.799	0.044				2.572	0.632
N0	326(41.53%)	175(43.97%)	151(39.02%)			176(36.90%)	89(41.01%)	87(33.46%)			150(48.70%)	86(47.51%)	64(50.39%)
N1	175(22.29%)	99(24.87%)	76(19.64%)			101(21.17%)	53(24.42%)	48(18.46%)			74(24.03%)	46(25.41%)	28(22.05%)
N2	122(15.54%)	55(13.82%)	67(17.31%)			77(16.14%)	32(14.75%)	45(17.31%)			45(14.61%)	23(12.71%)	22(17.32%)
N3	162(20.64%)	69(17.34%)	93(24.03%)			123(25.79%)	43(19.82%)	80(30.77%)			39(12.66%)	26(14.36%)	13(10.24%)
Pathological TNM stage				7.477	0.113				9.882	0.043				3.449	0.486
Tis/T0	74(9.43%)	38(9.55%)	36(9.30%)			71(14.88%)	35(16.13%)	36(13.85%)			3(0.97%)	3(1.66%)	0(0.00%)
I	157(20.00%)	85(21.36%)	72(18.60%)			83(17.40%)	46(21.20%)	37(14.23%)			74(24.03%)	39(21.55%)	35(27.56%)
II	262(33.38%)	145(36.43%)	117(30.23%)			118(24.74%)	59(27.19%)	59(22.69%)			144(46.75%)	86(47.51%)	58(45.67%)
III	292(37.20%)	130(32.66%)	162(41.86%)			205(42.98%)	77(35.48%)	128(49.23%)			87(28.25%)	53(29.28%)	34(26.77%)
Total lymph nodes				1.228	0.268				0.005	0.941				0.486	0.486
<21	391(49.81%)	206(51.76%)	185(47.80%)			202(42.35%)	92(42.40%)	110(42.31%)			189(61.36%)	114(62.98%)	75(59.06%)
≥21	394(50.19%)	192(48.24%)	202(52.20%)			275(57.65%)	125(57.60%)	150(57.69%)			119(38.64%)	67(37.02%)	52(40.94%)
Positive lymph nodes				1.770	0.183				2.647	0.104				0.248	0.619
<1	329(41.91%)	176(44.22%)	153(39.53%)			179(37.53%)	90(41.47%)	89(34.23%)			150(48.70%)	86(47.51%)	64(50.39%)
≥1	456(58.09%)	222(55.78%)	234(60.47%)			298(62.47%)	127(58.53%)	171(65.77%)			158(51.30%)	95(52.49%)	63(49.61%)
Postoperative chemotherapy				0.922	0.337				0.063	0.801				7.447	0.006
No	269(34.27%)	130(32.66%)	139(35.92%)			247(51.78%)	111(51.15%)	136(52.31%)			22(7.14%)	19(10.50%)	3(2.36%)
Yes	516(65.73%)	268(67.34%)	248(64.08%)			230(48.22%)	106(48.85%)	124(47.69%)			286(92.86%)	162(89.50%)	124(97.64%)
Postoperative radiotherapy				5.820	0.016				1.068	0.301				6.793	0.009
No	196(24.97%)	114(28.64%)	82(21.19%)			119(24.95%)	59(27.19%)	60(23.08%)			77(25.00%)	55(30.39%)	22(17.32%)
Yes	589(75.03%)	284(71.36%)	305(78.81%)			358(75.05%)	158(72.81%)	200(76.92%)			231(75.00%)	126(69.61%)	105(82.68%)
Postoperative endocrine therapy				1.090	0.296				0.766	0.382				0.021	0.884
No	302(38.47%)	146(36.68%)	156(40.31%)			206(43.19%)	89(41.01%)	117(45.00%)			96(31.17%)	57(31.49%)	39(30.71%)
Yes	483(61.53%)	252(63.32%)	231(59.69%)			271(56.81%)	128(58.99%)	143(55.00%)			212(68.83%)	124(68.51%)	88(69.29%)
Postoperative targeted therapy				10.053	0.002				5.720	0.017				1.797	0.180
No	583(74.27%)	315(79.15%)	268(69.25%)			332(69.60%)	163(75.12%)	169(65.00%)			251(81.49%)	152(83.98%)	99(77.95%)
Yes	202(25.73%)	83(20.85%)	119(30.75%)			145(30.40%)	54(24.88%)	91(35.00%)			57(18.51%)	29(16.02%)	28(22.05%)

In all breast cancer patients, there were 398 cases in the low SII group and 387 cases in the high SII group. Statistical analysis showed that menopausal status (χ2=7.033, P=0.008), clinical T stage (χ2=25.424, P <0.0001), clinical N stage (χ2=22.656, P=0.002), clinical TNM stage (χ2=21.459, P <0.0001), postoperative radiotherapy (χ2=5.820, P=0.016), and postoperative targeted therapy (χ2=10.053, P=0.002) were statistically significant.

In the NACT group (477 patients), there were 217 cases in the low SII group and 260 cases in the high SII group. Statistical analysis showed that menopausal status (χ2=10.533, P=0.001), clinical T stage (χ2=12.659, P=0.013), clinical TNM stage (χ2=6.364, P=0.042), neoadjuvant chemotherapy regimen (χ2=10.210, P=0.037), pathological N stage (χ2=9.799, P=0.044), pathological TNM stage (χ2=9.882, P=0.043) and postoperative targeted (χ2=5.720, P=0.017) were statistically significant.

In the non-NACT group (308 breast cancer patients), there were 181 cases in the low SII group and 127 cases in the high SII group. Statistical analysis showed that postoperative chemotherapy (χ2=7.447, P=0.006) and postoperative radiotherapy (χ2=6.793, P=0.009) were statistically significant.

Hematology Parameters

Alanine aminotransferase (ALT), aspartate aminotransferase (AST), lactate dehydrogenase (LDH), r-glutamyltranspeptidase (GGT), alkaline phosphatase (ALP), blood glucose (GLU), immunoglobulin A (IgA) and albumin (ALB) were used to evaluate the nutritional status of breast cancer. The median values were 15.00U/L, 18.00U/L, 167.00 U/L, 17.00U/L, 64.00 U/L, 5.33mmol/L, 2.30 g/L, 45.2 g/L, respectively. Our analysis of inflammatory markers associated with breast cancer included C-reactive protein (CRP), carbohydrate antigen 125 (CA125), carbohydrate antigen (CA15-3), carcinoembryonic antigen (CEA), plasma D-dimer (D-D), fibrinogen (FIB), the international standardized ratio of prothrombin time (INR), fibrinogen degradation products (FDP), and various peripheral blood count parameters such as white blood cell (W), red blood cell (R), hemoglobin (Hb), N, L, M, eosinophils (E), basophils (B), and P. Their median values were 0.20 mg/dl, 13.35 U/mL, 11.63 U/mL, 1.66 ng/mL, 0.29 mg/L, 2.85 g/L, 0.93, 1.40 ug/mL, 6.01×109/L, 4.40×1012/L, 132g/L, 3.68×109/L, 1.76×109/L, 0.35×109/L, 0.06×109/L, 0.02×109/L, and 243×109/L, respectively. These findings are depicted in Table 2.

Table 2

The Correlations Between Nutritional Parameters/Blood Parameters and SII

Parameters	N	SII 785				N	SII 477				N	SII 308
Cases (n)	785	Low SII 398	High SII 387	χ2	P value		Low SII 217	High SII 260	χ2	P value		Low SII 181	High SII 127	χ2	P value
ALT (U/L)				0.003	0.960				0.013	0.908				0.192	0.662
<15	370(47.13%)	187(46.98%)	183(47.29%)			208(43.61%)	94(43.32%)	114(43.85%)			162(52.60%)	93(51.38%)	69(54.33%)
≥15	416(52.99%)	211(53.02%)	205(52.97%)			269(56.39%)	123(56.68%)	146(56.15%)			147(47.73%)	88(48.62%)	59(46.46%)
AST (U/L)				0.003	0.960				0.139	0.710				0.925	0.336
<18	378(48.15%)	192(48.24%)	186(48.06%)			211(44.23%)	98(45.16%)	113(43.46%)			167(54.22%)	94(51.93%)	73(57.48%)
≥18	407(51.85%)	206(51.76%)	201(51.94%)			266(55.77%)	119(54.84%)	147(56.54%)			141(45.78%)	87(48.07%)	54(42.52%)
LDH (U/L)				8.470	0.004				9.209	0.002				0.016	0.898
<167	376(47.90%)	211(53.02%)	165(42.64%)			193(40.46%)	104(47.93%)	89(34.23%)			183(59.42%)	107(59.12%)	76(59.84%)
≥167	409(52.10%)	187(46.98%)	222(57.36%)			284(59.54%)	113(52.07%)	171(65.77%)			125(40.58%)	74(40.88%)	51(40.16%)
GGT (U/L)				1.132	0.287				2.588	0.108				0.772	0.380
<17	366(46.62%)	193(48.49%)	173(44.70%)			203(42.56%)	101(46.54%)	102(39.23%)			163(52.92%)	92(50.83%)	71(55.91%)
≥17	419(53.38%)	205(51.51%)	214(55.30%)			274(57.44%)	116(53.46%)	158(60.77%)			145(47.08%)	89(49.17%)	56(44.09%)
ALP (U/L)				0.202	0.654				0.102	0.750				1.422	0.233
<64	377(48.03%)	188(47.24%)	189(48.84%)			227(47.59%)	105(48.39%)	122(46.92%)			150(48.70%)	83(45.86%)	67(52.76%)
≥64	408(51.97%)	210(52.76%)	198(51.16%)			250(52.41%)	112(51.61%)	138(53.08%)			158(51.30%)	98(54.14%)	60(47.24%)
GLU (mmol/L)				0.288	0.591				2.524	0.112				0.707	0.401
<5.33	391(49.81%)	202(50.75%)	189(48.84%)			247(51.78%)	121(55.76%)	126(48.46%)			144(46.75%)	81(44.75%)	63(49.61%)
≥5.33	394(50.19%)	196(49.25%)	198(51.16%)			230(48.22%)	96(44.24%)	134(51.54%)			164(53.25%)	100(55.25%)	64(50.39%)
ALB (g/L)				13.001	0.0003				7.705	0.006				5.083	0.024
<45.2	392(49.94%)	224(56.28%)	168(43.41%)			235(49.27%)	122(56.22%)	113(43.46%)			157(50.97%)	102(56.35%)	55(43.31%)
≥45.2	393(50.06%)	174(43.72%)	219(56.59%)			242(50.73%)	95(43.78%)	147(56.54%)			151(49.03%)	79(43.65%)	72(56.69%)
CRP (mg/dl)				1.408	0.235				0.152	0.697				1.040	0.308
<0.02	384(48.92%)	203(51.01%)	181(46.77%)			187(39.20%)	83(38.25%)	104(40.00%)			197(63.96%)	120(66.30%)	77(60.63%)
≥0.02	401(51.08%)	195(48.99%)	206(53.23%)			290(60.80%)	134(61.75%)	156(60.00%)			111(36.04%)	61(33.70%)	50(39.37%)
CA125 (U/mL)				9.209	0.002				10.367	0.001				0.124	0.725
<13.35	392(49.94%)	220(55.28%)	172(44.44%)			221(46.33%)	118(54.38%)	103(39.62%)			171(55.52%)	102(56.35%)	69(54.33%)
≥13.35	393(50.06%)	178(44.72%)	215(55.56%)			256(53.67%)	99(45.62%)	157(60.38%)			137(44.48%)	79(43.65%)	58(45.67%)
CA153 (U/mL)				0.797	0.372				4.449	0.035				4.644	0.031
<11.63	392(49.94%)	205(51.51%)	187(48.32%)			208(43.61%)	106(48.85%)	102(39.23%)			184(59.74%)	99(54.70%)	85(66.93%)
≥11.63	393(50.06%)	193(48.49%)	200(51.68%)			269(56.39%)	111(51.15%)	158(60.77%)			124(40.26%)	82(45.30%)	42(33.07%)
CEA (ng/mL)				0.011	0.915				0.071	0.789				0.426	0.514
<1.66	392(49.94%)	198(49.75%)	194(50.13%)			212(44.44%)	95(43.78%)	117(45.00%)			180(58.44%)	103(56.91%)	77(60.63%)
≥1.66	393(50.06%)	200(50.25%)	193(49.87%)			265(55.56%)	122(56.22%)	143(55.00%)			128(41.56%)	78(43.09%)	50(39.37%)
D-D (mg/L)				0.100	0.752				0.008	0.928				2.669	0.102
<0.29	387(49.30%)	194(48.74%)	193(49.87%)			200(41.93%)	91(41.94%)	109(41.92%)			187(60.71%)	103(56.91%)	84(66.14%)
≥0.29	398(50.70%)	204(51.26%)	194(50.13%)			277(58.07%)	126(58.06%)	151(58.08%)			121(39.29%)	78(43.09%)	43(33.86%)
FIB (g/L)				8.387	0.004				4.700	0.030				1.906	0.167
<2.85	388(49.43%)	217(54.52%)	171(44.19%)			216(45.28%)	110(50.69%)	106(40.77%)			172(55.84%)	107(59.12%)	65(51.18%)
≥2.85	397(50.57%)	181(45.48%)	216(55.81%)			261(54.72%)	107(49.31%)	154(59.23%)			136(44.16%)	74(40.88%)	62(48.82%)
INR				10.784	0.001				6.581	0.010				0.698	0.404
<0.93	365(46.50%)	208(52.26%)	157(40.57%)			177(37.11%)	94(43.32%)	83(31.92%)			188(61.04%)	114(62.98%)	74(58.27%)
≥0.93	420(53.50%)	190(47.74%)	230(59.43%)			300(62.89%)	123(56.68%)	177(68.08%)			120(38.96%)	67(37.02%)	53(41.73%)
FDP (ug/mL)				2.018	0.155				0.457	0.499				0.239	0.625
<1.40	367(46.75%)	196(49.25%)	171(44.19%)			137(28.72%)	59(27.19%)	78(30.00%)			230(74.68%)	137(75.69%)	93(73.23%)
≥1.40	418(53.25%)	202(50.75%)	216(55.81%)			340(71.28%)	158(72.81%)	182(70.00%)			78(25.32%)	44(24.31%)	34(26.77%)
White blood cell (W) (×109/L)				50.511	<0.0001				39.723	<0.0001				13.475	0.0002
<6.01	389(49.55%)	247(62.06%)	142(36.69%)			239(50.10%)	143(65.90%)	96(36.92%)			150(48.70%)	104(57.46%)	46(36.22%)
≥6.01	396(50.45%)	151(37.94%)	245(63.31%)			238(49.90%)	74(34.10%)	164(63.08%)			158(51.30%)	77(42.54%)	81(63.78%)
Red blood cell (R) (×1012/L)				7.186	0.007				4.946	0.026				2.264	0.132
<4.40	389(49.55%)	216(54.27%)	173(44.70%)			235(49.27%)	119(54.84%)	116(44.62%)			154(50.00%)	97(53.59%)	57(44.88%)
≥4.40	396(50.45%)	182(45.73%)	214(55.30%)			242(50.73%)	98(45.16%)	144(55.38%)			154(50.00%)	84(46.41%)	70(55.12%)
Hemoglobin (Hb) (×109/L)				3.622	0.057				3.023	0.082				1.529	0.216
<132	382(48.66%)	207(52.01%)	175(45.22%)			243(50.94%)	120(55.30%)	123(47.31%)			139(45.13%)	87(48.07%)	52(40.94%)
≥132	403(51.34%)	191(47.99%)	212(54.78%)			234(49.06%)	97(44.70%)	137(52.69%)			169(54.87%)	94(51.93%)	75(59.06%)
Neutrophil (N) (×109/L)				148.170	<0.0001				90.962	<0.0001				55.799	<0.0001
<3.68	392(49.94%)	284(71.36%)	108(27.91%)			229(48.01%)	156(71.89%)	73(28.08%)			163(52.92%)	128(70.72%)	35(27.56%)
≥3.68	393(50.06%)	114(28.64%)	279(72.09%)			248(51.99%)	61(28.11%)	187(71.92%)			145(47.08%)	53(29.28%)	92(72.44%)
Lymphocyte (L) (×109/L)				43.588	<0.0001				15.549	<0.0001				26.815	<0.0001
<1.76	391(49.81%)	152(38.19%)	239(61.76%)			258(54.09%)	96(44.24%)	162(62.31%)			133(43.18%)	56(30.94%)	77(60.63%)
≥1.76	394(50.19%)	246(61.81%)	148(38.24%)			219(45.91%)	121(55.76%)	98(37.69%)			175(56.82%)	125(69.06%)	50(39.37%)
Monocyte (M) (×109/L)				2.913	0.088				3.234	0.072				0.086	0.770
<0.35	367(46.75%)	198(49.75%)	169(43.67%)			216(45.28%)	108(49.77%)	108(41.54%)			151(49.03%)	90(49.72%)	61(48.03%)
≥0.35	418(53.25%)	200(50.25%)	218(56.33%)			261(54.72%)	109(50.23%)	152(58.46%)			157(50.97%)	91(50.28%)	66(51.97%)
Eosinophils (E) (×109/L)				19.123	<0.0001				6.290	0.012				10.563	0.001
<0.06	356(45.35%)	150(37.69%)	206(53.23%)			241(50.52%)	96(44.24%)	145(55.77%)			115(37.34%)	54(29.83%)	61(48.03%)
≥0.06	429(54.65%)	248(62.31%)	181(46.77%)			236(49.48%)	121(55.76%)	115(44.23%)			193(62.66%)	127(70.17%)	66(51.97%)
Basophils (B) (×109/L)				11.478	0.001				1.559	0.212				15.340	<0.0001
<0.02	224(28.54%)	135(33.92%)	89(23.00%)			136(28.51%)	68(31.34%)	68(26.15%)			88(28.57%)	67(37.02%)	21(16.54%)
≥0.02	561(71.46%)	263(66.08%)	298(77.00%)			341(71.49%)	149(68.66%)	192(73.85%)			220(71.43%)	114(62.98%)	106(83.46%)
Platelet (P) (×109/L)				66.899	<0.0001				49.263	<0.0001				16.716	<0.0001
<243	388(49.43%)	254(63.82%)	134(34.63%)			224(46.96%)	140(64.52%)	84(32.31%)			164(53.25%)	114(62.98%)	50(39.37%)
≥243	397(50.57%)	144(36.18%)	253(65.37%)			253(53.04%)	77(35.48%)	176(67.69%)			144(46.75%)	67(37.02%)	77(60.63%)

In all breast cancer patients, LDH (χ2=8.470, P=0.004), ALB (χ2=13.001, P=0.0003), CA125 (χ2=9.201, P=0.003), FIB (χ2=8.387, P=0.004), INR (χ2=10.784, P=0.001), W (χ2=50.511, P<0.0001), R (χ2=7.186, P=0.007), N (χ2=148.170, P<0.0001), L (χ2=43.588, P<0.0001), E (χ2=19.123, P<0.0001), B (χ2=11.478, P=0.001), and P (χ2=66.899, P<0.0001) were statistically significant.

In the NACT group (477 patients), LDH (χ2=9.209, P=0.002), ALB (χ2=7.705, P=0.006), CA125 (χ2=10.367, P=0.001), CA153 (χ2=4.449, P=0.035), FIB (χ2=4.700, P=0.030), INR (χ2=6.581, P=0.010), W (χ2=39.723, P<0.0001), R (χ2=4.946, P=0.026), N (χ2=90.962, P<0.0001), L (χ2=15.549, P<0.0001), E (χ2=6.290, P=0.012, P (χ2=49.263, P<0.0001) were statistically significant.

In the non-NACT group (308 breast cancer patients), ALB (χ2=5.083, P=0.024), CA153 (χ2=4.644, P=0.031), W (χ2=13.475, P=0.0002), N (χ2=55.799, P<0.0001), L (χ2=26.815, P<0.0001), E (χ2=10.563, P=0.001), B (χ2=15.340, P<0.0001), P (χ2=16.716, P<0.0001) were statistically significant.

Univariate and Multivariate Cox Regression Survival Analyses

Based on univariate analysis, independent factors that led to enhanced DFS and OS were menopausal status, blood glucose, FDP, eosinophil, platelet, SII, clinical T stage, histological type, pathological N stage, molecular type, Ki-67, CK5/6, lymphatic invasion, postoperative chemotherapy, and postoperative targeted therapy. Additional multivariate analysis revealed menopausal status, blood glucose, CA153, INR, lymphocytes, monocytes, SII, clinical T stage, histological type, pathological N and TNM stages, Ki-67, CK5/6, E-cad, postoperative targeted therapy, postoperative chemotherapy, and lymph vessel invasion were independent factors for improving DFS and OS. The above findings are depicted in Table 3.

Table 3

Univariate and Multivariate Cox Regression Survival Analyses of the SII for the Prediction of DFS and OS in Breast Cancer Patients

		DFS				OS
	Univariate Analysis		Multivariate Analysis		Univariate Analysis		Multivariate Analysis
Parameters	Hazard Ratio (95% CI)	P value	Hazard Ratio (95% CI)	P value	Hazard Ratio (95% CI)	P value	Hazard Ratio (95% CI)	P value
Age (year)		0.539				0.975
<47	1(reference)				1(reference)
≥47	0.897(0.636–1.266)				0.994(0.703–1.406)
Marital status		0.554				0.577
Married	1(reference)				1(reference)
Unmarried	0.801(0.384–1.667)				0.808(0.383–1.704)
Occupation		0.862				0.497
Mental worker	1(reference)				1(reference)
Manual worker	1.023(0.715–1.463)				0.855(0.598–1.223)
Others	1.079(0.818–1.423)				1.077(0.812–1.429)
Weight (Kg)		0.106				0.192
<62.00	1(reference)				1(reference)
≥62.00	1.372(0.934–2.017)				1.304(0.874–1.946)
Height (m)		0.584				0.658
<1.60	1(reference)				1(reference)
≥1.60	0.925(0.700–1.221)				0.937(0.705–1.246)
BMI		0.371				0.781
<24.00	1(reference)				1(reference)
≥24.00	0.837(0.567–1.235)				0.944(0.631–1.412)
Menarche age (year)		0.611				0.269
<14	1(reference)				1(reference)
≥14	1.067(0.829–1.374)				1.159(0.891–1.508)
Menopause		0.008		0.002		<0.0001		0.006
No	1(reference)		1(reference)		1(reference)		1(reference)
Yes	1.637(1.137–2.357)		1.439(1.147–1.806)		1.552(1.217–1.979)		1.380(1.098–1.733)
ALT (U/L)		0.470				0.070
<15	1(reference)				1(reference)
≥15	0.892(0.656–1.214)				0.746(0.543–1.024)
AST (U/L)		0.604				0.925
<18	1(reference)				1(reference)
≥18	0.920(0.672–1.259)				1.015(0.737–1.397)
LDH (U/L)		0.483				0.901
<167	1(reference)				1(reference)
≥167	1.106(0.834–1.466)				1.018(0.766–1.352)
GGT (U/L)		0.683				0.568
<17	1(reference)				1(reference)
≥17	1.061(0.797–1.412)				1.089(0.811–1.463)
ALP (U/L)		0.081				0.111
<64	1(reference)				1(reference)
≥64	1.288(0.969–1.712)				1.262(0.947–1.682)
GLU (mmol/L)		0.003		0.002		0.013		0.023
<5.33	1(reference)		1(reference)		1(reference)		1(reference)
≥5.33	0.658(0.500–0.864)		0.700(0.559–0.878)		0.695(0.522–0.927)		0.756(0.594–0.961)
ALB (g/L)		0.050				0.439
<45.2	1(reference)				1(reference)
≥45.2	1.260(1.000–1.587)				1.105(0.856–1.426)
CRP (mg/dl)		0.330				0.736
<0.2	1(reference)				1(reference)
≥0.2	0.868(0.653–1.153)				0.949(0.704–1.280)
CA125 (U/mL)		0.058				0.201
<13.35	1(reference)				1(reference)
≥13.35	1.266(0.992–1.616)				1.186(0.912–1.542)
CA153 (U/mL)		0.104				0.002		0.001
<11.63	1(reference)				1(reference)		1(reference)
≥11.63	1.260(0.953–1.665)				1.553(1.171–2.061)		1.438(1.153–1.793)
CEA (ng/mL)		0.507				0.841
<1.66	1(reference)				1(reference)
≥1.66	0.915(0.706–1.187)				1.027(0.788–1.338)
D-D (mg/L)		0.164				0.240
<0.29	1(reference)				1(reference)
≥0.29	1.215(0.923–1.600)				1.183(0.893–1.567)
FIB (g/L)		0.523				0.256
<2.85	1(reference)				1(reference)
≥2.85	0.916(0.701–1.197)				1.167(0.893–1.525)
INR		0.707				0.048		0.013
<0.93	1(reference)				1(reference)		1(reference)
≥0.93	0.953(0.741–1.224)				1.292(1.002–1.666)		1.322(1.061–1.649)
FDP (ug/mL)		0.037		0.027		0.334
<1.40	1(reference)		1(reference)		1(reference)
≥1.40	1.307(1.017–1.681)		1.301(1.030–1.643)		0.861(0.635–1.166)
ABO blood type		0.087				0.079
A	1(reference)				1(reference)
B	0.919(0.674–1.253)				0.854(0.618–1.180)
O	0.733(0.529–1.015)				0.768(0.548–1.076)
AB	1.248(0.795–1.958)				1.355(0.848–2.165)
White blood cell (W)×109/L		0.067				0.127
<6.01	1(reference)				1(reference)
≥6.01	1.457(0.974–2.181)				1.386(0.911–2.108)
Red blood cell (R)×1012/L		0.859				0.399
<4.40	1(reference)				1(reference)
≥4.40	0.972(0.716–1.320)				1.143(0.837–1.560)
Hemoglobin (Hb)×109/L		0.778				0.355
<132	1(reference)				1(reference)
≥132	0.957(0.707–1.295)				0.868(0.644–1.170)
Neutrophil (N)×109/L		0.119				0.162
<3.68	1(reference)				1(reference)
≥3.68	0.732(0.495–1.083)				0.751(0.504–1.121)
Lymphocyte (L)×109/L		0.913				0.033		0.029
<1.76	1(reference)				1(reference)		1(reference)
≥1.76	1.017(0.749–1.379)				1.325(1.023–1.716)		1.309(1.028–1.666)
Monocyte (M)×109/L		0.340				0.005		0.002
<0.35	1(reference)				1(reference)		1(reference)
≥0.35	0.877(0.671–1.147)				0.672(0.510–0.885)		0.705(0.564–0.882)
Eosinophils (E)×109/L		0.036		0.029		0.093
<0.06	1(reference)		1(reference)		1(reference)
≥0.06	0.752(0.577–0.981)		0.780(0.624–0.974)		0.812(0.637–1.035)
Basophils (B)×109/L		0.828				0.517
<0.02	1(reference)				1(reference)
≥0.02	1.033(0.769–1.387)				1.103(0.819–1.485)
Platelet (P)×109/L		0.003		0.006		0.061
<243	1(reference)		1(reference)		1(reference)
≥243	0.666(0.510–0.869)		0.704(0.550–0.902)		0.776(0.595–1.011)
Systemic immune-inflammation index (SII)		<0.0001		<0.0001		<0.0001		<0.0001
<560	1(reference)		1(reference)		1(reference)		1(reference)
≥560	1.965(1.430–2.701)		1.676(1.334–2.105)		2.086(1.518–2.868)		2.073(1.640–2.622)
Tumor site		0.205				0.279
Right	1(reference)				1(reference)
Left	1.174(0.915–1.506)				1.149(0.893–1.477)
US-Primary tumor site		0.429				0.548
Upper outer quadrant	1(reference)				1(reference)
Lower outer quadrant	1.318(0.889–1.956)				1.294(0.859–1.950)
Lower inner quadrant	1.115(0.644–1.930)				1.476(0.853–2.553)
Upper inner quadrant	1.274(0.910–1.785)				1.111(0.782–1.578)
Central	1.349(0.768–2.371)				1.093(0.619–1.929)
Clinical stage
Clinical T stage		0.031		0.022		0.023		0.011
T1	1(reference)		1(reference)		1(reference)		1(reference)
T2	2.323(1.332–4.051)		1.930(1.183–3.150)		2.413(1.345–4.328)		2.305(1.392–3.817)
T3	2.228(1.112–4.463)		2.004(1.103–3.641)		2.698(1.320–5.510)		2.426(1.315–4.476)
T4	2.121(1.055–4.745)		1.851(1.072–3.671)		2.861(1.236–6.619)		2.333(1.158–4.703)
Clinical N stage		0.188				0.320
N0	1(reference)				1(reference)
N1	0.960(0.640–1.439)				1.029(0.666–1.590)
N2	1.004(0.501–2.015)				0.992(0.486–2.028)
N3	1.684(0.786–3.608)				1.626(0.723–3.656)
Clinical TNM stage		0.185				0.417
I	1(reference)				1(reference)
II	0.563(0.300–1.055)				0.641(0.329–1.247)
III	0.630(0.259–1.530)				0.666(0.258–1.718)
Type of surgery		0.221				0.316
Mastectomy	1(reference)				1(reference)
Breast-conserving surgery	0.799(0.558–1.144)				1.208(0.834–1.748)
Histologic type		0.020		0.027		0.001		0.011
Ductal	1(reference)		1(reference)		1(reference)		1(reference)
Lobular	2.518(1.102–5.750)		2.473(1.131–5.410)		3.314(1.394–7.877)		2.140(1.035–4.423)
Others	2.118(1.044–4.680)		1.798(1.159–3.749)		3.136(1.417–6.940)		2.312(1.125–4.752)
Histologic grade		0.120				0.203
I	1(reference)				1(reference)
II	0.820(0.514–1.308)				0.810(0.506–1.296)
III	0.643(0.392–1.056)				0.658(0.394–1.098)
Pathological TNM classification
Pathological T stage		0.125				0.052
Tis/T0	1(reference)				1(reference)
T1	0.734(0.239–2.248)				0.594(0.195–1.808)
T2	0.708(0.225–2.224)				0.480(0.153–1.504)
T3	0.600(0.167–2.145)				0.379(0.107–1.342)
T4	1.703(0.430–6.731)				1.198(0.305–4.706)
Pathological N stage		0.016		0.048		0.002		0.001
N0	1(reference)		1(reference)		1(reference)		1(reference)
N1	2.638(1.074–7.476)		1.402(1.039–1.892)		1.236(1.171–1.790)		1.283(1.041–1.713)
N2	2.911(1.294–10.95)		1.149(1.086–1.649)		2.600(1.245–5.429)		1.413(1.003–1.991)
N3	4.740(1.264–17.77)		1.522(1.078–2.150)		4.241(1.929–9.325)		1.880(1.371–2.578)
Pathological TNM stage		0.284				0.018		0.012
Tis/T0	1(reference)				1(reference)		1(reference)
I	3.206(0.885–11.61)				3.027(1.202–11.01)		2.118(1.565–7.025)
II	3.503(0.925–13.25)				3.832(1.009–14.55)		2.429(1.393–8.223)
III	2.660(0.554–12.75)				2.532(1.337–4.796)		2.645(1.428–4.899)
Total lymph nodes		0.727				0.543
<21	1(reference)				1(reference)
≥21	0.906(0.521–1.575)				0.832(0.461–1.502)
Positive lymph nodes		0.314				0.923
<1	1(reference)				1(reference)
≥1	0.526(0.151–1.835)				0.938(0.256–3.437)
Postoperative pathology (IHC)
Molecular subtype		0.039		0.009		0.114
Luminal A	1(reference)		1(reference)		1(reference)
Luminal B HER2+	0.248(0.092–0.670)		0.372(0.199–0.697)		0.290(0.105–0.800)
Luminal B HER2-	0.608(0.354–0.958)		0.504(0.305–0.830)		0.533(0.308–0.921)
HER2 enriched	0.186(0.064–0.546)		0.325(0.174–0.609)		0.358(0.120–1.069)
Triple negative	0.591(0.294–0.843)		0.527(0.300–0.924)		0.658(0.328–1.321)
ER status		0.087				0.940
Negative	1(reference)				1(reference)
Positive	0.642(0.386–1.066)				0.980(0.593–1.620)
PR status		0.256				0.217
Negative	1(reference)				1(reference)
Positive	1.256(0.847–1.862)				1.265(0.870–1.838)
HER2 status		0.111				0.204
Negative (0–++)	1(reference)				1(reference)
Positive (+++)	2.061(0.846–5.025)				1.769(0.732–4.271)
Ki-67 status		0.003		0.001		0.006		0.001
Negative (≤14%)	1(reference)		1(reference)		1(reference)		1(reference)
Positive (>14%)	1.694(1.197–2.396)		1.666(1.222–2.272)		1.631(1.154–2.306)		1.691(1.251–2.286)
AR status		0.474				0.820
Negative	1(reference)				1(reference)
Positive	0.848(0.541–1.330)				0.943(0.574–1.551)
CK5/6 status		0.024		0.0001		0.049		0.0002
Negative	1(reference)		1(reference)		1(reference)		1(reference)
Positive	1.674(1.071–2.614)		1.900(1.371–2.632)		1.600(1.001–2.557)		1.847(1.335–2.556)
E-cad status		0.173				<0.0001		<0.0001
Negative	1(reference)				1(reference)		1(reference)
Positive	1.271(0.899–1.797)				2.775(1.895–4.066)		2.821(2.124–3.747)
EGFR status		0.313				0.932
Negative	1(reference)				1(reference)
Positive	0.811(0.540–1.217)				0.981(0.636–1.512)
P53 status		0.071				0.092
Negative	1(reference)				1(reference)
Positive	0.773(0.585–1.021)				0.815(0.643–1.034)
TOP2A status		0.292				0.479
Negative	1(reference)				1(reference)
Positive	1.212(0.847–1.734)				1.146(0.785–1.672)
Lymph vessel invasion		0.028		0.022		0.016		0.002
Negative	1(reference)		1(reference)		1(reference)		1(reference)
Positive	1.433(1.040–1.977)		1.358(1.044–1.765)		1.492(1.077–2.068)		1.481(1.152–1.904)
Neural invasion		0.577				0.755
Negative	1(reference)				1(reference)
Positive	0.887(0.584–1.348)				1.066(0.710–1.601)
Postoperative chemotherapy		<0.0001		<0.0001		0.0001		0.0001
No	1(reference)		1(reference)		1(reference)		1(reference)
Yes	2.108(1.436–3.094)		1.807(1.297–2.518)		1.931(1.311–2.843)		1.692(1.235–2.318)
Postoperative radiotherapy		0.281				0.164
No	1(reference)				1(reference)
Yes	1.198(0.862–1.665)				1.273(0.906–1.789)
Postoperative endocrine therapy		0.051				0.211
No	1(reference)				1(reference)
Yes	1.366(0.999–1.867)				1.217(0.894–1.657)
Postoperative targeted therapy		<0.0001		<0.0001		0.013		<0.0001
No	1(reference)		1(reference)		1(reference)		1(reference)
Yes	2.480(1.713–3.591)		2.050(1.600–2.628)		1.592(1.105–2.293)		1.687(1.317–2.161)

DFS and OS

Both univariate and multivariate analyses found SII to be an independent factor that improves DFS and OS. Univariate analysis demonstrated that the low SII group remarkably improved DFS and OS (HR: 1.965, 95% CI: 1.430–2.701, P <0.0001 and HR: 1.676, 95% CI: 1.334–2.105, P <0.0001). Subsequent multivariate analysis also mirrored these findings, with the low group SII predictive for better DFS and OS (HR: 2.086, 95% CI: 1.518–2.868, P <0.0001) and HR: 2.073, 95% CI: 1.640–2.622, P <0.0001).

The mean DFS and OS in the low group were 46.65 months (3.10–238.00 months) and 69.92 months (6.43–260.00 months); The mean survival time of DFS and OS in the high SII group was 27.37 months (3.13–205.50 months) and 49.53 months (10.77–247.30 months). Log-rank analysis showed that the mean survival time of DFS and OS in the low SII group was significantly higher than that in the high SII group (χ2=19.840, P <0.0001 and χ2=24.050, P <0.0001) (Figure 1).

Figure 1

DFS and OS of breast cancer patients. (A) Kaplan–Meier analysis of DFS for the SII of all patients with breast cancer. (B) Kaplan–Meier analysis of OS for the SII of all patients with breast cancer. (C) Kaplan–Meier analysis of DFS for the SII of patients with breast cancer (NACT group). (D) Kaplan–Meier analysis of OS for the SII of patients with breast cancer (NACT group). (E) Kaplan–Meier analysis of DFS for the SII of patients with breast cancer (non-NACT group). (F) Kaplan–Meier analysis of OS for the SII of patients with breast cancer (non-NACT group).

SII and Pathological TNM Stage

Both univariate and multivariate pathology revealed that the N stage represented an independent influencer of DFS and OS. Moreover, the pathological TNM stage also represented an independent factor of OS. To further analyze the SII prognostic value, we analyzed the relationship between SII and the TNM stage. We defined pathological stages Tis/T0+I as early breast cancer and pathological stage II+III as advanced breast cancer.

Patients in the low SII group with early-stage breast cancer had significantly longer mean DFS and OS in contrast to those with high SII indices (χ2=6.119, P=0.013, and χ2=9.155, P=0.003). Similarly, patients in the low SII group with advanced breast cancer had significantly longer mean DFS and OS in contrast to those with high SII indices (χ2=13.320, P=0.0003, and χ2=15.460, P <0.0001) (Figure 2).

Figure 2

DFS and OS based on SII scores of patients with breast cancer of different pathological stage. (A) Kaplan–Meier analysis of DFS for the SII of patients with early breast cancer. (B) Kaplan–Meier analysis of OS for the SII of patients with early breast cancer. (C) Kaplan–Meier analysis of DFS for the SII of patients with advanced breast cancer. (D) Kaplan–Meier analysis of OS for the SII of patients with advanced breast cancer. (E) Kaplan–Meier analysis of DFS for the SII of patients with early breast cancer (NACT group). (F) Kaplan–Meier analysis of OS for the SII of patients with early breast cancer (NACT group). (G) Kaplan–Meier analysis of DFS for the SII of patients with advanced breast cancer (NACT group). (H) Kaplan–Meier analysis of OS for the SII of patients with advanced breast cancer (NACT group). (I) Kaplan–Meier analysis of DFS for the SII of patients with early breast cancer (non-NACT group). (J) Kaplan–Meier analysis of OS for the SII of patients with early breast cancer (non-NACT group). (K) Kaplan–Meier analysis of DFS for the SII of patients with advanced breast cancer (non-NACT group). (L) Kaplan–Meier analysis of OS for the SII of patients with advanced breast cancer (non-NACT group).

Molecular Type and SII in Breast Cancer

Another independent factor of DFS and OS was the molecular subtype of breast cancer, as uncovered by both univariate and multivariate analyses. Of the 785 patients, 62 were Luminal A, 98 were Luminal B HER2-positive, 325 were Luminal B HER2-negative, 129 were HER2-overexpressing, and 171 were triple-negative. Table 4 shows the detailed information of the molecular type of breast cancer.

Table 4

Association of Molecular Subtype and SII in Patients with Breast Cancer

Parameters	N	SII 785				N	SII 477				N	SII 308
Cases (n)	785	Low SII 398	High SII 387	χ2	P value		Low SII 217	High SII 260	χ2	P value		Low SII 181	High SII 127	χ2	P value
Core needle biopsy (N=477)
Molecular subtype									12.210	0.032
Luminal A						25(5.24%)	12(5.53%)	13(5.00%)
Luminal B HER2+						67(14.05%)	28(12.90%)	39(15.00%)
Luminal B HER2-						186(38.99%)	83(38.25%)	103(39.62%)
HER2 enriched						91(19.08%)	40(18.43%)	51(19.62%)
Triple negative						108(22.64%)	54(24.88%)	54(20.77%)
ER status									0.126	0.723
Negative						191(40.04%)	85(39.17%)	106(40.77%)
Positive						286(59.96%)	132(60.83%)	154(59.23%)
ER status									0.836	0.934
0–25%						228(47.80%)	106(48.85%)	122(46.92%)
26–50%						42(8.81%)	21(9.68%)	21(8.08%)
51–75%						33(6.92%)	15(6.91%)	18(6.92%)
76–100%						174(36.48%)	75(34.56%)	99(38.08%)
PR status									0.037	0.848
Negative						189(39.62%)	87(40.09%)	102(39.23%)
Positive						288(60.38%)	130(59.91%)	158(60.77%)
PR status									4.008	0.405
0–25%						286(59.96%)	132(60.83%)	154(59.23%)
26–50%						67(14.05%)	35(16.13%)	32(12.31%)
51–75%						45(9.43%)	15(6.91%)	30(11.54%)
76–100%						79(16.56%)	35(16.13%)	44(16.92%)
HER2 status									0.796	0.372
Negative (0–++)						313(65.62%)	147(67.74%)	166(63.85%)
Positive (+++)						164(34.38%)	70(32.26%)	94(36.15%)
Ki-67 status									0.452	0.501
Negative (≤14%)						84(17.61%)	41(18.89%)	43(16.54%)
Positive (>14%)						393(82.39%)	176(81.11%)	217(83.46%)
Ki-67 status									1.661	0.798
0–25%						161(33.75%)	76(35.02%)	85(32.69%)
26–50%						189(39.62%)	87(40.09%)	102(39.23%)
51–75%						88(18.45%)	40(18.43%)	48(18.46%)
76–100%						39(8.18%)	14(6.45%)	25(9.62%)
Postoperative pathology (IHC)
Molecular subtype				11.250	0.047				14.560	0.012				5.544	0.236
Luminal A	62(7.90%)	37(9.30%)	25(6.46%)			41(8.60%)	20(9.22%)	21(8.08%)			21(6.82%)	17(9.39%)	4(3.15%)
Luminal B HER2+	98(12.48%)	44(11.06%)	54(13.95%)			61(12.79%)	22(10.14%)	39(15.00%)			37(12.01%)	22(12.15%)	15(11.81%)
Luminal B HER2-	325(41.40%)	165(41.46%)	160(41.34%)			166(34.80%)	77(35.48%)	89(34.23%)			159(51.62%)	88(48.62%)	71(55.91%)
HER2 enriched	129(16.43%)	59(14.82%)	70(18.09%)			96(20.13%)	41(18.89%)	55(21.15%)			33(10.71%)	18(9.94%)	15(11.81%)
Triple negative	171(21.78%)	93(23.37%)	78(20.16%)			113(23.69%)	57(26.27%)	56(21.54%)			58(18.83%)	36(19.89%)	22(17.32%)
ER status				0.019	0.892				0.058	0.809				0.165	0.685
Negative	296(37.71%)	151(37.94%)	145(37.47%)			195(40.88%)	90(41.47%)	105(40.38%)			101(32.79%)	61(33.70%)	40(31.50%)
Positive	489(62.29%)	247(62.06%)	242(62.53%)			282(59.12%)	127(58.53%)	155(59.62%)			207(67.21%)	120(66.30%)	87(68.50%)
ER status				6.325	0.176				3.285	0.511				5.499	0.240
0–25%	375(47.77%)	197(49.50%)	178(45.99%)			235(49.27%)	109(50.23%)	126(48.46%)			140(45.45%)	88(48.62%)	52(40.94%)
26–50%	66(8.41%)	34(8.54%)	32(8.27%)			31(6.50%)	16(7.37%)	15(5.77%)			35(11.36%)	18(9.94%)	17(13.39%)
51–75%	48(6.11%)	16(4.02%)	32(8.27%)			27(5.66%)	8(3.69%)	19(7.31%)			21(6.82%)	8(4.42%)	13(10.24%)
76–100%	296(37.71%)	151(37.94%)	145(37.47%)			184(38.57%)	84(38.71%)	100(38.46%)			112(36.36%)	67(37.02%)	45(35.43%)
PR status				0.062	0.804				0.007	0.931				0.005	0.943
Negative	315(40.13%)	158(39.70%)	157(40.57%)			210(44.03%)	96(44.24%)	114(43.85%)			105(34.09%)	62(34.25%)	43(33.86%)
Positive	470(59.87%)	240(60.30%)	230(59.43%)			267(55.97%)	121(55.76%)	146(56.15%)			203(65.91%)	119(65.75%)	84(66.14%)
PR status				0.993	0.911				0.716	0.949				0.099	0.999
0–25%	502(63.95%)	253(63.57%)	249(64.34%)			335(70.23%)	154(70.97%)	181(69.62%)			167(54.22%)	99(54.70%)	68(53.54%)
26–50%	90(11.46%)	48(12.06%)	42(10.85%)			48(10.06%)	23(10.60%)	25(9.62%)			42(13.64%)	25(13.81%)	17(13.39%)
51–75%	55(7.01%)	25(6.28%)	30(7.75%)			38(7.97%)	15(6.91%)	23(8.85%)			17(5.52%)	10(5.52%)	7(5.51%)
76–100%	138(17.58%)	72(18.09%)	66(17.05%)			56(11.74%)	25(11.52%)	31(11.92%)			82(26.62%)	47(25.97%)	35(27.56%)
HER2 status				2.278	0.131				1.580	0.209				0.040	0.842
Negative (0–++)	557(70.96%)	292(73.37%)	265(68.48%)			320(67.09%)	152(70.05%)	168(64.62%)			237(76.95%)	140(77.35%)	97(76.38%)
Positive (+++)	228(29.04%)	106(26.63%)	122(31.52%)			157(32.91%)	65(29.95%)	92(35.38%)			71(23.05%)	41(22.65%)	30(23.62%)
Ki-67 status				0.006	0.941				0.100	0.752				1.413	0.235
Negative (≤14%)	219(27.90%)	111(27.89%)	108(27.91%)			153(32.08%)	68(31.34%)	85(32.69%)			66(21.43%)	43(23.76%)	23(18.11%)
Positive (>14%)	566(72.10%)	287(72.11%)	279(72.09%)			324(67.92%)	149(68.66%)	175(67.31%)			242(78.57%)	138(76.24%)	104(81.89%)
Ki-67 status				0.321	0.988				1.618	0.806				0.225	0.994
0–25%	342(43.57%)	175(43.97%)	167(43.15%)			233(48.85%)	112(51.61%)	121(46.54%)			109(35.39%)	63(34.81%)	46(36.22%)
26–50%	257(32.74%)	131(32.91%)	126(32.56%)			139(29.14%)	62(28.57%)	77(29.62%)			118(38.31%)	69(38.12%)	49(38.58%)
51–75%	137(17.45%)	69(17.34%)	68(17.57%)			70(14.68%)	28(12.90%)	42(16.15%)			67(21.75%)	41(22.65%)	26(20.47%)
76–100%	49(6.24%)	23(5.78%)	26(6.72%)			35(7.34%)	15(6.91%)	20(7.69%)			14(4.55%)	8(4.42%)	6(4.72%)
AR status				14.812	0.000				8.194	0.004				0.129	0.720
Negative	666(84.84%)	357(89.70%)	309(79.84%)			362(75.89%)	178(82.03%)	184(70.77%)			304(98.70%)	179(98.90%)	125(98.43%)
Positive	119(15.16%)	41(10.30%)	78(20.16%)			115(24.11%)	39(17.97%)	76(29.23%)			4(1.30%)	2(1.10%)	2(1.57%)
AR status				12.840	0.012				7.140	0.129				0.809	0.369
0–25%	688(87.64%)	364(91.46%)	324(83.72%)			383(80.29%)	184(84.79%)	199(76.54%)			305(99.03%)	180(99.45%)	125(98.43%)
26–50%	25(3.18%)	9(2.26%)	16(4.13%)			25(5.24%)	9(4.15%)	16(6.15%)			0(0.00%)	0(0.00%)	0(0.00%)
51–75%	29(3.69%)	13(3.27%)	16(4.13%)			29(6.08%)	13(5.99%)	16(6.15%)			0(0.00%)	0(0.00%)	0(0.00%)
76–100%	43(5.48%)	12(3.02%)	31(8.01%)			40(8.39%)	11(5.07%)	29(11.15%)			3(0.97%)	1(0.55%)	2(1.57%)
CK5/6 status				1.233	0.267				0.353	0.553				0.405	0.525
Negative	684(87.13%)	352(88.44%)	332(85.79%)			406(85.12%)	187(86.18%)	219(84.23%)			278(90.26%)	165(91.16%)	113(88.98%)
Positive	101(12.87%)	46(11.56%)	55(14.21%)			71(14.88%)	30(13.82%)	41(15.77%)			30(9.74%)	16(8.84%)	14(11.02%)
E-cad status				22.464	<0.0001				5.013	0.025				13.277	0.0003
Negative	353(44.97%)	212(53.27%)	141(36.43%)			170(35.64%)	89(41.01%)	81(31.15%)			183(59.42%)	123(67.96%)	60(47.24%)
Positive	432(55.03%)	186(46.73%)	246(63.57%)			307(64.36%)	128(58.99%)	179(68.85%)			125(40.58%)	58(32.04%)	67(52.76%)
EGFR status				1.907	0.167				0.273	0.601				0.693	0.405
Negative	589(75.03%)	307(77.14%)	282(72.87%)			335(70.23%)	155(71.43%)	180(69.23%)			254(82.47%)	152(83.98%)	102(80.31%)
Positive	196(24.97%)	91(22.86%)	105(27.13%)			142(29.77%)	62(28.57%)	80(30.77%)			54(17.53%)	29(16.02%)	25(19.69%)
P53 status				3.845	0.050				4.437	0.035				0.384	0.536
Negative	395(50.32%)	214(53.77%)	181(46.77%)			243(50.94%)	122(56.22%)	121(46.54%)			152(49.35%)	92(50.83%)	60(47.24%)
Positive	390(49.68%)	184(46.23%)	206(53.23%)			234(49.06%)	95(43.78%)	139(53.46%)			156(50.65%)	89(49.17%)	67(52.76%)
P53 status				2.210	0.697				3.149	0.533				0.876	0.646
0–25%	576(73.38%)	299(75.13%)	277(71.58%)			353(74.00%)	169(77.88%)	184(70.77%)			223(72.40%)	130(71.82%)	93(73.23%)
26–50%	80(10.19%)	40(10.05%)	40(10.34%)			45(9.43%)	17(7.83%)	28(10.77%)			35(11.36%)	23(12.71%)	12(9.45%)
51–75%	108(13.76%)	51(12.81%)	57(14.73%)			58(12.16%)	23(10.60%)	35(13.46%)			50(16.23%)	28(15.47%)	22(17.32%)
76–100%	21(2.68%)	8(2.01%)	13(3.36%)			21(4.40%)	8(3.69%)	13(5.00%)			0(0.00%)	0(0.00%)	0(0.00%)
TOP2A status				5.817	0.016				0.579	0.447				5.731	0.017
Negative	299(38.09%)	168(42.21%)	131(33.85%)			165(34.59%)	79(36.41%)	86(33.08%)			134(43.51%)	89(49.17%)	45(35.43%)
Positive	486(61.91%)	230(57.79%)	256(66.15%)			312(65.41%)	138(63.59%)	174(66.92%)			174(56.49%)	92(50.83%)	82(64.57%)
TOP2A status				5.176	0.270				2.361	0.670				7.202	0.126
0–25%	575(73.25%)	304(76.38%)	271(70.03%)			354(74.21%)	168(77.42%)	186(71.54%)			221(71.75%)	136(75.14%)	85(66.93%)
26–50%	158(20.13%)	74(18.59%)	84(21.71%)			88(18.45%)	34(15.67%)	54(20.77%)			70(22.73%)	40(22.10%)	30(23.62%)
51–75%	49(6.24%)	19(4.77%)	30(7.75%)			33(6.92%)	14(6.45%)	19(7.31%)			16(5.19%)	5(2.76%)	11(8.66%)
76–100%	3(0.38%)	1(0.25%)	2(0.52%)			2(0.42%)	1(0.46%)	1(0.38%)			1(0.32%)	0(0.00%)	1(0.79%)
Lymph vessel invasion				9.036	0.003				4.160	0.041				2.873	0.090
Negative	558(71.08%)	302(75.88%)	256(66.15%)			320(67.09%)	156(71.89%)	164(63.08%)			238(77.27%)	146(80.66%)	92(72.44%)
Positive	227(28.92%)	96(24.12%)	131(33.85%)			157(32.91%)	61(28.11%)	96(36.92%)			70(22.73%)	35(19.34%)	35(27.56%)
Neural invasion				4.329	0.038				1.518	0.218				0.751	0.386
Negative	670(85.35%)	350(87.94%)	320(82.69%)			384(80.50%)	180(82.95%)	204(78.46%)			286(92.86%)	170(93.92%)	116(91.34%)
Positive	115(14.65%)	48(12.06%)	67(17.31%)			93(19.50%)	37(17.05%)	56(21.54%)			22(7.14%)	11(6.08%)	11(8.66%)

In all breast cancer patients, AR (χ2=14.812, P=0.0002), E-cad (χ2=22.464, P <0.0001), TOP2A (χ2=5.817, P=0.016), lymph vessel invasion (χ2=9.036, P=0.003), nerve invasion (χ2=4.329, P=0.038) were statistically significant.

In the NACT group (477 patients), AR (χ2=8.194, P=0.004), E-cad (χ2=5.013, P=0.025), P53 (χ2=4.437, P=0.035) and lymph vessel invasion (χ2=4.160, P=0.041) were statistically significant.

In the non-NACT group (308 breast cancer patients), E-cad (χ2=13.277, P=0.0003) and TOP2A (χ2=5.731, P=0.017) were statistically significant.

To further analyze the prognostic value of SII, we examined the association between SII and molecular typing of breast cancer (Figures 3–Figure 5). A log-rank analysis revealed that the low SII group had longer DFS and OS when compared against the high SII group.

Figure 3

DFS and OS based on SII scores in patients with breast cancer of various molecular subtypes. (A) DFS as shown by Kaplan–Meier analysis based on the SII of patients with luminal A breast cancer. (B) OS as shown by Kaplan–Meier analysis based on the SII of patients with luminal A breast cancer. (C) DFS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (D) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (E) DFS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-negative breast cancer. (F) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-negative breast cancer. (G) DFS, as shown by Kaplan–Meier based on the SII of patients with HER2-enriched breast cancer. (H) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (I) DFS, as shown by Kaplan–Meier based on the SII of patients with triple-negative breast cancer. (J) OS, as shown by Kaplan–Meier based on the SII of patients with triple-negative breast cancer.

Figure 4

DFS and OS based on SII scores in patients with breast cancer of various molecular subtypes (NACT group). (A) DFS as shown by Kaplan–Meier analysis based on the SII of patients with luminal A breast cancer. (B) OS as shown by Kaplan–Meier analysis based on the SII of patients with luminal A breast cancer. (C) DFS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (D) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (E) DFS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-negative breast cancer. (F) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-negative breast cancer. (G) DFS, as shown by Kaplan–Meier based on the SII of patients with HER2-enriched breast cancer. (H) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (I) DFS, as shown by Kaplan–Meier based on the SII of patients with triple-negative breast cancer. (J) OS, as shown by Kaplan–Meier based on the SII of patients with triple-negative breast cancer.

Figure 5

DFS and OS based on SII scores in patients with breast cancer of various molecular subtypes (Non-NACT group). (A) DFS as shown by Kaplan–Meier analysis based on the SII of patients with luminal A breast cancer. (B) OS as shown by Kaplan–Meier analysis based on the SII of patients with luminal A breast cancer. (C) DFS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (D) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (E) DFS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-negative breast cancer. (F) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-negative breast cancer. (G) DFS, as shown by Kaplan–Meier based on the SII of patients with HER2-enriched breast cancer. (H) OS, as shown by Kaplan–Meier based on the SII of patients with luminal B HER2-positive breast cancer. (I) DFS, as shown by Kaplan–Meier based on the SII of patients with triple-negative breast cancer. (J) OS, as shown by Kaplan–Meier based on the SII of patients with triple-negative breast cancer.

SII and Lymph Vessel Invasion

Univariate and multivariate analysis also uncovered lymph vessel invasion as an independent factor of DFS and OS. Of the 785 cases, 227 cases were associated with lymph vessel invasion, and 558 cases were without that. Additional analysis on the relationship between the prognostic value of SII and lymphatic invasion was also performed. The mean DFS and OS in patients without lymph vessel invasion were 50.96 months and 79.65 months, respectively. The mean DFS and OS in patients with lymphatic invasion were 28.97 months and 53.37 months, respectively. Patients who had no evidence of lymphatic invasion had a much higher DFS and OS in comparison to those with lymph vessel invasion (χ2=20.940, P <0.0001 and χ2=26.540, P <0.0001). Among the 558 patients without lymph vessel invasion, those who had low SII indices had enhanced DFS and OS compared to those in the high SII group (χ2=13.170, P=0.0003, and χ2=15.950, P <0.0001). Among the 227 patients with lymph vessel invasion, those who had low SII indices had augmented DFS and OS compared to those in the high SII group (χ2=3.209, P=0.073, and χ2=4.894, P=0.027) (Figure 6). In the NACT group (477 patients receiving neoadjuvant chemotherapy), the DFS and OS of SII and vascular tumor thrombus were shown in Figure 7. In the non-NACT group (308 breast cancer patients), the DFS and OS of SII and vascular tumor thrombus were shown in Figure 8.

Figure 6

DFS and OS based on the presence of lymph vessel invasion in breast cancer patients. (A) DFS, as shown by Kaplan–Meier analysis based on the SII of all patients with breast cancer. (B) OS, as shown by Kaplan–Meier analysis based on the SII of all patients with breast cancer. (C) DFS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients without lymph vessel invasion. (D) OS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients without lymph vessel invasion. (E) DFS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients with lymph vessel invasion. (F) OS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients with lymph vessel invasion.

Figure 7

DFS and OS based on the presence of lymph vessel invasion in breast cancer patients (NACT group). (A) DFS, as shown by Kaplan–Meier analysis based on the SII of all patients with breast cancer. (B) OS, as shown by Kaplan–Meier analysis based on the SII of all patients with breast cancer. (C) DFS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients without lymph vessel invasion. (D) OS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients without lymph vessel invasion. (E) DFS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients with lymph vessel invasion. (F) OS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients with lymph vessel invasion.

Figure 8

DFS and OS based on the presence of lymph vessel invasion in breast cancer patients (non-NACT group). (A) DFS, as shown by Kaplan–Meier analysis based on the SII of all patients with breast cancer. (B) OS, as shown by Kaplan–Meier analysis based on the SII of all patients with breast cancer. (C) DFS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients without lymph vessel invasion. (D) OS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients without lymph vessel invasion. (E) DFS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients with lymph vessel invasion. (F) OS, as shown by Kaplan–Meier analysis based on the SII of breast cancer patients with lymph vessel invasion.

SII and Neoadjuvant Chemotherapy/Postoperative Chemotherapy

Among those in the NACT cohort, 28 patients were exposed to the AC/ACF regimen; 27 patients were treated exposed to the CT/ACT regimen; 223 patients were exposed to the AT regimen; 141 patients were exposed to the TP regimen; 58 patients were exposed to one other regimen. All 477 patients received surgical treatment after neoadjuvant chemotherapy. Of these patients, 247 did not receive postoperative chemotherapy, and 230 did. Of all patients who received postoperative chemotherapy, 43 patients were exposed to the AC/ACF chemotherapy regimen; 30 patients were exposed to the CT/ACT chemotherapy regimen; 37 patients were exposed to the AT chemotherapy regimen; 39 patients were exposed to the TP chemotherapy regimen, and 81 patients exposed to other chemotherapy regimens. 66.88% (319/477) patients achieved the clinical objective response rate (CR+PR), and 98.53% (470/477) achieved the clinical benefit rate (CR+PR +SD). The pathological response to neoadjuvant chemotherapy was evaluated using the MPG grading system. There were 22 cases of MPG 1 (4.61%), 126 cases of MPG 2 (26.42%), 177 cases of MPG 3 (37.11%), 62 cases of MPG4 (13.00%), and 90 cases of MPG 5 (18.87%). To further analyze the prognostic value of SII, the relationship between SII and MPG was scrutinized. Log-rank analysis revealed that the mean survival time of DFS and OS was significantly different among different MPG grades (χ2=18.290, P <0.0001 and χ2=18.020, P <0.0001) (Figure 9).

Figure 9

The impact of Miller and Payne grade (MPG) on DFS and OS in breast cancer patients who received NACT. (A) DFS as shown by Kaplan–Meier analysis based on the MPG and the SII of patients with breast cancer. (B) OS as shown by Kaplan–Meier analysis based on the MPG and the SII of patients with breast cancer. (C) Kaplan–Meier analysis of DFS based on MPG1 for the SII of patients with breast cancer. (D) Kaplan–Meier analysis of OS based on MPG1 for the SII of patients with breast cancer. (E) Kaplan–Meier analysis of DFS based on MPG2 for the SII of patients with breast cancer. (F) Kaplan–Meier analysis of OS based on MPG2 for the SII of patients with breast cancer. (G) Kaplan–Meier analysis of DFS based on MPG3 for the SII of patients with breast cancer. (H) Kaplan–Meier analysis of OS based on MPG3 for the SII of patients with breast cancer. (I) Kaplan–Meier analysis of DFS based on MPG4 for the SII of patients with breast cancer. (J) Kaplan–Meier analysis of OS based on MPG4 for the SII of patients with breast cancer. (K) Kaplan–Meier analysis of DFS based on MPG5 for the SII of patients with breast cancer. (L) Kaplan–Meier analysis of OS based on MPG5 for the SII of patients with breast cancer.

The association between SII and treatment response groups was also studied. Log-rank analysis showed that the mean DFS and OS among different Response groups were statistically significant (χ2=12.540, P=0.006 and χ2=10.820, P=0.013) (Figure 10).

Figure 10

The impact of response to neoadjuvant chemotherapy in breast cancer patients who received NACT on DFS and OS. (A) Kaplan–Meier analysis of DFS for SII based on the response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (B) Kaplan–Meier analysis of OS for SII based on the response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (C) Kaplan–Meier analysis of DFS for SII based on CR response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (D) Kaplan–Meier analysis of OS for SII based on CR response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (E) Kaplan–Meier analysis of DFS for SII based on PR response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (F) Kaplan–Meier analysis of OS for SII based on PR response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (G) Kaplan–Meier analysis of DFS for SII based on SD response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (H) Kaplan–Meier analysis of OS for SII based on SD response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (I) Kaplan–Meier analysis of DFS for SII based on PD response to neoadjuvant chemotherapy in breast cancer patients who received NACT. (J) Kaplan–Meier analysis of OS for SII based on PD response to neoadjuvant chemotherapy in breast cancer patients who received NACT.

Correlation Between SII and Toxicity Assessment

Neoadjuvant chemotherapy toxicity and adverse reactions were recorded after each participant underwent two cycles of neoadjuvant chemotherapy. In the NACT group, common chemotherapeutic side effects included liver dysfunction, myelosuppression, gastrointestinal reactions, thrombocytopenia, neutropenia, leucopenia, anemia, peripheral neurotoxicity, alopecia, mouth ulcers, diarrhea, vomiting, nausea, and decreased appetite. None of the patients experienced chemotherapy-related death. The difference in the incidence of peripheral neurotoxicity was statistically significant between the groups (χ2=5.032, P=0.025), as shown in Table 5.

Table 5

Correlation Between SII and Toxicity Assessment

Parameters	N	SII 477
Cases (n)		Low SII 217	High SII 260	χ2	P value
Decreased appetite				0.048	0.826
No	70(14.68%)	31(14.29%)	39(15.00%)
Yes	407(85.32%)	186(85.71%)	221(85.00%)
Nausea				1.349	0.245
No	59(12.37%)	31(14.29%)	28(10.77%)
Yes	418(87.63%)	186(85.71%)	232(89.23%)
Vomiting				0.700	0.403
No	234(49.06%)	111(51.15%)	123(47.31%)
Yes	243(50.94%)	106(48.85%)	137(52.69%)
Diarrhea				0.532	0.466
No	444(93.08%)	204(94.01%)	240(92.31%)
Yes	33(6.92%)	13(5.99%)	20(7.69%)
Mouth ulcers				0.790	0.374
No	463(97.06%)	209(96.31%)	254(97.69%)
Yes	14(2.94%)	8(3.69%)	6(2.31%)
Alopecia				2.178	0.140
No	222(46.54%)	109(50.23%)	113(43.46%)
Yes	255(53.46%)	108(49.77%)	147(56.54%)
Peripheral neurotoxicity				5.032	0.025
No	390(81.76%)	168(77.42%)	222(85.38%)
Yes	87(18.24%)	49(22.58%)	38(14.62%)
Anemia				0.190	0.909
Grade 0	257(53.88%)	119(54.84%)	138(53.08%)
Grade 1–2	215(45.07%)	96(44.24%)	119(45.77%)
Grade 3–4	5(1.05%)	2(0.92%)	3(1.15%)
Leukopenia				2.194	0.334
Grade 0	138(28.93%)	56(25.81%)	82(31.54%)
Grade 1–2	233(48.85%)	113(52.07%)	120(46.15%)
Grade 3–4	106(22.22%)	48(22.12%)	58(22.31%)
Neutropenia				1.692	0.429
Grade 0	143(29.98%)	61(28.11%)	82(31.54%)
Grade 1–2	179(37.53%)	79(36.41%)	100(38.46%)
Grade 3–4	155(32.49%)	77(35.48%)	78(30.00%)
Thrombocytopenia				0.613	0.736
Grade 0	372(77.99%)	166(76.50%)	206(79.23%)
Grade 1–2	98(20.55%)	48(22.12%)	50(19.23%)
Grade 3–4	7(1.47%)	3(1.38%)	4(1.54%)
Gastrointestinal reaction				1.479	0.477
Grade 0	38(7.97%)	19(8.76%)	19(7.31%)
Grade 1–2	433(90.78%)	194(89.40%)	239(91.92%)
Grade 3–4	6(1.26%)	4(1.84%)	2(0.77%)
Myelosuppression				0.106	0.948
Grade 0	90(18.87%)	41(18.89%)	49(18.85%)
Grade 1–2	175(36.69%)	78(35.94%)	97(37.31%)
Grade 3–4	212(44.44%)	98(45.16%)	114(43.85%)
Hepatic dysfunction				3.378	0.185
Grade 0	371(77.78%)	175(80.65%)	196(75.38%)
Grade 1–2	105(22.01%)	41(18.89%)	64(24.62%)
Grade 3–4	1(0.21%)	1(0.46%)	0(0.00%)

Discussion

Breast cancer is one of the most common female malignancies, with its incidence surpassing that of lung cancer.25 2.26 million of the 19.29 million new cancer cases reported by the International Agency for Research on Cancer (IARC) were breast cancer, making it the most numerous cancer in the world. In 2020, the statistics of the China National Cancer Center show that of the 420,000 new female breast cancer patients, 120,000 women died of breast cancer. Breast cancer-associated mortality rates are expected to rise annually. This has been attributed to various sociodemographic risk factors for breast cancer, such as late birth, fewer births, and obesity, to name a few. At present, the primary means of treating breast cancer is via surgery, with chemoradiotherapy, endocrine therapy, and targeted therapy acting as effective adjuvants and neoadjuvants that improve the survival time and quality of life of breast cancer patients.

Studies have pointed out that systemic inflammatory response is closely related to the prognosis of several malignant tumors. The application of changes of inflammatory cells in peripheral blood to predict tumor prognosis has received more and more attention, but the mechanism of inflammatory cells causing tumor prognosis remains unclear.26 Studies have shown that inflammatory cells such as lymphocytes, neutrophils, and platelets, have the potential to prognosticate several malignancies.27–29 Neutrophils are the primary responders to inflammation and infection and important participants in the process of cancer development and are therefore associated with tumor progression.30–32 Platelets secrete a large number of microparticles and exosomes, promoting the interaction between tumor cells and may act as a prerequisite for hematological metastasis, while secreted chemokines can recruit myeloid cells and mediate vascular occlusion with platelet thrombi.28,33,34 Another critical component of tumor immunity is lymphocytes, which can inhibit tumor progression and metastasis.35–37 The SII represents an effective indicator of the immune status of malignant tumors and is based on the neutrophils, platelet, and lymphocyte counts.38–40 Studies have also found that SII functions as an independent prognostic factor for a variety of malignant tumors.41–44 Wang et al report that preoperative SII and BI-RADS 5 were independent prognostic factors for triple-negative breast cancer, and patients with decreased SII had improved chances of having longer DFS and OS.45 Liu et al documents SII to be an independent and effective predictor of triple-negative breast cancer, and those with increased SII values were more likely to have shorter DFS, OS, and distant metastasis-free survival.46 Jiang et al found that SII was an independent prognostic factor for DFS and OS in HER2-positive breast cancer, which was superior to NLR, PLR, and other inflammatory indexes in terms of prognostic reliability.47 However, few studies have examined the relationship between SII and breast cancer with neoadjuvant treatment. Therefore, this study retrospectively studied the effect of SII on breast cancer patient survival and prognosis in those who received neoadjuvant chemotherapy.

Our team has published similar results on SII and breast cancer in 2020, and this study was a follow-up study.48 We analyzed the association between SII and clinicopathology in patients with breast cancer. The results showed that the clinicopathological characteristics, including clinical data (menopausal status, US tumor location, US tumor size, US-LNM, clinical T, N, and TNM stages, duration of surgery, postoperative radiotherapy, and postoperative targeted therapy were improved in the low SII group. Nutritional and hematological parameters (LDH, ALB, CA125, FIB, INR, W, R, N, L, E, B, P). Both univariate and multivariate analyses revealed menopausal status, blood glucose, SII, clinical T stage, histological type, pathological N stage, Ki-67, CK5/6, lymph vessel invasion, postoperative targeted therapy, and postoperative chemotherapy to be independent predictors of improvement in DFS and OS. The optimal threshold value of 560 for SII was obtained using a ROC curve. Subsequent results showed that the mean survival times of DFS and OS in the low SII group were increased in contrast to those of the high SII group.

At the same time, we analyzed the relationship between SII and pathological TNM stage. We discovered that those in the low SII group had shorter DFS and OS compared to those in the high SII group in both early and advanced breast cancer. Those in the NACT group who had low SII demonstrated increased average DFS and OS in contrast to those of the high SII group, but this difference was not significant. We also analyzed the relationship between SII and postoperative molecular type of breast cancer. The average DFS and OS in the low SII group were longer in contrast to those of the high SII group across various molecular subtypes, especially in Luminal B HER2-negative type, HER2 enriched type, and triple-negative type.

Lymph vessel invasions are closely related to malignant tumors, with a high degree of invasion corresponding to a poorer prognosis.49 The average DFS and OS of breast cancer patients with lymph vessel invasion were lower compared to individuals without lymphatic invasion. A meta-study by Mari et al also pointed out that lymphatic invasion was a critical prognostic factor for the poor prognosis of patients with bladder cancer after radical cystectomy. In triple-negative breast cancer, the lymphatic invasion was an important prognostic factor, especially in those with lymph node metastasis. We further analyzed the relationship between SII and lymphatic invasion. Those lacking lymphatic invasion in the low SII group had a much enhanced DFS and OS compared to those with increased SII scores. However, the two breast cancer patient groups had similar DFS and OS between those with lymphatic invasion. Amongst those in the NACT group, there was no significant difference in SII between the two groups for breast cancer patients with lymph vessel invasion.

The efficacy of chemotherapy was assessed in patients receiving neoadjuvant chemotherapy after two cycles. After the end of the chemotherapy cycle, all patients received surgical treatment, and the postoperative pathology was evaluated using MPG. We analyzed the relationship among SII, MPG, and Response. In different MPG stages, the mean DFS and OS in the low SII group were increased in contrast to those with raised scores. However, these differences were not statistically significant. Similar trends were seen across different Response groups, with the differences also remaining statistically insignificant. Nevertheless, patients with a lower SII score were less likely to experience peripheral neurotoxicity compared to those with a higher SII score.

Inflammatory cells infiltrate the tumor microenvironment and affect tumor cell growth and development. Neutrophils and monocytes, which are differentiated granulocyte-mononuclear progenitor cells, promote tumor cell growth and angiogenesis by releasing various pro-inflammatory mediators, such as epidermal growth factor, tumor necrosis factor, and vascular endothelial growth factor, in a similar way to the development of inflammation. Chemokine-mediated platelet aggregation occludes blood vessels and promotes the occurrence and progression of malignant tumors. Lymphocytes are critical in mediating the tumor-specific immune response and are integral components of immune surveillance. The increase in the absolute value of neutrophils and platelets and the decrease in the absolute value of lymphocytes in peripheral blood is associated with the occurrence, proliferation, and progression of tumors. Therefore, SII can be used as a practical clinical indicator for tumor progression and prognosis. In this study, we found that the use of SII is not commonly used to stratify breast cancer patients undergoing neoadjuvant chemotherapy. The number of breast cancer patients in China is on the rise year by year. Considering the imbalanced distribution of medical resources and medical conditions in China, these reproducible and minimally-invasive indicators are very useful in guiding clinical treatment and prevention of breast cancer and can provide an effective and powerful point of reference for clinical practice.

Conclusion

In conclusion, we outlined the relationship between SII and breast cancer and demonstrated that low SII is beneficial in breast cancer patient prognosis. Nevertheless, the patients in this study were from a single center and were relatively few in number, a relatively small patient base, and a large number of advanced patients receiving neoadjuvant therapy would help in improving the strength of this study. The optimal threshold SII value appears to be related to the number of patients included and pathological conditions. Therefore, the optimal threshold value of SII in this study still needs to be further studied and verified.