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Introduction

Hepatocellular carcinoma (HCC) is a common type of cancer originating from liver cells, typically occurring in patients with liver cirrhosis or chronic hepatitis (1). HCC is a significant global burden and is ranked as the sixth most common cancer and the fourth leading cause of cancer-related death worldwide (2). The primary risk factors for HCC include viral hepatitis, liver cirrhosis, alcohol abuse and non-alcoholic fatty liver disease (3). The early diagnosis of HCC is difficult as symptoms such as jaundice, abdominal pain and weight loss are not always apparent until the advanced stages of the disease. As a result, the treatment of HCC remains a challenge, despite the availability of certain treatment modalities, such as surgical resection, liver transplantation, chemotherapy and radiation therapy (4). Surgery is the primary treatment modality for HCC; however, for patients with a high risk of postoperative recurrence, such as those with larger tumor volumes (diameter >5 cm), multiple tumor nodules, the presence of satellite lesions, elevated preoperative α-fetoprotein levels and active chronic viral hepatitis, adjuvant therapy can be considered after curative resection. Adjuvant therapy commonly used for patients with HCC includes targeted therapy and immunotherapy (5).

Immune checkpoint inhibitors (ICIs) are a novel class of cancer treatment drugs that restore the ability of T cells to attack tumor cells by blocking inhibitory signaling molecules, such as cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) and programmed cell death protein 1 (PD-1)/PD ligand 1 (PD-L1), on the surface of T cells (6–8). ICIs have been reported to be effective in treating certain solid tumors, including HCC (9–11). Previous studies have also reported that ICIs may improve treatment efficacy and the survival rate of patients with HCC (12,13). However, the application of ICIs also presents certain challenges, including adverse reactions and treatment resistance in some patients. Studies focusing on ICIs have shown that the objective response rates (ORR) for nivolumab and pembrolizumab are only 20 and 16.9%, respectively (14,15). Existing biomarkers that indicate the use of ICIs, such as PD-L1 expression levels and microsatellite instability, are difficult to assess and may not be applicable to all patients (16,17). Therefore, it is still crucial to identify convenient and effective biomarkers to determine which patients will benefit from ICI treatment.

Non-invasive biomarkers have attracted attention since they are easy to assess without the need for tissue biopsy or other invasive procedures. The effectiveness of non-invasive biomarkers for determination of the use of ICIs has also been widely reported (18–20). These biomarkers are also more practical for patients with HCC with lower surgical and biopsy rates. The efficacy of ICIs is dependent on the immune function of the patient, which is influenced by inflammation and nutritional status (21). Numerous studies have shown that certain inflammatory and nutritional biomarkers such as prognostic nutrition index (PNI) and systemic immune-inflammation index (SII) could predict the prognosis of patients with solid tumors who receive ICIs (22–25). However, to the best of our knowledge, the value of these biomarkers in HCC remains unclear.

Therefore, the present study comprehensively evaluated the predictive ability of the PNI, nutritional risk index (NRI), geriatric NRI (GNRI), SII, systemic inflammation response index (SIRI) and advanced lung cancer inflammation index (ALI) for the determination of the prognosis of patients with HCC who received ICIs.

Materials and methods

Patients

The present study included 151 patients with HCC who received ICIs at Harbin Medical University Cancer Hospital (Harbin, China) from January 2019 to December 2021. The age range was 37–81 years old. The clinical and pathological data of the patients were collected through the electronic medical record system. All patients had a confirmed diagnosis of HCC through pathological assessment, and complete clinical and pathological data were available. Clinical data loss or treatment abandonment were exclusion criteria for enrollment in the present study. The Barcelona Clinic Liver Cancer (BCLC) stages system, which combines tumor burden, liver function and performance status, is the most commonly used staging system for HCC (26,27). BCLC stage has been indicated as the primary reference for the selection of treatment modalities for patients with HCC in numerous guidelines (28,29). Therefore, both BCLC and Tumor-Node-Metastasis (TNM) stage information was collected from the patients and the main subgroup analyses were established based on the BCLC stages (30). The data collection and statistical analysis process adhered to the principles of The Declaration of Helsinki and its subsequent amendments, and the present study was approved by The Ethics Committee of Harbin Medical University Cancer Hospital (approval no. ALTN-AK105-III-06). Due to the retrospective nature of the present investigation, The Ethics Committee of Harbin Medical University Cancer Hospital waived the requirement for informed patient consent.

Data collection and follow-up

The progression-free survival (PFS) and overall survival (OS) time were determined following routine patient follow-up via telephone. PFS was determined as the period from the start of treatment to the occurrence of tumor progression, with evidence of progression obtained through imaging and pathological examination. In addition, PFS for patients without evidence of tumor progression was determined as the period from the start of treatment to death or the last follow-up. OS was defined as the period from the start of treatment to death or the last follow-up. The clinical information, pathological characteristics and blood parameters of the patients were obtained from the electronic medical record system and subsequently analyzed.

Treatment methods

Due to the unsatisfactory outcomes of using targeted therapy or immunotherapy alone, combination therapy is the main approach in current HCC treatment (31). Among the 151 patients included in the present study, 51 patients (33.8%) underwent curative resection, with 29 of them (56.9%) receiving atezolizumab combined with bevacizumab treatment due to poor pathological results or postoperative recurrence. The remaining patients participated in a clinical trial and received camrelizumab combined with apatinib treatment (trial registration number: CTR20211710). A total of 100 patients (66.2%) did not undergo surgical treatment due to disease progression or poor liver function. Among them, 48 patients (48.0%) received atezolizumab combined with bevacizumab treatment, while the rest participated in the same clinical trial and received camrelizumab combined with apatinib treatment.

Nutritional and inflammatory markers

The nutritional and inflammatory markers evaluated in the present study were calculated based on the blood parameters of the patients. The calculation formulas of PNI, GNRI, NRI, SII, SIRI and ALI are presented in Table I. Death-based survival receiver operating characteristic (ROC) curves were plotted and cut-off points for biomarkers in the present study were determined by calculating the maximum Youden index (Fig. 1). The area under the curve (AUC), maximum Youden index and cut-off points are presented in Table II.

Figure 1. ROC curves of the inflammation and nutritional markers. The ROC curves for (A) PNI, (B) GNRI, (C) NRI, (D) SII, (E) SIRI and (F) ALI. AUC, area under the curve; ROC, receiver operating characteristic; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Table I. Calculation formulas for the inflammation and nutritional markers.

Table I.

Calculation formulas for the inflammation and nutritional markers.

Marker	Calculation formula
PNI	Albumin (g/l) + 5 × lymphocyte (109/l)
GNRI	[1.489 × albumin (g/l)] + [41.7 × (weight/ideal weighta)]
NRI	[1.519 × albumin (g/l)] + [41.7 × (weight/ideal weighta)]
SII	platelet (109/l) × neutrophil (109/l)/lymphocyte (109/l)
SIRI	monocyte (109/l) × neutrophil (109/l)/lymphocyte (109/l)
ALI	BMI (kg/m2) × albumin (g/dl) × lymphocyte (109/l)/neutrophil (109/l)

a The ideal weight was calculated through the Lorentz equations as follows: Male=height-100-[(height-150)/4]; female=height-100-[(height-150)/2.5]. BMI, body mass index; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Table II. Cut-off points for inflammation and nutritional markers.

Table II.

Cut-off points for inflammation and nutritional markers.

Marker	AUC	95% CI	Youden index	Cut-off point
PNI	0.559	0.466–0.652	0.142	43.37
GNRI	0.591	0.499–0.683	0.179	88.92
NRI	0.589	0.497–0.681	0.168	92.22
SII	0.553	0.460–0.646	0.141	377.03
SIRI	0.600	0.508–0.692	0.224	1.02
ALI	0.586	0.494–0.679	0.182	30.31

[i] AUC, area under the curve; CI, confidence interval; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Statistical analysis

The one-sample Kolmogorov-Smirnov test was used to assess whether continuous variables followed a Gaussian distribution. Continuous variables following a Gaussian distribution are presented as the mean ± SD and were analyzed using unpaired independent-sample t-test. Continuous variables not following a Gaussian distribution are presented as the median and interquartile range and were analyzed using the Mann-Whitney U test. Categorical variables are presented as the number and percentage of patients. Survival analysis was performed using the Kaplan-Meier curve and evaluated the differences in patient survival through log-rank test. Prognostic markers were assessed using Cox regression analysis and are presented as risk hazard ratios and 95% confidence intervals. In addition, time-ROC curves were plotted to evaluate the prognostic value of inflammation and nutritional markers. Nomograms were constructed to predict the survival probability of patients with HCC who received ICIs, and the accuracy of the nomograms was evaluated by drawing calibration curves. All statistical analyses were performed using R 4.2.2 (r-project.org; ‘ggplot2’, ‘survival’, ‘survminer’, ‘rms’, ‘pROC’, and ‘timeROC’). P<0.05 was considered to indicate a statistically significant difference.

Results

Patient characteristics

Among the 151 patients who received ICIs, there were 124 (82.1%) male and 27 (17.9%) female patients, with a mean age of 57.41 (SD, 9.14) years. All patients received standard treatment prior to receiving ICIs. Among the patients, 123 (81.5%) patients had tumor ≥5 cm. The number of patients in BCLC stage A, stage B and stage C were 4 (2.6%), 62 (41.1%) and 85 (56.3%), respectively. TNM staging indicated that 4 (2.6%) patients were in stage I, 55 (36.4%) patients were in stage II, 70 (46.4%) patients were in stage III and 22 (14.6%) patients were in stage IV. In addition, due to the markedly skewed distribution of carcinoembryonic antigen, α-fetoprotein and carbohydrate antigen 199, patients were grouped based on the median values of these factors. The detailed patient characteristics are presented in Table III. The detailed blood parameters from patients before treatment were also collected (Table IV). Because BCLC stage A patients usually experience a greater survival advantage compared with stage B or C patients, and the limited number of cases (n=4) did not support conducting a subgroup analysis for BCLC stage A patients, the BCLC stage A patients were excluded from all subsequent analyses to prevent the introduction of bias into the results (32).

Table III. Patient characteristics (n=151).

Table III.

Patient characteristics (n=151).

Patient characteristic	Value
Sex, n (%)
Male	124 (82.10)
Female	27 (17.90)
Mean age, years (SD)	57.41 (9.14)
Mean BMI, kg/m2 (SD)	23.34 (3.57)
Smoking, n (%)
Yes	31 (20.5)
No	120 (79.5)
Alcohol consumption, n (%)
Yes	19 (12.6)
No	132 (87.4)
ECG, n (%)
Normal	66 (43.7)
Abnormal	85 (56.3)
ABO blood type, n (%)
A	42 (27.8)
B	45 (29.8)
AB	22 (14.6)
O	42 (27.8)
Surgery, n (%)
Yes	51 (33.8)
No	100 (66.2)
Tumor number, n (%)
Single	62 (41.1)
Multiple	89 (58.9)
Tumor size, n (%)
<5 cm	28 (18.5)
≥5 cm	123 (81.5)
Liver cirrhosis, n (%)
Yes	45 (29.8)
No	106 (70.2)
BCLC stage, n (%)
A	4 (2.6)
B	62 (41.1)
C	85 (56.3)
TNM stage, n (%)
I	4 (2.6)
II	55 (36.4)
III	70 (46.4)
IV	22 (14.6)
CEA, n (%)
<2.38 ng/ml	75 (49.7)
≥2.38 ng/ml	76 (50.3)
AFP, n (%)
<151.4 ng/ml	75 (49.7)
≥151.4 ng/ml	76 (50.3)
CA199, n (%)
<22.64 U/ml	74 (49.0)
≥22.64 U/ml	77 (51.0)

[i] AFP, α-fetoprotein; BCLC, Barcelona Clinic Liver Cancer; BMI, body mass index; CA199, carbohydrate antigen 199; CEA, carcinoembryonic antigen; ECG, electrocardiogram; TNM, Tumor-Node-Metastasis.

Table IV. Patient blood parameters (n=151).

Table IV.

Patient blood parameters (n=151).

Parameter	Median (interquartile range)
ALT, U/l	31.00 (22.00, 49.00)
AST, U/l	47.00 (31.00, 47.00)
γ-GGT, U/l	97.00 (47.00, 237.00)
ALP, U/l	120.00 (91.00, 204.00)
TBIL, µmol/l	20.00 (14.50, 32.10)
DBIL, µmol/l	5.00 (3.20, 10.50)
IDBIL, µmol/l	15.30 (11.10, 22.50)
TP, g/l	72.00 (68.10, 77.10)
ALB, g/l	38.30 (34.10, 41.70)
GLOB, g/l	32.90 (29.30, 39.40)
A/G	1.10 (0.90, 1.40)
PALB, mg/l	146.00 (101.00, 200.00)
Urea, mmol/l	5.40 (4.40, 6.90)
CREA, µmol/l	73.00 (63.00, 83.00)
UA, µmol/l	298.00 (232.00, 364.00)
CYS-C, mg/l	0.97 (0.76, 1.07)
CO2-CP, mmol/l	25.6 (23.6, 27.8)
LDH, U/l	225.00 (184.00, 295.00)
Glu, mmol/l	5.20 (4.70, 5.90)
K, mmol/l	4.00 (3.70, 4.30)
Na, mmol/l	139.00 (137.00, 140.00)
Cl, mmol/l	103.00 (101.00, 105.00)
Ca, mmol/l	2.30 (2.10, 2.40)
PHOS, mmol/l	1.00 (0.90, 1.14)
Mg, mmol/l	0.86 (0.77, 0.95)
WBC, 109/l	6.06 (4.82, 7.64)
NEU, 109/l	4.08 (2.98, 5.18)
LYM, 109/l	1.30 (0.90, 1.70)
MON, 109/l	0.45 (0.31, 0.62)
EOS, 109/l	0.08 (0.04, 0.13)
BAS, 109/l	0.02 (0.01, 0.03)
RBC, 109/l	4.49 (4.05, 4.85)
HGB, 109/l	140.00 (126.00, 155.00)
HCT, ×109/l	41.80 (37.90, 46.60)
PLT, ×109/l	158.00 (109.00, 207.00)
PT, sec	12.20 (11.60, 13.10)
INR,	1.07 (1.01, 1.15)
Fbg, g/l	2.97 (2.39, 3.90)
TT, sec	16.90 (16.20, 17.50)

[i] ALT, alanine transaminase; AST, aspartate aminotransferase; γ-GGT, γ-glutamyl transferase; ALP, alkaline phosphatase; TBIL, total bilirubin; DBIL, direct BIL; IDBIL, indirect BIL; TP, total protein; ALB, albumin; GLOB, globulin; A/G, albumin/globulin; PALB, prealbumin; urea, urea nitrogen; CREA, creatinine; UA, uric acid; CYS-C, cystatin C; CO₂-CP, CO₂ combining power; LDH, lactate dehydrogenase; Glu, glucose; PHOS, phosphate; WBC, white blood cell; NEU, neutrophil; LYM, lymphocyte; MON, monocyte; EOS, eosinophil; BAS, basophil; RBC, red blood cell; HGB, hemoglobin; HCT, hematocrit; PLT, platelet; PT, prothrombin time; INR, international normalized ratio; Fbg, fibrinogen; TT, thrombin time.

Distribution differences in inflammation and nutritional marker scores

Differences in the inflammatory and nutritional marker scores among different surgery, tumor size and BCLC stage groups were assessed. The nutritional markers (PNI, GNRI and NRI) all followed a Gaussian distribution. The unpaired independent samples t-test demonstrated significant differences in these biomarkers among different surgery, tumor size and BCLC stage groups (all P<0.05; Fig. 2). The inflammatory markers (SII, SIRI and ALI) did not demonstrate a Gaussian distribution and so significant differences between their maximum and minimum values, the data characteristics and distributions of these markers could not be evaluated using violin plots combined with box plots. The median values of SII, SIRI, and ALI for patients who underwent surgery were 653.64 (313.46, 1165.24), 0.87 (0.56, 3.34), and 45.03 (18.15, 71.64), respectively, while for patients who did not undergo surgery, the respective values were 554.55 (355.89, 838.45), 0.97 (0.63, 1.72), and 34.74 (23.36, 53.25). Furthermore, the median values of SII, SIRI, and ALI for patients with tumor size <5 cm were 533.28 (311.35, 1033.29), 0.77 (0.45, 1.38), and 35.55 (25.31, 73.70), respectively, while for patients with tumor size ≥5 cm, the respective values were 590.21 (350.39, 859.96), 1.01 (0.64, 2.06), and 36.93 (19.69, 56.51). Median SII, SIRI, and ALI for patients with BCLC B stage were 592.41 (333.91, 918.23), 0.89 (0.64, 1.74), and 37.65 (24.68, 64.32), respectively, while for patients with BCLC C stage, the respective values were 554.55 (349.67, 873.63), 1.03 (0.58, 1.97), and 35.00 (19.83, 55.93). The Mann-Whitney U test demonstrated significant differences in SII, SIRI and ALI scores among different surgery, tumor size and BCLC stage groups (all P<0.05; Table V). These results suggested a possible significant association between inflammation and nutritional markers, and disease progression.

Figure 2. Distribution differences in nutritional marker scores. (A) PNI, (B) GNRI and (C) NRI scores in different surgery, tumor size and BCLC stage groups. BCLC, Barcelona Clinic Liver Cancer; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI.

Table V. SII, SIRI, and ALI scores.

Table V.

SII, SIRI, and ALI scores.

A, SII
Characteristic	Rank mean	Sum of ranks	U-value	Z-value	P-value
Surgery			2254.500	−4.428	<0.001
Yes	62.77	7204.50
No	86.53	3673.50
Tumor size, cm			1517.500	−3.513	<0.001
<5	50.20	1895.50
≥5	74.85	8982.50
BCLC stage			2534.500	−3.394	<0.001
B	52.38	4487.50
C	75.18	6390.50
B, SIRI
Characteristic	Rank mean	Sum of ranks	U-value	Z-value	P-value
Surgery			2371.000	−4.350	<0.001
Yes	63.90	3547.00
No	84.05	7331.00
Tumor size, cm			2280.000	−2.701	<0.001
<5	61.41	1658.00
≥5	86.83	9220.00
BCLC stage			2545.400	−3.710	<0.001
B	61.08	4407.00
C	76.13	6471.00
C, ALI
Characteristic	Rank mean	Sum of ranks	U-value	Z-value	P-value
Surgery			2095.500	−2.362	<0.001
Yes	51.17	7045.50
No	79.84	3832.50
Tumor size, cm			1755.500	−3.323	<0.001
<5	61.80	8615.50
≥5	93.80	2262.50
BCLC stage			1336.500	−3.171	<0.001
B	50.49	5991.50
C	88.81	4886.50

[i] BCLC, Barcelona Clinic Liver Cancer; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Univariate and multivariate Cox regression analysis

Cox regression analysis was performed on the disease characteristics, and the inflammation and nutritional markers of patients. The univariate results demonstrated that both the PFS and OS of patients were significantly related to surgery, tumor number, tumor size, liver cirrhosis, BCLC stage, TNM stage. and all inflammatory and nutritional markers (all P<0.05; Table VI). In addition, sex was also a significant prognostic factor for OS. Moreover, the multivariate analysis found that GNRI, PNI, BCLC stage and TNM stage were independent prognostic markers for PFS, and GNRI, BCLC stage and TNM stage were independent prognostic markers for OS.

Table VI. Univariate and multivariate analyses for PFS and OS.

Table VI.

Univariate and multivariate analyses for PFS and OS.

	PFS				OS
	Univariate analysis		Multivariate analysis		Univariate analysis		Multivariate analysis
Variable	HR (95% CI)	P-value	HR (95% CI)	P-value	HR (95% CI)	P-value	HR (95% CI)	P-value
Sex
Male	Ref				Ref		Ref
Female	1.565	0.094			1.760	0.035	1.041	0.900
	(0.927–2.643)				(1.042–2.973)		(0.556–1.947)
Age	0.995	0.732			0.995	0.723
	(0.970–1.022)				(0.970–1.021)
BMI	0.939	0.070			0.957	0.213
	(0.877–1.005)				(0.893–1.026)
Smoking
No	Ref				Ref
Yes	1.358	0.317			1.346	0.332
	(0.745–2.475)				(0.739–2.452)
Drinking
No	Ref				Ref
Yes	1.125	0.719			1.105	0.761
	(0.592–2.139)				(0.581–2.100)
CEA, U/ml
<2.38	Ref				Ref
≥2.38	1.360	0.191			1.448	0.116
	(0.858–2.155)				(0.913–2.297)
AFP, U/ml
<151.4	Ref				Ref
≥151.4	1.176	0.489			1.290	0.278
	(0.743–1.862)				(0.814–2.045)
CA199, U/ml
<22.64	Ref				Ref
≥22.64	1.291	0.278			1.161	0.524
	(0.814–2.047)				(0.733–1.838)
Surgery
Yes	Ref		Ref		Ref		Ref
No	2.481	0.001	1.169	0.629	2.683	<0.001	1.324	0.369
	(1.457–4.222)		(0.621–2.202)		(1.578–4.562)		(0.718–2.439)
Tumor number
Single	Ref		Ref		Ref		Ref
Multiple	1.721	0.029	1.259	0.402	1.761	0.022	1.434	0.202
	(1.058–2.800)		(0.734–2.161)		(1.084–2.860)		(0.824–2.493)
Tumor size, cm
<5	Ref		Ref		Ref		Ref
≥5	3.225	0.002	1.881	0.137	3.284	0.002	2.069	0.086
	(1.537–6.770)		(0.818–4.321)		(1.568–6.877)		(0.901–4.752)
Liver cirrhosis
No	Ref		Ref		Ref		Ref
Yes	1.874	0.013	1.742	0.050	1.655	0.045	1.645	0.066
	(1.141–3.076)		(1.013–2.998)		(1.011–2.708)		(0.967–2.797)
BCLC stage
B	Ref		Ref		Ref		Ref
C	2.726	<0.001	1.769	0.045	3.178	<0.001	2.353	0.006
	(1.667–4.457)		(0.999–3.133)		(1.938–5.209)		(1.276–4.340)
TNM stage
II	Ref		Ref		Ref		Ref
III	2.314	<0.001	1.345	0.037	2.782	<0.001	2.017	0.004
	(1.117–3.028)		(0.893–2.461)		(1.564–4.792)		(1.325–4.660)
IV	3.406	<0.001	1.970	0.025	3.749	<0.001	2.807	0.001
	(2.040–5.688)		(1.091–3.559)		(2.246–6.258)		(1.487–5.298)
PNI
<43.37	Ref		Ref		Ref		Ref
≥43.37	4.189	<0.001	2.069	0.046	2.606	<0.001	1.212	0.572
	(2.497–7.029)		(1.013–4.226)		(1.628–4.170)		(0.623–2.358)
GNRI
<88.92	Ref		Ref		Ref		Ref
≥88.92	7.855	<0.001	2.841	0.019	5.889	<0.001	2.654	0.031
	(4.443–13.919)		(1.183–6.821)		(3.441–10.078)		(1.094–6.438)
NRI
<92.22	Ref		Ref		Ref		Ref
≥92.22	3.170	<0.001	1.077	0.852	3.021	<0.001	1.541	0.292
	(1.959–5.131)		(0.494–2.348)		(1.880–4.853)		(0.689–3.447)
SII
<377.03	Ref		Ref		Ref		Ref
≥377.03	1.849	0.027	1.071	0.857	2.006	0.012	1.004	0.992
	(1.073–3.186)		(0.510–2.249)		(1.163–3.460)		(0.473–2.130)
SIRI
<1.02	Ref		Ref		Ref		Ref
≥1.02	1.962	0.005	1.703	0.157	2.134	0.002	1.796	0.124
	(1.228–3.134)		(0.815–3.555)		(1.332–3.421)		(0.852–3.789)
ALI
<30.31	Ref		Ref		Ref		Ref
≥30.31	1.884	0.007	1.149	0.714	1.956	0.004	1.502	0.280
	(1.188–2.987)		(0.547–2.416)		(1.232–3.105)		(0.718–3.142)

[i] Ref, reference; BMI, body mass index; CI, confidence interval; HR, hazard ratio; OS, overall survival; PFS, progress-free survival; AFP, α-fetoprotein; CA199, carbohydrate antigen 199; CEA, carcinoembryonic antigen; BCLC, Barcelona Clinic Liver Cancer; TNM, Tumor-Node-Metastasis; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Survival analysis for inflammatory and nutritional markers

In the present study, survival analysis was performed for inflammation and nutritional markers after grouping and survival curves were plotted. There were 62 cases with a PNI <43.37 and 85 cases with a PNI ≥43.37. Patients with a low PNI had significantly shorter PFS (13.14 vs. 20.53 months; P<0.001) and OS (15.70 vs. 22.37 months; P<0.001) times compared with patients with a high PNI (Fig. 3A and B). Furthermore, there were 27 patients with a GNRI <88.92 and 120 patients with a GNRI ≥88.92. Patients with a GNRI <88.92 had significantly shorter PFS (7.13 vs. 18.43 months; P<0.001) and OS (9.30 vs. 21.87 months; P<0.001) times compared with patients with a GNRI ≥88.92 (Fig. 3C and D). There were 48 patients with a NRI <92.22 and 99 cases with a NRI ≥92.22. Patients with a NRI <92.22 had significantly shorter PFS (11.02 vs. 19.39 months; P<0.001) and OS (14.01 vs. 22.27 months; P<0.001) times compared with patients with NRI ≥92.22 (Fig. 3E and F).

Figure 3. Inflammation and nutritional marker-related PFS and OS curves. (A) PFS and (B) OS curves for PNI. (C) PFS and (D) OS curves for GNRI. (E) PFS and (F) OS curves for NRI. (G) PFS and (H) OS curves for SII. (I) PFS and (J) OS curves for SIRI. (K) PFS and (L) OS curves for ALI. PFS, progression-free survival; OS, overall survival; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

For the inflammatory markers, there were 43 cases with a SII <377.03 and 104 cases with SII ≥377.03. Patients with a SII ≥377.03 had significantly shorter PFS (20.13 vs. 15.24 months; P=0.048) and OS (not reached vs. 18.77 months; P=0.021) times compared with patients with a SII <377.03 (Fig. 3G and H). Furthermore, 76 patients had a SIRI <1.02 and 71 patients had a SIRI ≥1.02. Patients with a SIRI ≥1.02 had significantly shorter PFS (20.13 vs. 15.07 months; P=0.004) and OS (not reached vs. 17.57 months; P=0.003) times compared with patients with a SIRI <1.02 (Fig. 3I and J). Finally, there were 64 cases with an ALI <30.31 and 83 cases with an ALI ≥30.31. Patients with an ALI <30.31 had significantly shorter PFS (15.10 vs. 19.39 months; P=0.006) and OS (17.57 vs. 23.13 months; P=0.004) times compared with patients with an ALI ≥30.31 (Fig. 3K and L).

Subgroup survival analysis

To further investigate the prognostic value of inflammatory and nutritional biomarkers, subgroup survival analyses among patients with different BCLC stages were performed. There were 62 patients (42.2%) in BCLC stage B, among whom 30 patients (48.4%) underwent surgery and targeted therapy combined with immunotherapy, while 32 patients (51.6%) only received targeted therapy combined with immunotherapy. After analyzing all BCLC stage B patients, the results revealed significant associations between PNI, GNRI and NRI, and survival among patients with BCLC stage B (all P<0.001; Fig. 4). However, it is worth noting that the results for GNRI may be biased due to a small sample size of only 6 patients in the low GNRI group. Furthermore, there were 85 patients (57.8%) with BCLC stage C, among whom 18 patients (21.2%) underwent surgery and targeted therapy combined with immunotherapy, while 67 patients (78.8%) only received targeted therapy combined with immunotherapy. After analyzing all BCLC stage C patients, we found that all inflammatory and nutritional indicators demonstrated significant prognostic value in patients with BCLC stage C (all P<0.05; Fig. 5).

Figure 4. PFS and OS curves for patients with BCLC stage B. (A) PFS and (B) OS curves for PNI. (C) PFS and (D) OS curves for GNRI. (E) PFS and (F) OS curves for NRI. (G) PFS and (H) OS curves for SII. (I) PFS and (J) OS curves for SIRI. (K) PFS and (L) OS curves for ALI. BCLC, Barcelona Clinic Liver Cancer; PFS, progression-free survival; OS, overall survival; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Figure 5. PFS and OS curves for patients with BCLC stage C. (A) PFS and (B) OS curves for PNI. (C) PFS and (D) OS curves for GNRI. (E) PFS and (F) OS curves for NRI. (G) PFS and (H) OS curves for SII. (I) PFS and (J) OS curves for SIRI. (K) PFS and (L) OS curves for ALI. BCLC, Barcelona Clinic Liver Cancer; PFS, progression-free survival; OS, overall survival; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Subgroup survival analysis was also performed on surgical and non-surgical patients. Among patients who underwent surgery, all inflammatory and nutritional markers demonstrated significant prognostic value for OS, and all except SII demonstrated significant prognostic value for PFS (all P<0.05; Fig. 6). However, the results of GNRI were also limited in their reference value due to the small sample size of the GNRI <88.92 group (n=2). Furthermore, PNI, GNRI, and NRI also demonstrated significant prognostic value in non-surgical patients (all P<0.05; Fig. 7).

Figure 6. PFS and OS curves for patients that underwent surgery. (A) PFS and (B) OS curves for PNI. (C) PFS and (D) OS curves for GNRI. (E) PFS and (F) OS curves for NRI. (G) PFS and (H) OS curves for SII. (I) PFS and (J) OS curves for SIRI. (K) PFS and (L) OS curves for ALI. PFS, progression-free survival; OS, overall survival; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Figure 7. PFS and OS curves for patients that did not undergo surgery. (A) PFS and (B) OS curves for PNI. (C) PFS and (D) OS curves for GNRI. (E) PFS and (F) OS curves for NRI. (G) PFS and (H) OS curves for SII. (I) PFS and (J) OS curves for SIRI. (K) PFS and (L) OS curves for ALI. PFS, progression-free survival; OS, overall survival; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Prognostic value of inflammation and nutritional markers

In the ROC curves based on death, it was demonstrated that SIRI and ALI had a markedly higher Youden index and AUC than inflammation and nutritional markers in this study (Fig. 1; Table II). To evaluate the prognostic value of the inflammation and nutritional markers, time-ROC curves based on PFS and OS were plotted (Fig. 8), the results demonstrated that the prognostic values of GNRI, NRI and PNI were higher than those for SII, SIRI and ALI, at all times, with the prognostic value of GNRI being the highest at all times.

Figure 8. Inflammation and nutritional marker-related time-ROC curves of PFS and OS. Time-ROC curves of (A) PFS and (B) OS. AUC of GNRI was consistently higher than that of other indicators at all time points, indicating its superior predictive value. AUC, area under the curve; ROC, receiver operating characteristic; PFS, progression-free survival; OS, overall survival; PNI, prognostic nutrition index; NRI, nutritional risk index; GNRI, geriatric NRI; SII, systemic immune-inflammation index; SIRI, systemic inflammation response index; ALI, advanced lung cancer inflammation index.

Nomograms predict survival probability

Due to the identification of PNI and GNRI as independent prognostic factors according to the Cox regression analysis, predictive models for patients with HCC who received ICIs were constructed to further evaluate their prognostic value (Fig. 9). The C-index (95% CI) of the nomograms for PFS and OS were 0.801 (0.746–0.877) and 0.823 (0.761–0.898), reflecting the high predictive accuracy of the nomograms. Due to limited number of patients, bootstrap validation was performed on the nomograms and calibration curves were plotted (Fig. 10), which demonstrated the high predictive performance of the nomograms.

Figure 9. Nomograms predicting the probability of PFS and OS. Nomograms predicted probability of (A) PFS and (B) OS. GNRI exhibits highest proportion of scores in both PFS and OS nomograms (even surpassing TNM and BCLC stage), further confirming its superior predictive advantage. PFS, progression-free survival; OS, overall survival; PNI, prognostic nutrition index; GNRI, geriatric nutritional risk index; BCLC, Barcelona Clinic Liver Cancer; TNM, Tumor-Node-Metastasis.

Figure 10. Calibration curves of the nomograms. The calibration curves of the (A) PFS and (B) OS nomograms. The high consistency between the predicted survival probabilities and actual survival probabilities in the calibration curves demonstrated the high accuracy of the nomograms for PFS and OS. PFS, progression-free survival; OS, overall survival.

Discussion

The emergence of ICIs has changed the cancer treatment landscape, increasing patient survival (33). However, patients with solid tumors have a low responsiveness to ICIs and only a subset of patients may benefit from ICI treatment, including patients with HCC (34,35). Existing biomarkers are costly to assess and may not be applicable to all patients, making it difficult to further promote their use (36). Non-invasive biomarkers based on the inflammatory and nutritional status of patients have gained widespread attention due to their ease of acquisition and accuracy and have been used to predict the efficacy of ICIs in certain solid tumors with satisfactory results. Mezquita et al (37) conducted a multicenter study on lung cancer in 2018 to validate the accuracy of non-invasive indicators in predicting the efficacy of ICIs. They established a lung immune prognostic index by combining the derived neutrophil-to-lymphocyte ratio (dNLR) and lactate dehydrogenase (LDH) and found a significant correlation between this index and adverse outcomes of ICIs (37). The present study evaluated the predictive ability of commonly used inflammatory and nutritional markers on the prognosis of patients with HCC who received ICIs, offering broader references for selecting treatment strategies for these patients.

Nutritional status is closely related to immune function, and nutritional indicators have been widely studied in the application of ICIs. In 2022, Sun et al (38) collected the data of 146 patients with gastric cancer who received ICIs or chemotherapy and analyzed the predictive efficacy of PNI in these patients. The results demonstrated that PNI was not only a prognostic indicator for ICIs and chemotherapy in patients, but also an independent prognostic biomarker for disease-free survival. It is worth noting that, since ICIs were still not a standard treatment and were expensive, only a few patients with advanced gastric cancer considered using them, resulting in a significantly higher survival rate for patients who received chemotherapy than those who received ICIs (38). Certain studies focusing on GNRI validated the association between nutritional status and the efficacy of ICIs (39–41). Sonehara et al (42) assessed the survival time of 85 patients with advanced non-small cell lung cancer who were treated with ICIs and reported that those with a low GNRI had a shorter survival time. Other studies on nutritional indicators in patients receiving ICIs have reported similar findings (23,43,44). Inflammation is another of the factors that affect immune function. A study on renal cell carcinoma found that SII was a significant factor in disease progression and prognosis after analyzing its application in 49 patients who received ICIs combined with targeted therapy (45). Qi et al (46) extensively studied the application of inflammatory biomarkers in patients with small-cell lung cancer receiving ICIs. The survival status of 53 patients was prospectively analyzed and it was found that inflammatory markers were related to prognosis, in particular the platelet-lymphocyte ratio. ALI is also an accurate indicator of the inflammatory status of patients. Mountzios et al (47) collected the data of 672 patients with non-small cell lung cancer who received ICIs and analyzed the application of ALI. The results demonstrated that ALI was a significant prognostic factor for patients who received ICIs, and a high ALI was associated with a longer survival time. Subsequent studies also reported the value of ALI in predicting the prognosis of other tumors (48–50). In summary, certain inflammatory and nutritional markers have been reported to be related to the prognosis of patients with cancer.

The present study analyzed the data of 151 patients with HCC who received ICIs, to evaluate the prognostic value of classic nutritional and inflammatory markers with a larger sample size of patients than previous studies (51–53). As with previous studies, ICIs were not the preferred treatment for solid tumors and patients who received ICIs had a poor clinical and pathological status (38,54). Only one-third of patients in the present study received surgical treatment, and more than one-half of these patients had BCLC stage C and TNM stage III + IV. Survival analysis demonstrated that PNI, GNRI, NRI, SII, SIRI and ALI were all significantly associated with patient prognosis. Subgroup survival analysis also indicated that nutritional markers maintained significant prognostic value in all patients. Furthermore, although the death-based ROC curves had higher AUCs for SIRI and ALI, both the time-ROC curve and multivariate Cox regression analysis indicated predictive advantages for PNI, GNRI and NRI. Moreover, GNRI had the highest prognostic value in the present study. The nomograms indicated that the prognostic value of GNRI exceeded the value of the BCLC and TNM stage, which might be due to the uneven distribution of patients in different stages in the present study.

ICIs are a novel type of cancer treatment that inhibit receptors, such as PD-1, PD-L1 and CTLA-4, on the surface of tumor cells, thus enhancing the ability of immune cells to attack tumors (55). Therefore, the effectiveness of ICIs relies on normal immune function. The nutritional and inflammatory status could affect the immune system of the patient, thereby affecting its cytotoxicity against tumors, and consequently influencing the effectiveness of immunotherapy (56,57). Firstly, malnutrition could affect the growth and function of immune cells, thereby reducing the immune response to tumors. For example, a lack of protein and energy could lead to a decrease in the number and activity of T cells and B cells, and a decrease in the phagocytic function of macrophages, thereby decreasing the antitumor ability of the body (58,59). Secondly, inflammatory status can have a negative impact on the immune system (60). Inflammation can deplete the nutrient reserves in the body, and lead to persistent activation of immune cells and inflammatory responses, thereby inhibiting the immune response to tumors and enhancing tumor escape mechanisms (61,62). Albumin levels and weight not only reflect the nutritional status of patients, but also indicate their liver function reserve and treatment tolerance (63,64). Furthermore, 'a previous study reported that low levels of serum albumin are associated with systemic inflammation (65). Lymphocytes are a major component of both cellular and humoral immunity and serve key roles in the antitumor process (66,67). Low levels of lymphocytes can restrict the ability of the immune system to fight tumors, leading to accelerated tumor progression and metastasis. Moreover, the levels of neutrophils, monocytes and platelets can also reflect the inflammatory status of the patient and can promote tumor progression and metastasis (68–71). This may enable classic inflammatory and nutritional markers to accurately predict the prognosis of patients with HCC who receive ICIs. Furthermore, GNRI includes changes in patient weight after illness, which dynamically reflects the patient condition compared to other indicators and may more accurately reflect the condition of the patient. Albumin is synthesized by the liver and may more accurately reflect the liver status of patients with HCC. This may give GNRI a significant advantage in the prediction of clinical outcomes in patients with HCC.

The present study had certain limitations. First, the information bias inherent to retrospective studies could not be avoided. Especially as ICIs have not yet been routinely used in treating HCC and the number of patients who received ICIs in the present study was still relatively small. Second, the cut-off values of the biomarkers considered in the present study need to be further evaluated in studies with a larger sample size. Finally, the prognostic value of GNRI requires further validation through prospective studies.

In conclusion, the present study found that PNI, GNRI, NRI, SII, SIRI and ALI were all associated with the efficacy of ICIs in HCC and could serve as non-invasive biomarkers for ICI effectiveness. In addition, nutritional markers had greater predictive ability than inflammatory markers in the present study, with GNRI being the biomarker with the best prognostic value.

Acknowledgements

Not applicable.

Funding

The present study was supported by The Beijing Medical and Health Foundation (grant no. YWJKJJHKYJJ-LC19009) and The Beijing Medical Award Foundation (grant no. YXJL-2022-1350-0312).

Availability of data and materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Authors' contributions

CL and HZ performed the study and wrote the manuscript. Data curation and investigation was performed by RZ and ZG. PW was responsible for data analysis and interpretation. ZQ designed and performed the study and reviewing and editing the manuscript. All authors read and approved the final manuscript. CL and ZQ confirm the authenticity of all the raw data.

Ethics approval and consent to participate

This study was approved by The Ethics Committee of Harbin Medical University Cancer Hospital (Harbin, China; approval no., ALTN-AK105-III-06.). Due to the retrospective nature of this investigation, The Ethics Committee of Harbin Medical University Cancer Hospital waived the requirement for informed patient consent.

Patient consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

References