Prognostic role of an inflammation scoring system in radical resection of oral squamous cell carcinoma

Background Inflammatory markers can influence the postoperative prognosis and outcome of malignant tumors. However, the role of inflammatory factors in oral squamous cell carcinoma (OSCC) are still debatable. The primary objective of this investigation was to detect the preoperative blood fibrinogen and neutrophil–lymphocyte ratio (NLR) in OSCC patients and to determine the predictive validity of F-NLR (combined fibrinogen and NLR score). Methods A total of 365 patients with oral cancer after surgery were separated into three classes: F-NLR of 2, with hyperfibrinogenemia (> 250 mg/dL) and high NLR (> 3.2); F-NLR of 1, with only one higher index; and F-NLR of 0, with no higher indices. Univariate and multivariate analyses were used to identify risk factors for the demographic and clinical characteristics of patients in the three F-NLR groups. Kaplan–Meier survival analysis was used to assess the prognosis. Results Preoperative F-NLR showed a relatively better predictive role in oral cancer prognosis than fibrinogen and NLR alone. Multivariate analysis revealed that F-NLR has the potential to be an independent predictor for OSCC cancer-specific survival (P < 0.001). Patients with high scores had a relatively poorer prognosis than those with low scores (P < 0.001). Conclusions Our findings indicate that blood F-NLR may serve as an independent prognostic factor in OSCC patients.


Background
The most common cancer in the oral cavity is oral squamous cell carcinoma (OSCC) [1]. OSCC is a highly metastatic tumor, and even patients in early stages have a high rate of recurrence and metastasis. Surgery, radiation, targeted therapy, and chemotherapy are the predominant treatment options for oral cancer, depending on the kind and severity of the disease [2]. Although there have been steady advancements in treatment, OSCC has a poor prognosis when compared to other head and neck cancers. The most likely reason is a combination of variables, including tumor depth, local invasion, nodal involvement, and perineural invasion [3]. Regretfully, these parameters can only be determined after surgical excision and histological investigation. Accordingly, it is critical to determine whether blood indicators can predict OSCC prognosis during the initial clinical evaluation.
Multiple studies have been conducted for years to correlate blood inflammatory factors to predict survival in patients with OSCC. Cancer cell adhesion is facilitated by systemic inflammation, which is signaled by the increase in circulating neutrophils at the front line of defense [4][5][6]. An important feature of cancer is the ability to evade killing by the immune system [7]. Studies have shown that tumor-infiltrating lymphocytes (TILs) play a key role in tumor progression in the tumor immune microenvironment, including that of OSCC [8,9]. Multiple studies have confirmed that elevated levels of TILs are associated with good prognosis in OSCC [10,11]. Lymphocytes, particularly cytotoxic lymphocytes, influence cancer progression and cancer treatment by eliminating tumor cells [12,13]. The available evidence suggests that increased pretreatment neutrophil and lymphocyte numbers are correlated with a poor cancer outcome [14][15][16].
Fibrinogen is a protein that promotes inflammation and is produced in the liver as a result of interleukin-6 and IL-1b activation [17,18]. Fibrinogen is converted to fibrin by activated thrombin in the coagulation cascade and can regulate the development of malignant tumors [19]. Recent research has confirmed that plasma fibrinogen levels play an oncogenic role in a variety of human cancers [20][21][22][23]. NLR (neutrophil-lymphocyte ratio) has become a prognostic indicator for many malignant tumors, and a high NLR often shortens the survival of patients [24][25][26]. Alternatively, NLR could be used as an independent prognostic indicator in patients with OSCC [27]. A recent meta-analysis of 17 studies with 4597 patients showed that pre-treatment NLR correlates with a statistically significant decrease of OS in head and neck squamous cell carcinoma patients [28]. The generation of inflammatory cytokines/chemokines by neutrophils facilitates the occurrence and development of tumors by creating a suitable tumor microenvironment [29]. Currently, there is no data on the combined parameters of plasma fibrinogen and NLR in the preoperative environment to predict the prognosis of OSCC.
The objective of this research was to determine the prognostic significance of F-NLR (combined fibrinogen and NLR score) in patients with OSCC. This work will generate fresh insight into the clinical efficacy of a composite score based on F-NLR as a prognostic factor of OSCC.

Materials and methods
A total of 365 individuals with OSCC treated with radical resection at the Department of Oral and Maxillofacial Surgery, The Affiliated Huaian No.1 People's Hospital of Nanjing Medical University from February 2014 to November 2019 were enrolled in this retrospective analysis. The eligibility criteria included patients who had (1) a confirmed pathological diagnosis of OSCC; (2) no history of cancer; (3) no distant metastasis; (4) standard surgical approach: including primary tumor resection and neck dissection; (5) available clinical data and follow-up data; (6) no other conditions that could cause the blood values to change; and (7) no adjuvant radiotherapy or chemotherapy preoperatively. Patients with missing or partial data were excluded from the research. Preoperative medical and blood tests, as well as other necessary examinations, were performed on these patients to aid in the proper planning of surgery.

Blood assessment for determination of fibrinogen and NLR
One week before the start of treatment, blood samples were taken. The blood samples were immediately sent to the laboratory for testing of relevant indicators. Neutrophils and lymphocytes were measured using a SYSMEX Analyzer CS5100, Japan. Plasma fibrinogen concentrations were detected by a SYSMEX analyzer XN-9000, Japan. The measured indices were recorded, and the NLR is indicated as the neutrophil count/lymphocyte count.

Calculation of prognostic scores
The cutoff threshold for fibrinogen based on our study was 250 mg/dL. The cutoff threshold of NLR based on our data was 3.2. The F-NLR score was classified into three groups: F-NLR of 2, with hyperfibrinogenemia (> 250 mg/dL) and high NLR (> 3.2); F-NLR of 1, with only one higher index; and F-NLR of 0, with neither hyperfibrinogenemia nor high NLR.

Follow-up
Follow-up was performed monthly for the first 6 months and then every 6 months via telephone follow-up or clinical follow-up. From the time of surgery to death because of OSCC, the duration of cancer-specific survival (CSS) was recorded.

Statistical analysis
Univariable and multivariable analyses were used to evaluate clinical factors for CSS. Categorical data were analyzed by the chi-square test or Fisher's exact test. Continuous data were compared by the Mann-Whitney U test. Multivariate Cox regression analysis and Kaplan-Meier analysis were utilized to assess CSS of OSCC. All data analyses were performed with SPSS (IBM SPSS 22.0, SPSS Inc.). Statistical tests were two-sided and considered significant with a P value < 0.05.

Demographic data
A total of 365 patients who were eligible to participate were included in this study. The age of treatment ranged from 21 to 90 years, with males averaging 64 years and females averaging 63 years. A total of 174 (47.7%) of the patients were females, whereas 191 (52.3%) were males. Tumor size ≤ 4 cm (80.0%) and no lymph node metastases (78.4%) were the most common clinicopathological characteristics (Table 1).

Correlation of fibrinogen and NLR with clinicopathological characteristics
Patients were divided into three groups according to F-NLR (0, n = 100; 1, n = 203; 2, n = 62). The clinicopathological characteristics of the patients in the three groups are listed in Table 2. Higher F-NLRs were associated with tumor size (P = 0.0301), cervical node metastasis (P = 0.0039) and lymphatic and vascular invasion (LVI) (P = 0.0009).

Risk factors for the prognosis of OSCC
Fourteen clinicopathological parameters were included in the univariate analyses, and nine significant parameters for univariate analysis were included in the multivariate analyses (Table 3). Multivariate analysis showed that F-NLR was an independent prognostic factor for cancer-specific survival (HR for F-NLR 1 and F-NLR 2: 26.566 and 3.895; 95% CI 5.589-126.258 and 1.321-11.485; P < 0.001 and P = 0.014, respectively). Patients with high F-NLR had a poor prognosis (Fig. 2).
In a stratified analysis based on tumor size and lymph node metastasis, the results showed that the prognostic value of F-NLR was maintained for T1-T2

Discussion
Oral cancer is the world's 11th most prevalent cancer [30]. Diagnosis at the early stage is critical for improving patient survival rates. When identified early, the survival probability is approximately 80-90% [31]. Therefore, it is critical to assess patients' prognostic variables before surgery. Plasma biomarkers have great potential for predicting tumor recurrence, because they can help surgeons make more individualized treatment plans [32]. Furthermore, these markers can be collected through standard blood testing prior to surgery, which is both cost effective and convenient. Patients with cancer frequently have a better prognosis when there is no inflammation. The detection of circulating cell components is the most common method for measuring the degree of activation of the systemic inflammatory response [33]. For several common peripheral blood-derived inflammation scores, neutrophils play an active role in promoting tumor progression [34]. TILs play important roles in the progression of OSCC. Three main immunophenotypes are currently recognized according to the distribution of T cells in the tumor: immune-inflamed, immune-excluded, and immune-desert [35]. Immune-inflamed tumors are characterized by a dense infiltration of immune cells in close proximity to tumor cells. Immune-excluded tumors are characterized by the presence of large numbers of immune cells that do not penetrate the tumor F-NLR the combined fibrinogen and NLR score, F-NLR of 2, with hyperfibrinogenemia (> 400 mg/dL) and high NLR (> 2.5), F-NLR of 1, with only one higher index, and F-NLR of 0, with neither hyperfibrinogenemia nor high NLR, NLR Neutrophil-to-lymphocyte ratio, MPV mean platelet volume, PNI perineural invasion, LVI lymphatic and vascular invasion     [36]. Based on the above results, lymphocytes can significantly inhibit the proliferation of tumors [37]. Therefore, the NLR can serve as a reliable tumor prognostic factor. Numerous studies have confirmed that NLR is a prognostic factor for a variety of benign and malignant tumors and a representative indicator of tumor-associated inflammation, and NLR has been shown to have predictive value for oral cancer [38][39][40][41]. Activation of the coagulation cascade has a substantial effect on the development of cancer, and fibrinogen has been shown to be one of the regulators of systemic inflammation and tumor progression [42,43]. These studies have laid a solid foundation for the next step to explore the role of inflammatory factors in the prognosis of oral cancer. In this study, patients with advanced tumors tended to have a high fibrinogen level and high NLR. In addition, high fibrinogen and high NLR were found to be important indicators for predicting clinical outcome in this study (P < 0.001 and P = 0.008). The results of our study are consistent with those of previous meta-analyses, showing that high NLR significantly reduces the survival time of head and neck squamous cell carcinoma patients [28]. We propose the following mechanism of action: Fibrinogen may function by forming a protective framework that facilitates tumor migration, invasion, and angiogenesis. Tumor cells create an inflammatory state in the body and accelerate the production of fibrinogen in the liver, thus forming a vicious cycle. We also confirmed that age, tumor size, and cervical nodal metastasis are independent prognostic factors for oral squamous cell carcinoma, as previously reported by Broglie et al. [44] and Patel et al. [45]. Interestingly, the multivariate analysis showed that different MPV (mean platelet volume) levels can also significantly affect the prognosis of oral cancer. MPV is an indicator . F-NLR combined fibrinogen and NLR score, NLR neutrophil-to-lymphocyte ratio, CSS cancer-specific survival, OSCC oral squamous cell carcinoma of platelet activation and has been found to be a prognostic indicator in a variety of cancers [46]. The value of MPV as a prognostic indicator may be that activated platelets promote the secretion of cytokines, such as platelet-derived endothelial cell growth factor, which accelerates tumorigenesis [47]. In a study observed over 30 years, Zanoni et al. found that perineural invasion (PNI) and lymphatic and vascular invasion (LVI) were independent prognostic factors of OSCC [48]. However, unlike the previous study, our data analysis showed that only LVI was prognostic factor for OSCC, but PNI was not statistically different. The reason may be that we only have nine PNI positive patients, and analyses with larger sample sizes require further validation.
The new scoring system (F-NLR) is a good predictor for the prognosis of a variety of malignancies. Wang et al. proved that F-NLR can independently predict the prognosis of patients with non-small-cell lung cancer [49]. Data from Felice's studies showed that F-NLR is substantially related to worse survival results in individuals with anal canal cancer [50]. The above research has established that the F-NLR is a reliable scoring system for assessing malignant tumors. No detailed investigation of the application prospects of the F-NLR scoring system in oral cancer has been performed. Therefore, this retrospective study was performed to identify the association of F-NLR with prognosis after radical resection of oral cancer.
For predictive analysis following radical excision of oral cancer, we separated the patients with different F-NLR into three independent groups. The results suggested that F-NLR, as predicted, can identify more individuals with a worse prognosis than fibrinogen or NLR alone. This finding demonstrates that F-NLR may be more reliable than individual scores. The median survival times were 62 months (scores of 0) and 41 months (scores of 1-2), respectively. Patients with high F-NLR had a substantially poorer prognosis than those with low scores. Meanwhile, these data show that F-NLR is connected to tumor development and aggressiveness. In our subgroup analyses, F-NLR was a good prognostic factor; for example, in patients with T1-T2 tumor sizes and different lymph node metastases, the F-NLR scoring system showed a good prognostic effect.
This study has some limitations. First, a single-center retrospective study may lead to selection bias. Second, the short follow-up period was not sufficient to further assess the survival of patients. Consequently, a more comprehensive multicenter prospective study is needed to confirm that F-NLR does independently predict prognosis in patients with OSCC.
According to the findings of this study, F-NLR has clinical promise as a low-cost prognostic factor in patients with OSCC.

Conclusion
This study suggests that the F-NLR is an independent prognostic indicator for the survival rate of OSCC.