This article is mentioned in:

Introduction

Lung cancer is one of the most common cancers in clinic, it is often found in mucosal epithelium of bronchus (1). Studies showed that in 2016 new patients with lung cancer increased ~2.67 million worldwide, and the morbidity of lung cancer ranked the second among all cancers (2). Lung adenocarcinoma is a lung cancer where the age of onset tends to be younger (3). At present, the pathogenesis of lung adenocarcinoma is still unclear. Tumor metastasis easily occurs in lung adenocarcinoma and ~30% of patients with advanced lung adenocarcinoma have metastasis, which makes the fatality rate of lung adenocarcinoma the highest among all cancers (4,5). It has been shown that without effective treatment, the median survival time of this type of patients is only 1 month (6). The most effective means of treating lung adenocarcinoma in clinic are resection, radiotherapy and chemotherapy (7). At present, with the development of the treatment of tumor diseases, lung cancer resection has been improved and nidus separation can be finished preferably in patients during resection (8), however, in the process of postoperative chemotherapy, side effects easily appear when normal lung tissue in the radiation field is injured (9). Patients with slight injury have difficulty in breathing and impairment of lung function, while in severe cases patients present extensive pulmonary fibrosis, which directly threatens their life (10). Therefore, the way to improve the therapeutic effective rate of lung adenocarcinoma is a major focus in current clinical research. Molecular targeted therapy has become a hotspot in research. Some data have demonstrated that AFAP1-AS1, CDK4, CDK6 and NAT8L may become potential targets of future clinical treatment of lung cancer (11–13). Epidermal growth factor receptor-tyrosine kinase inhibitor (EGFR-TKI) has an extremely important influence on lung adenocarcinoma (14). Cancer factors enhance the susceptibility of tumor tissue for programmed cell death protein 1 (PD-1) blockade via EGFR pathway, and the key of EGFR-TKI is inhibiting the combination of PD-1 and EGFR (15). It has been proven that lung adenocarcinoma receives the largest beneficial effect when EGFR-TKI is applied in the treatment of non-small cell carcinoma (16,17), but it is still controversial how to better predict the clinical efficacy and prognosis of patients. Carcinoembryonic antigen (CEA) is currently the most sensitive tumor marker (18), and lactate dehydrogenase (LDH) is a prognostic indicator that is closely related to tumor cell load and distant metastasis (19). There are few studies on the two in the targeted therapy of lung adenocarcinoma, therefore, this report retrospectively analyzed patients with lung adenocarcinoma who were admitted and treated in The First People's Hospital of Chuzhou (Chuzhou, China) since 2014 to investigate the significance of CEA and LDH in the targeted therapy of lung adenocarcinoma.

Patients and methods

General data

Eighty-nine patients with lung adenocarcinoma, who were admitted to The First People's Hospital of Chuzhou from January 2014 to February 2015, were the study subjects and were analyzed retrospectively. Among the patients, there were 38 patients with EGFR sensitive mutation, accounting for 42.70% of all subjects. There were 34 males and 55 females, aged from 37 to 69 years, with an average age of 51.63±11.74 years.

Inclusion and exclusion criteria

Inclusion criteria: all patients who were diagnosed with lung adenocarcinoma via biopsy in the Pathology Department of The First People's Hospital of Chuzhou; patients who received lung tissue resection or EGFR-TKI targeted therapy in The First People's Hospital of Chuzhou; patients with complete clinical data; patients 40–65 years of age. Exclusion criteria: patients with other abnormalities in cardiopulmonary functions before the preoperative diagnosis; with other tumor diseases, blood diseases, immune diseases, or physical disabilities; who were chronically ill; patients in gestation period; patients who had surgical contraindications; patients who had received chemotherapy before operation; patients pathologically diagnosed with local or distant metastasis after operation. The study was approved by the Ethics Committee of The First People's Hospital of Chuzhou. Patients had complete clinical data and signed informed consents were obtained from the patients and/or the guardians.

Methods

Among the 89 study subjects, 51 patients received resection in The First People's Hospital of Chuzhou and were set as the operation group; the other 38 patients received EGFR-TKI targeted therapy in The First People's Hospital of Chuzhou, and were considered the targeted group. The operations were performed by the senior chief clinicians. The therapeutic drug was AZD9291, also known as Osimertinib, which is the third generation of EGFR-TKI. This compound is an irreversible mutant selective EGFR-TKI (exon 19 deletion type EGFRIC50=12.92 nM, L858R/T790M EGFR IC50=11.44 nM, wild-type EGFR IC50=493.8 nM), oral administration, 80 mg, PO QD.

Venous blood of patients (5.0 ml) was taken before surgery, 4 weeks after the targeted therapy, or 1 week after surgery. CEA electrochemiluminescence kit (cat. no. LT13001; Quanzhou Lantu Biotechnology Co., Ltd., Quanzhou, China) was used to detect the expression of CEA in serum with UniCel DxI 800 immunoassay system (Beckman Coulter, Inc., Brea, CA, USA), and an automatic biochemical analyzer (Beckman Coulter, Inc., Shanghai, China) was used to detect the expression of LDH in serum.

Observation indicators

The clinical data of patients in the two groups included sex, age, weight, and course of disease. The therapeutic effective rate was calculated using the Response Evaluation Criteria in Solid Tumors (RECIST) of 2012 as a reference (20) and the patients were separated into four stages, based on complete response (CR), partial response (PR), stable disease (SD) and progressive disease (PD). All patients took imageological examination at the 5th week after the treatment, and the imageological results were used for the evaluation and reference of the final efficacy. Therapeutic effective rate = (the number of patients who were graded in CR+PR)/total number ×100%. Patients in the targeted group were given a 3-year prognostic follow-up in the form of call, letter, hospital review and visit. The deadline of the follow-up was April 2018 and the ultimate event was the death of the patient. The 3-year survival rate of the patients was recorded.

Statistical analysis

SPSS 24.0 statistical software (Shanghai Yuchuang Network Technology Co., Ltd., Shanghai, China) was used to analyze and process all data; the enumeration data were expressed in the form of rate, and Chi-square (χ2) test was used for their comparison between groups; the measurement data were expressed as the mean ± standard deviation, and paired t-test was used for their comparison between groups. Kaplan-Meier survival analysis was used for the survival curves and log-rank test was used for the comparison of the survival rates. P<0.05 was considered to indicate a statistically significant difference.

Results

Comparison of the clinical data

There were no significant differences concerning age, weight, course of disease, sex, smoking, drinking, place of residence, tumor metastasis and differentiated degree of patients between the two groups (P>0.050). This proves that there was comparability between the patients of the two groups. Details are shown in Table I.

Table I. Comparison of the patients' clinical data between the two groups [n (%)].

Table I.

Comparison of the patients' clinical data between the two groups [n (%)].

Characteristics	Targeted group (n=38)	Operation group (n=51)	χ2 or t	P-value
Age (years)	51.67±12.33	50.84±11.96	0.320	0.750
Weight (kg)	72.96±15.68	74.24±16.07	0.376	0.708
Course of disease (weeks)	3.52±1.66	3.70±1.54	0.528	0.599
Sex			0.045	0.831
Male	15 (39.47)	19 (37.25)
Female	23 (60.53)	32 (62.75)
Smoking			0.163	0.686
Yes	8 (21.05)	9 (17.65)
No	30 (78.95)	42 (82.35)
Drinking			0.112	0.738
Yes	5 (13.16)	8 (15.69)
No	33 (86.84)	43 (84.31)
Place of residence			0.362	0.547
City	31 (81.58)	44 (86.27)
Countryside	7 (18.42)	7 (13.73)
Tumor metastasis			0.056	0.813
Yes	9 (23.68)	11 (21.57)
No	29 (76.32)	40 (78.43)
Differentiated degree			0.159	0.924
High	13 (34.21)	16 (31.37)
Middle	20 (52.63)	29 (56.86)
Low	5 (13.16)	6 (11.76)

Comparison of the therapeutic effective rate

In the targeted group, 52.63% of the cases were CR, 28.95% were PR, 13.16% were SD, and 5.26% were PD; the therapeutic effective rate was 81.58%. In the operation group, 56.86% of the cases were CR, 25.49% were PR, 9.80% were SD, and 5.88% were PD; the therapeutic effective rate was 82.35%. The differences were found to be statistically not significant when the therapeutic effective rates of the two groups were compared (P>0.050) (Table II).

Table II. Comparison of the therapeutic effective rate [n (%)].

Table II.

Comparison of the therapeutic effective rate [n (%)].

Items	Targeted group (n=38)	Operation group (n=51)	χ2	P-value
CR	20 (52.63)	29 (56.86)	0.787	0.375
PR	11 (28.95)	13 (25.49)	0.132	0.716
SD	5 (13.16)	5 (9.80)	0.246	0.620
PD	2 (5.26)	4 (7.84)	0.016	0.900
Effective rate (%)	81.58	82.35	0.009	0.925

[i] CR, complete response; PR, partial response; SD, stable disease; PD, progressive disease.

Comparison of the expression levels of LDH and CEA

The expression levels of LDH in the targeted group before and after treatment were 224.56±12.67 and 163.75±9.24 U/l, respectively; the expression levels of LDH in the operation group before and after treatment were 230.64±13.08 and 160.54±9.87 U/l, respectively. There was no significant difference in the LDH of the patients in the two groups before or after treatment (P>0.050). The expression level of LDH after treatment was lower than that before treatment (P<0.050) in both groups. The expression levels of CEA in the targeted group before and after treatment were 20.77±3.68 and 3.54±0.62 ng/ml, respectively; the expression levels of CEA in the operation group before and after treatment were 21.34±3.92 and 3.27±0.70 ng/ml, respectively. There was no significant difference in CEA of patients in the two groups before or after treatment (P>0.050). The expression level of CEA after treatment was lower than that before treatment (P<0.050) in both groups (Figs. 1 and 2).

Figure 1. Comparison of the expression level of LDH between the targeted and the operation group before and after treatment. The level of LDH in the serum of the patients was detected by using an automatic biochemical analyzer. The results showed that there was no significant difference in the expression level of LDH between the two groups before or after treatment. The expression level of LDH after treatment decreased in both groups when compared to that before treatment. *P<0.050, compared with the expression level of LDH in the same group before treatment. LDH, lactate dehydrogenase.

Figure 2. Comparison of the expression level of CEA between the targeted and the operation group before and after treatment. The level of CEA in the serum of the patients was detected by electrochemiluminescence. The results showed that there was no significant difference in the expression level of CEA between the two groups before or after treatment. The expression level of CEA after treatment decreased in both groups when compared to that before treatment. *P<0.050, compared with the expression level of CEA in the same group before treatment. CEA, carcinoembryonic antigen.

Difference of efficacy of the targeted groups

According to the medians of LDH and CEA expression levels in patients of the two groups before treatment, 20 cases were in LDH high-expression group (LDH≥224.56 U/l); 18 patients were in LDH low-expression group (LDH<224.56 U/l); 17 patients were in CEA high-expression group (CEA≥20.77 ng/ml); and 21 patients were in CEA low-expression group (CEA<20.77 ng/ml). The therapeutic effective rate of LDH high-expression group was 65.00%, which was significantly lower than that of LDH low-expression group (100.00%) (P=0.004). The therapeutic effective rate of CEA high-expression group was 64.71%, which was also significantly lower than that of CEA low-expression group (95.24%) (P=0.016). Details are shown in Tables III and IV.

Table III. Therapeutic effective rate of LDH high and low-expression groups [n (%)].

Table III.

Therapeutic effective rate of LDH high and low-expression groups [n (%)].

Items	LDH high-expression group (n=20)	LDH low-expression group (n=18)	χ2	P-value
CR	5 (25.00)	14 (77.78)
PR	8 (40.00)	4 (22.22)
SD	5 (25.00)	0 (0.00)
PD	2 (10.00)	0 (0.00)
Effective rate (%)	65.00	100.00	8.485	0.004

[i] LDH, lactate dehydrogenase; CR, complete response; PR, partial response; SD, stable disease; PD, progressive disease.

Table IV. Therapeutic effective rate of CEA high and low-expression groups [n (%)].

Table IV.

Therapeutic effective rate of CEA high and low-expression groups [n (%)].

Items	CEA high-expression group (n=17)	CEA low-expression group (n=21)	χ2	P-value
CR	5 (29.41)	15 (71.43)
PR	6 (35.29)	5 (23.81)
SD	4 (23.53)	1 (4.76)
PD	2 (11.76)	0 (0.00)
Effective rate (%)	64.71	95.24	5.828	0.016

[i] CEA, carcinoembryonic antigen; CR, complete response; PR, partial response; SD, stable disease; PD, progressive disease.

Prognosis

Among the 38 patients in the targeted group, 37 patients were successfully followed up, and the success rate of the follow-up visit was 97.37%. There were 19 patients in LDH high-expression group, 18 patients in LDH low-expression group, 16 patients in CEA high-expression group and 21 patients in CEA low-expression group. The 3-year total mortality of LDH high-expression group was 47.37%, which was significantly higher than that of LDH low-expression group (11.11%) (P=0.034). The 3-year total mortality of CEA high-expression group was 56.25%, which was significantly higher than that of CEA low-expression group (4.76%) (P=0.020). When the data of all the deceased patients were compared, it was concluded that 14 patients (77.78%) had high-expression of LDH and CEA (Figs. 3 and 4).

Figure 3. The survival curves of LDH high and low-expression groups at 3 years after prognosis. The total mortality of LDH high-expression group at 3 years was 47.37%, which was significantly lower than that of LDH low-expression group (11.11%, P=0.034). LDH, lactate dehydrogenase.

Figure 4. The survival curves of CEA high and low-expression groups at 3 years after prognosis. The total mortality of CEA high-expression group at 3 years was 56.25%, which was significantly lower than that of CEA low-expression group (4.76%, P=0.020). CEA, carcinoembryonic antigen.

Discussion

The morbidity and mortality of lung adenocarcinoma are extremely high in clinic (21). The scheme of diagnosis and treatment of lung adenocarcinoma has long been a research hotspot in clinic, and targeted therapy has gradually become popularized in recent years. Compared with traditional resection, radiotherapy and chemotherapy, the targeted therapy is safer in ensuring the effective remission of patients' tumors, and it achieves the purpose of treating tumors by regulating one or more factors directly related to tumors (21,22). While EGFR-TKI is applied in lung adenocarcinoma, the mechanism is using the combination between gefitinib or erlotinib and EGFR in lung adenocarcinoma cells, and disrupting the signal transduction of the downstream cells by inhibiting the activation of tyrosine kinase, thereby preventing the spread, infiltration and metastasis of cancer cells (23). However, some related drug resistance usually appears in most patients in the process of targeted therapy, which weakens the therapeutic effect of targeted drugs (24). So it is particularly important to monitor the therapeutic effect and estimate the condition of prognosis in the process of targeted therapy.

In this study, the difference of the efficacy between EGFR-TKI targeted therapy and traditional resection for the patients with lung adenocarcinoma, and the expression levels of LDH and CEA were investigated. The significance of the expression levels of LDH and CEA and the effect of prognosis of LDH and CEA in patients with lung adenocarcinoma who were treated with EGFR-TKI targeted therapy were also investigated. Results showed that there is no significant difference in the therapeutic effective rates and the expression of LDH and CEA between the targeted and the operation group, which suggests that EGFR-TKI targeted therapy has an extremely high application value for treating lung adenocarcinoma. LDH mainly belongs to the enzyme in the glycolytic pathway and plays a great role in facilitating the formation of lactic acid, which originates from pyruvate (25). In general, LDH exists in almost every cell of the organisms, and its activity is generally high in human body. Therefore, LDH does not have high specificity for the early diagnosis of diseases, and it is often used as a reference to prognostically monitor and estimate the state of the disease of patients (26). CEA is a glycoprotein that only exists in cancer and embryonic tissues, and directly acts on the adhesion reaction between tumor cells, which has a strong regulatory ability on the differentiation, apoptosis, infiltration and metastasis of cancer cells (27). In this study, there was no difference between the targeted and the operation group, which proves that EGFR-TKI targeted therapy could effectively improve the condition of tumor nidus of lung adenocarcinoma in patients, reduce the tumor volume in patients, and achieve the purpose of treating tumors. In addition, there was no difference in the expression of CEA and LDH before or after treatment between the two groups, which preliminarily suggests that these indicators could be generally applied for the treatment of lung cancer, and errors in expression levels would not be caused by traumatic surgery. However, more in-depth research is required for comparison in order to obtain most accurate experiment results. The contingency could not be excluded due to the small sample size in this study. Analysis of the efficacy and the difference of prognosis of patients in CEA high-expression group, CEA low-expression group, LDH high-expression group and LDH low-expression group in the targeted group showed that CEA and LDH high-expression groups were both significantly worse than CEA and LDH low-expression groups. This suggests that CEA and LDH both have a high application value for monitoring the efficacy and prognosis of patients who receive EGFR-TKI targeted therapy. Tumor cells can perform unlimited aerobic glycolysis with the support of enough nutrition, while the main substance that provides nutrition for them is LDH (28). It is speculated that due to the incomplete elimination of tumor nidus, cancer cells consume a large amount of oxygen in patient's body, thus the patient's body is chronically in a state of hypoxia, which induces the enhancement of glycolysis and raises the level of LDH, allowing tumor cells to get enough energy again to further metastasize and invade. So, the prognosis of LDH high-expression group is significantly worse than that of LDH low-expression group. CEA, a tumor marker, reflects the active ability of tumors. The higher its expression is, the stronger the activation ability of tumors is, thereby, the prognosis is worse.

In this study, the difference of efficacy between EGFR-TKI targeted therapy and traditional resection in the treatment of patients with lung adenocarcinoma and the expression of LDH and CEA were investigated, and the significance of the expression and the effect of prognosis of LDH and CEA in patients with lung adenocarcinoma treated with EGFR-TKI targeted therapy were also investigated. There were some limitations because of the lack of experimental conditions. For example, the sample size was small, and the experimental population was uniform. Also, the time of the follow-up was short. LDH and CEA are both reactants with low specificity, and the abnormal expression of them could occur in patients with severe infections and organ damage.

In conclusion, the levels of CEA and LDH in serum are abnormally expressed in the process of EGFR-TKI targeted therapy of lung adenocarcinoma, which is of great significance for monitoring the efficacy and prognosis of the therapy of lung adenocarcinoma targeted by EGFR-TKI.

Acknowledgements

Not applicable.

Funding

No funding was received.

Availability of data and materials

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

Authors' contributions

GH, ZJ and SX recorded and analyzed the observation indicators. XS and WW collected and interpreted the patients' data using electrochemiluminescence, the automatic biochemical analyzer and SPSS 24.0 statistical software. GH wrote and revised the manuscript. All authors read and approved the final manuscript.

Ethics approval and consent to participate

The study was approved by the Ethics Committee of The First People's Hospital of Chuzhou (Chuzhou, China). Patients who participated in this research had complete clinical data and signed informed consents were obtained from the patients and/or the guardians.

Patient consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

References