Open Access

CT-guided aspiration lung biopsy for EGFR and ALK gene mutation analysis of lung cancer

  • Authors:
    • Weisheng Lian
    • Yong Ouyang
  • View Affiliations

  • Published online on: March 27, 2017     https://doi.org/10.3892/ol.2017.5921
  • Pages: 3415-3422
  • Copyright: © Lian et al. This is an open access article distributed under the terms of Creative Commons Attribution License.

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Abstract

The present study investigated the rates of detection and the positive rates of computed tomography (CT)-guided aspiration of lung biopsy for epidermal growth factor receptor (EGFR) gene and anaplastic lymphoma kinase (ALK) gene, and analyzed the relationship between gene mutation and clinical characteristics to improve the rate of related factors of gene detection. The clinical data and CT-guided aspiration biopsy specimen of 250 patients with lung cancer. Data showed that the rate of EGFR gene mutation was 41.2% (103/250) in biopsy specimens of non-small cell lung cancer patients. The rate of EGFR gene mutation of adenocarcinoma (56.6%, P<0.01) was higher than other types of lung cancer. ALK gene mutation of patients in phase IV was obviously higher than that of patients not in phase IV (18.5 and 1.8%, P<0.01). The rate of EGFR gene detection was 83.2% (208/250). The rate of detection of tumor cells >50 was higher. The rate of ALK protein immunohistochemical detection was 87.2%, and the rate of coarse needle biopsy detection was higher than that of the fine needle (91 and 72%, P<0.01), but the positive rate between coarse needle biopsy and fine needle biopsy had no difference (P>0.05). The rate of detection was associated with tumor cell number (P<0.05), and had no correlation with the proportion of tumor cells (P>0.05). The rate of detection of EGFR and ALK genes was associated with tumor cell number and had no correlation with the proportion of tumor cells. The rate of detection is higher when the number of tumor cells is more than 50.

Introduction

Lung cancer is the most common malignant tumor globally. According to the data of the World Health Organization (WHO) in 2008, death toll caused by lung cancer was 1.38 million all over the world each year, ranking the first in all malignant tumors (1). In 2005, the new cases of lung cancer in China were ~500,000 cases, including ~330,000 cases of males and 170,000 cases of females. Epidemiological study pointed out that lung cancer caused 89,200 deaths in urban and rural areas in China in 2009 (2). Therefore, studies on early lung cancer have very important medical and social significance (3). Non-small cell lung cancer (NSCLC) refers to all types of lung cancer except for small cell lung cancer. Its incidence accounts for ~80% of the total cases of lung cancer, among which ~2/3 of patients have distant metastases. In case of lack of anticancer treatment, their mean survival time is 4–5 months (1). Chemotherapy is the main treatment means, but the prognosis remains poor (4). NSCLC consists of three types, namely adenocarcinoma, squamous carcinoma and large cell carcinoma, among which adenocarcinoma is a more common tissue type (5).

In recent years, individualized treatment with molecular targeted therapy as the core content has become the research hotspot of lung cancer treatment and the detection of driver genes related to lung cancer has attracted increased attention (6,7). The epidermal growth factor receptor (EGFR) gene and anaplastic lymphoma kinase (ALK) fusion gene are the two driver genes proved in NSCLC (8,9). Their corresponding targeted drugs, including tyrosine kinase inhibitor (TKI) and crizotinib show good curative effects in clinical studies (10,11). Two phase III prospective randomized clinical trials showed that as a first-line treatment means, TKI gefitinib could more effectively prolong the progression-free survival (PFS) of patient, compared with chemotherapy protocol based on platinum PFS (12,13). Overall response rate of crizotinib to the phase I clinical trial treatment of ALK positive NSCLC patients reached 64% (14). Based on the test results of PROFILE 1001 and PROFILE 1005, the indications of crizotinib in ALK positive advanced NSCLC obtained accelerated approval by the U.S. Food and Drug Administration (FDA) in August 2011 (10).

Many studies showed that the utilization of corresponding targeted drug treatment of molecular targets for gene variation patients could not only prolong PFS obviously, but also significantly improve living quality, compared with chemotherapy (7). At present, all guidelines recommend that EGFR and ALK detection should be conducted before treatment so as to benefit patients from targeted drug treatment as soon as possible. In NCCN Guidelines 2014, EGFR and ALK detection of non-squamous carcinoma were listed in class 1 evidence recommending, while non-smoking squamous carcinoma should also take the detection of EGFR and ALK genes into consideration. With the rapid development of molecular biology and the maturity of gene detection technology, the effects of molecular targeted drugs in lung cancer treatment have been paid more and more attention and its curative effects were also recognized in the clinic, so it is necessary to improve the clinical gene detection.

Computed tomography (CT)-guided percutaneous lung aspiration biopsy has been widely used in clinic and has become important for the diagnosis and differential diagnosis of refractory lung diseases. For patients with advanced lung cancer who are not suitable for operation, cytological specimens may be the important source for their EGFR and ALK gene mutation detection. However, such invasive examination has many complications at present. Some clinical practices found that the clinical complications of CT-guided fine needle aspiration biopsy were much less than those of coarse needle aspiration biopsy. Under the premise of ensuring the rate of detection of certain gene, the utilization of fine needle aspiration biopsy for specimens applicable to fine needle aspiration could not only reach the target of gene detection, but also reduce clinical complications. From the perspective of application, small specimens (including lung aspiration and bronchoscope specimens) had greater application prospect. The rate of mutation of EGFR gene in Asian patients with lung adenocarcinoma was ~60.5% and the rate of expression of EML4/ALK fusion gene in Asian patients with NSCLC was ~10% (15,16).

Scorpion amplification refractory mutation system (Scorpion ARMS) is applied in the detection of EGFR gene mutation. It is a new technology that combines ARMS and Scorpion PCR technologies. Scorpion probe can detect mutant gene with the content as low as 1% in samples, with the characteristics of high sensitivity and strong specificity. It is especially suitable for aspiration and cytological specimens with less tumor cells (17).

At present, there are three methods for the detection of ALK fusion gene, namely based on PCR amplification technology, fluorescence in situ hybridization (FISH) and immunohistochemistry (IHC) (18). By virtue of the advantages, including simple operation and low price, IHC becomes the important method used for ALK detection at present. Ventana IHC has been approved to be used in the detection of ALK fusion gene by the European Union, China and other countries. Many studies also showed that Ventana IHC method and FISH method have high coherence in sensitivity and specificity (19). Moreover, compared with FISH detection method, Ventana detection was more efficient (the detection could be finished within 48 h generally) and it is relatively inexpensive, and has low requirements for detection personnel. The detection could be performed under a light microscope and the structure of tumor tissues and histological patterns of tumor cells could also be observed simultaneously. Due to the application of two-spot interpretation method, this method greatly reduced the effects of subjective factors on results (20,21). Therefore, this study applied Scorpion ARMS method and Ventana ALK (D5F3) IHC method, respectively, in the screening of EGFR and ALK fusion genes.

We conducted CT-guided coarse/fine needle aspiration for the detection of EGFR gene and ALK gene for 250 cases of NSCLC patients and analyzed the relationship between clinical characteristics and gene mutation so as to specify the rate of detection and the positive rate of CT-guided coarse/fine needle aspiration biopsy specimen used for gene detection and improve the rate of relevant factors of detection.

Patients and methods

Patients

The clinical data and CT-guided aspiration biopsy specimen of 250 patients with lung cancer admitted in Zhejiang Cancer Hospital from June 2014 to August 2015 were collected. Appropriate aspiration needles were selected according to tumor location and size, including 50 cases of fine needle aspiration and 200 cases of coarse needle aspiration. Clinical data included admission number, pathology number, age, gender, smoking history, clinical stages and pathological results (including pathological patterns, differentiation degree and IHC results). Appropriate aspiration needles were selected according to tumor location and size. Coarse needle applied BioPince 17-gauge coaxial automatic biopsy needle or Precisa 18- and 16-gauge semi-automatic biopsy needles to conduct aspiration biopsy, while fine needle applied Precisa 20-gauge semi-automatic biopsy needle or Cook 19-gauge coaxial semi-automatic biopsy needles (Shengdi Medical Instrument Company, Beijing, China) to conduct aspiration biopsy. This study was approved by the Ethics Committee of Zhejiang Cancer Hospital. All specimens were obtained before treatment and the patients or their families signed informed consent form for aspiration.

Research methods
CT-guided percutaneous aspiration biopsy

Percutaneous coarse/fine needle aspiration was conducted under the guidance of large-aperture spiral CT (Siemens AG, Berlin, Germany). Appropriate position was selected according to lesion location and the scanning area depending on the area of the lesion. CT scanning parameters: 120 kV for tube voltage, 220 mA for tube current, 5 mm for section thickness and 1.0 for guided pitch. Aspiration point was determined by applying metal mark locating method so as to avoid rib or scapula and substantial lesion was selected according to CT values. The fine needle applied Cook 19-gauge coaxial semi-automatic biopsy needle or Precisa 20-gauge semi-automatic biopsy needle, while coarse needle applied BioPince 17-gauge coaxial automatic biopsy needle or Precisa 18- and 16-gauge semi-automatic biopsy needles. The distance, depth and angle of needle insertion were measured. After routine disinfection, darpe and local anaesthesia, positioning aspiration was conducted to obtain tissues. After aspiration, CT scanning was repeated so as to obtain information whether there was pneumothorax, bleeding or other complications.

Specimen processing

Fine or coarse needle aspiration specimen was made into a cell wax block for use through fixing in 4% neutral formalin and embedding in paraffin. Before gene detection, whether the quantity and ratio of tumor cells in cell sections in each case of aspiration specimen met standards was observed. The ratio of tumor cells was calculated by average ratio of the number of specimen in hematoxylin and eosin (H&E) section counting tumor cells under an ordinary light microscope (Olympus, Tokyo, Japan) to the number of nucleated cells and the ratio of tumor cells, respectively, counted in 5 high-power fields (x400) selected from the most enriched area of tumor cells. In case the number of high-power fields did not reach 5, the average value of tumor cell ratios was taken according to actual number of fields, among which the absolute value of tumor cells counted in the field with the highest ratio was taken. The above were interpreted and recorded independently by two researchers, and then the results were checked. In case of inconsistent results, they were decided through consultation or interpreted by a third researcher.

EGFR gene mutation detected by ARMS method

The remaining tissues of the specimens obtained from CT-guided lung cancer aspiration biopsy after pathological diagnosis were used for EGFR gene detection. Eight to ten pieces of paraffin with the section thickness of 5–8 µm were cut from paraffin-embedded tissues, wrapped and put into a 1.5-ml centrifuge tube. In case of slicing, the slicing knife was disinfected with 75% alcohol between cases so as to prevent cross contamination. A piece of H&E staining section should be cut simultaneously from all specimens so as to judge the content of tissues in tumor cells. Tissue DNA was extracted and its concentration was measured by ultramicrospectrophotometer (Nano Photonics, Shanghai, China). The EGFR gene of aspiration specimens was detected by Scorpion ARMS (Gemma Gene Co., Shanghai, China). Moreover, the relationship between the number and ratio of clinical tumor cells and the rate of detection of specimens was analyzed. The clinicopathological characteristics of positive and negative patients with EGFR gene mutation were compared.

Detection of ALK expression by IHC

The remaining tissues from clinicopathological diagnosis were used. Six to eight pieces with the thickness of 3–5 µm were cut from paraffin-embedded tissues. In case of slicing, the slicing knife was disinfected with 75% alcohol between cases so as to prevent cross contamination. A piece of H&E staining section should be cut simultaneously from all specimens so as to judge the content of tissues in tumor cells. The ALK expression of 250 cases of aspiration specimens was detected by Ventana ALK (D5F3) IHC method (11). Moreover, the relationship between the number and ratio of clinical tumor cells and the rate of detection of small specimens was analyzed. The clinicopathological characteristics of positive and negative patients with ALK gene mutation were compared.

Data collection

Two hundred and fifty cases of small biopsy specimen from June 2014 to August 2015 in Zhejiang Cancer Hospital were collected, among them, 50 cases were with fine needle biopsy specimens and 200 cases with coarse needle biopsy specimens under CT-guidance. Of the 50 cases with fine needle biopsy specimens, 29 cases were male and 21 cases were female; aged from 22 to 84 years, with a median age of 63 years, 21 cases were older than 60 years, 29 cases were younger than 60 years. Of the 200 cases with coarse needle biopsy specimens, 127 cases were male and 73 cases were female; aged from 26 to 81 years, with a median age of 59 years, 101 cases were older than 60 years, 99 cases were younger than 60 years.

Statistical analysis

Relationship between detected patients and non-detected patients, ALK-positive/negative with clinical pathological characteristics was analyzed, dichotomous variable adopted the square test, comparison between groups was analyzed by t-test. Continuous variable was tested by Wilcoxon rank-sum test. The above statistical analysis was carried out with SPSS 17.0 (IBM, Armonk, NY, USA), measurement data were expressed by mean ± SD. P<0.05 was considered to indicate a statistically significant difference.

Results

General conditions

CT-guided fine needle aspiration biopsy for all patients achieved success and the length of tumor obtained through aspiration was 0.5–1.5 cm. There were 50 cases applied Cook 19-gauge coaxial biopsy needle or Precisa 20-gauge semi-automatic biopsy needle, and 200 cases applied BioPince 17-gauge automatic biopsy needle or Precisa 18- and 16-gauge semi-automatic biopsy needles. Complications after aspiration: Pneumothorax at different levels was found in 16 cases of coarse needle aspiration (8%, 16/200), among which the degree of pneumothorax of 6 cases (3%, 6/200) >20% of single lung and that was relieved after vacuum sealing drainage. The other cases improved through self-absorption. Thirty-one cases (15.5%, 31/200) had errhysis at different levels in needle passage and lesion area, as well as hemoptysis symptom. They were all relieved after giving medical hemostatic treatment. Among 50 cases of fine needle aspiration, only 2 cases had a small amount of pneumothorax and 3 cases had a little errhysis in needle passage. The absence of complaints after observing for 2–4 h confirmed that no further treatment was needed.

Detection of EGFR gene in CT-guided aspiration biopsy specimen of lung cancer
EGFR gene mutation in lung cancer aspiration biopsy detected by ARMS method

Among 250 cases of small biopsy specimens of lung cancer, a total of 103 cases were detected to have EGFR gene mutation, with the mutation rate of 41.2%, among which single-site mutation accounted for 93.2% and double-site mutation accounted for 6.8%. The most common mutation included exon 19 deletion and exon 21 L858R mutation and mutation was rare in the others (Table I).

Table I.

EGFR gene mutation in 250 cases of lung cancer aspiration biopsy by ARMS method (cases).

Table I.

EGFR gene mutation in 250 cases of lung cancer aspiration biopsy by ARMS method (cases).

PositionMutation typeCases (n)Percentage to all mutations (%)
Exon 19Deletion4644.7
Exon 21L858R mutation4139.8
Exon 21L861Q mutation32.9
Exon 18G719X mutation32.9
Exon 20T790M mutation32.9
Double19 deletion/L858R43.9
mutationmutation
DoubleG719X/L858R32.9
mutationmutation
Total 10341.2

[i] EGFR, epidermal growth factor receptor; ARMS, amplification refractory mutation system.

Relationship between EGFR gene mutation and clinical pathological characteristics

The results of detection of the mutation of EGFR gene for 250 cases of NSCLC showed that the rate of EGFR gene mutation in female patients (62.1%, 64/94) was significantly higher (P<0.01) than that of male patients (37.9%, 39/156). The rate of the mutation of EGFR gene in non-smoking patients (56.2%, 73/130) was significantly higher (P<0.01) than that of smoking patients (25%, 30/120). There were no differences in the rates of gene mutation at the age of 60 years or above. In histological types, there were 94 cases of patients with EGFR detected with mutation of 166 cases of lung adenocarcinoma, accounting for 56.6%. There were 3 cases of patients with EGFR mutation in 59 cases of squamous cell carcinoma, accounting for 5.1%. There were 3 cases of patients with EGFR mutation in 10 cases of squamous carcinoma. EGFR gene mutation (3/15) was detected in other types of lung cancer and the rate of EGFR gene mutation in patients with adenocarcinoma was significantly higher than that of squamous carcinoma and other types of lung cancer (P<0.01) (Table II).

Table II.

Relationship between EGFR gene mutation and clinical pathological characteristics (cases).

Table II.

Relationship between EGFR gene mutation and clinical pathological characteristics (cases).

Clinical characteristicsWith EGFR mutationWithout EGFR mutation
Gender
  Male39117
  Female6430
Age (years)
  ≥605171
  <605276
Smoking history
  Yes3090
  No7357
Phase
  I–III7499
  IV2948
Histological type
  Adenocarcinoma9472
  Squamous carcinoma356
  Adenosquamous carcinoma37
Others312

[i] EGFR, epidermal growth factor receptor.

Comparison of the rate of detection and positive rate of EGFR gene by percutaneous coarse/fine needle aspiration biopsy

The detection of the mutation of EGFR gene was conducted for 250 cases of NSCLC lung cancer with the rate of detection of 83.2% (208/250) and the positive rate of 41.2%, (103/250). Appropriate aspiration needle was selected according to mass location and size. Among 250 cases of patients, 200 cases were conducted with CT-guided coarse needle aspiration and 50 cases with fine needle aspiration. The results of the rate of detection showed that the rate of detection of CT-guided coarse needle biopsy aspiration (91%, 182/200) was significantly (P<0.01) higher than that of fine needle (52%, 26/50). The positive rate (45.5%, 91/200) was significantly higher (P<0.01) than that of fine needle (24%, 12/50) (Tables III and IV).

Table III.

Comparison of rate of detection of EGFR by percutaneous coarse/fine needle aspiration biopsy (cases).

Table III.

Comparison of rate of detection of EGFR by percutaneous coarse/fine needle aspiration biopsy (cases).

Aspiration needleCasesDetectedNot detectedPercentageP-value
Coarse needle2001821891.0
Fine needle50262452.0 <0.001a
Total2502084283.2

a P<0.01, the differences were statistically significant. EGFR, epidermal growth factor receptor.

Table IV.

Comparison of EGFR positive rate by percutaneous coarse/fine needle aspiration biopsy (cases).

Table IV.

Comparison of EGFR positive rate by percutaneous coarse/fine needle aspiration biopsy (cases).

Aspiration needleCasesPositiveNegativePercentageP-value
Coarse needle2009110945.5
Fine needle50123824.00.006a
Total25010314741.2

a P<0.01, the differences were statistically significant. EGFR, epidermal growth factor receptor.

Relationship between the number and ratio of tumor cells and the rate of detection of EGFR

The detection of the mutation of EGFR gene was conducted for 250 cases of NSCLC (with the rate of detection of 83.2%, 208/250). CT-guided coarse needle aspiration was conducted for 200 cases of patients with NSCLC. The results showed that the number of tumor cells of specimen was 51.67±25.43. There were 138 cases with the number of tumor cells of ≥50 and there were 195 cases with the ratio of tumor cells of ≥10%. Among 50 cases of patients conducted with fine needle aspiration, the number of tumor cells of specimen was 37.65±18.14. There were 33 cases with the number of tumor cells of ≥50 and there were 48 cases with the ratio of tumor cells of ≥10%. The results of the rate of detection of EGFR gene showed that the rate of detection of CT-guided coarse needle biopsy aspiration was higher (P<0.05) than that of fine needle. This was relevant to that of the number of tumor cells by coarse needle aspiration, which was more than that of tumor cells by fine needle aspiration (P<0.05), while it was irrelevant to the non-significant ratio of tumor cells of coarse and fine needles (Table V).

Table V.

Relationship between the number and ratio of tumor cells and the rate of detection of EGFR of small specimens (cases).

Table V.

Relationship between the number and ratio of tumor cells and the rate of detection of EGFR of small specimens (cases).

Aspiration needleCasesNo. of tumor cells (mean ± SD)No. of tumor cells (≥50)Ratio of tumor cells (≥10%)Rate of detection (%)
Coarse needle20051.67±25.4313819591.0
Fine needle50 37.65±18.14a21b48c52.0

a P<0.01

b P<0.05, the differences were statistically significant.

c P>0.05, the differences were not statistically significant. EGFR, epidermal growth factor receptor.

Detection of ALK gene in CT-guided aspiration biopsy specimen of lung cancer
ALK gene mutation in lung cancer aspiration biopsy detected by IHC method

Among 250 cases of small biopsy specimens of lung cancer, a total of 15 cases were detected to have ALK gene mutation, with the mutation rate of 6%, the ALK gene expression rate of Chinese patients with lung adenocarcinoma was 8.0%, and the rate of detection of patients with the number of tumor cells of more than 100 was higher (P<0.001).

Relationship between ALK gene mutation and clinicopathological characteristics

In our study, the correlation between ALK gene expression and age and pathological differentiation degree, was not found. Fifteen cases of patients with positive ALK gene were all non-smokers and patients with adenocarcinoma. ALK gene mutation of phase IV patients (18.5%, 12/65) was higher (P<0.05) than that of non-phase IV patients (1.8%, 3/170) (Table VI).

Table VI.

Relationship between ALK gene mutation and clinical pathological characteristics (cases).

Table VI.

Relationship between ALK gene mutation and clinical pathological characteristics (cases).

Clinical characteristicsWith ALK mutationWithout ALK mutationP-value
Gender
  Male61500.065b
  Female985
Age (years)
  ≥6061160.482b
  <609119
Smoking history
  Yes15105 <0.001a
  No0130
Phase
  I–III3170 <0.001a
  IV1265
Histological type
  Adenocarcinoma15151 <0.001a
  Squamous carcinoma059
  Adenosquamous010
  carcinoma
Other015
Pathological differentiation degree
  Poorly61120.824b
  Moderately450
  Well573

a P<0.01, the differences were statistically significant.

b P>0.05, the differences were not statistically significant. ALK, anaplastic lymphoma kinase.

Comparison of the rate of detection and positive rate of ALK gene by percutaneous coarse/fine needle aspiration biopsy

ALK IHC detection was conducted for 250 cases of NSCLC (with the rate of detection of 87.2%, 218/250; the positive rate of 6%, 15/250). The results of detection showed that the rate of ALK CT-guided coarse needle biopsy aspiration (91%, 182/200) was very significantly higher (P<0.01) than that of fine needle (72%, 36/50). The rate of positive ALK (6.5%, 13/200) was consistent with that of fine needle (4%, 2/50) and the differences were not statistically significant (P>0.05) (Tables VII and VIII).

Table VII.

Comparison of the rate of detection of ALK by percutaneous coarse/fine needle aspiration biopsy (cases).

Table VII.

Comparison of the rate of detection of ALK by percutaneous coarse/fine needle aspiration biopsy (cases).

Aspiration needleCasesDetectedNot detectedPercentageP-value
Coarse needle2001821891.0
Fine needle50361472.0 <0.001a
Total2502183287.2

a P<0.01, the differences were statistically significant. ALK, anaplastic lymphoma kinase.

Table VIII.

Comparison of ALK positive rate by percutaneous coarse/fine needle aspiration biopsy (cases).

Table VIII.

Comparison of ALK positive rate by percutaneous coarse/fine needle aspiration biopsy (cases).

Aspiration needleCasesPositiveNegativePercentageP-value
Coarse needle200131876.5
Fine needle502484.00.742a
Total250152356.0

a P>0.05, the differences were not statistically significant. ALK. anaplastic lymphoma kinase.

Relationship between the number and ratio of tumor cells and the rate of detection of EGFR

The detection of ALK gene mutation was conducted for 250 cases of NSCLC (with the rate of detection of 87.2%, 218/250). CT-guided coarse needle aspiration was conducted for 200 cases of patients with NSCLC. The results showed that the number of tumor cells of specimen was 51.67±25.43. There were 138 cases with the number of tumor cells of ≥50, and there were 195 cases with the ratio of tumor cells of ≥10%. Among 50 cases of patients conducted with fine needle aspiration, the number of tumor cells of specimen was 37.65±18.14, there were 33 cases with the number of tumor cells of ≥50, and there were 48 cases with the ratio of tumor cells of ≥10%. The results on the rate of detection of ALK gene showed that the rate of detection of CT-guided coarse needle biopsy aspiration was higher than that of fine needle (P<0.01), which was relevant to the number of tumor cells by coarse needle aspiration was more than that of tumor cells by fine needle aspiration (P>0.05), while it was irrelevant for the ratio of tumor cells of coarse and fine needles (P>0.05, the differences were not statistically significant) (Table IX).

Table IX.

Relationship between the number and ratio of tumor cells and the rate of detection of EGFR.

Table IX.

Relationship between the number and ratio of tumor cells and the rate of detection of EGFR.

Aspiration needleCasesNo. of tumor cells (mean ± SD)No. of tumor cells (≥50)Ratio of tumor cells (≥10%)Rate of detection (%)
Coarse needle20051.67±25.4313819591
Fine needle50 37.65±18.14a21b48c72

a P<0.01

b P<0.05, the differences were statistically significant.

c P>0.05, the differences were not statistically significant. EGFR, epidermal growth factor receptor.

Discussion

By virtue of the advantages, including minimally invasive, easy and simple to handle and less complications, CT-guided percutaneous lung aspiration biopsy has been widely used in clinic (22). Many clinical patients with advanced NSCLC have lost the opportunity of surgical therapy and lung aspiration biopsy is an important means to specify diagnosis (23). The implementation of molecular detection can also further specify the type of gene mutation so as to guide the next step of treatment. Compared with surgical specimens, the number and ratio of tumor cells contained in aspiration biopsy specimens were lower (24). The improvement of the rate of detection of clinical aspiration will be helpful in clinical diagnosis and treatment.

In our study, CT-guided aspiration biopsy for 250 cases of NSCLC patients achieved success and the length of tumor obtained through aspiration was 0.5–1.5 cm. There were 50 cases applied Cook 19-gauge coaxial biopsy needle or Precisa 20-gauge semi-automatic biopsy needle, and 200 cases applied BioPince 17-gauge automatic biopsy needle. Complications of fine needle after aspiration were significantly less. Among 50 cases of patients, only 3 cases had pneumothorax and 2 cases had slight errhysis in needle passage. The present study showed that the safety of CT-guided fine needle aspiration biopsy was higher than that of coarse needle aspiration biopsy, with much less clinical complications after aspiration. Under the premise of ensuring the rate of detection of certain gene, the utilization of fine needle aspiration biopsy for specimens applicable to fine needle aspiration could not only reach the target of gene detection, but also reduce clinical complications.

Among 250 cases of biopsy specimens of lung cancer, a total of 103 cases were detected to have EGFR gene mutation, with the mutation rate of 41.2%, among which exon 19 deletion (44.7%) and exon 21 L858R mutation (39.8%) were common. Among 250 cases of specimens, a total of 15 cases (6%) of ALK fusion gene were detected. There were great differences in the rate of EGFR mutation among different races. EGFR mutation rate of Asians was ~30%, which was considerably higher than that of Caucasians, 10%. The rate of EGFR mutation in Chinese population was also relatively higher (25). Studies reported that the expression rate of EML4/ALK in unselected NSCLC patients was <7%, without obvious racial differences (26). Therefore, the rates of EGFR and ALK gene mutation were both in normal range, which had no significant differences with the studies of other scholars.

The detection of the results of EGFR gene mutation showed that the rate of mutation of female patients was significantly higher than that of male patients (62.1 and 37.9%, P<0.01). The rate of mutation of non-smoking patients was significantly higher than that of smoking patients (56.2 and 25%, P<0.01). However, age and staging showed no correlation with gene mutation, which was consist with that in most studies (27). In histological types, the rate of EGFR gene mutation in adenocarcinoma (56.6%, P<0.01) was significantly higher than that of squamous carcinoma and other types of lung cancer. Although squamous carcinoma and other types of lung cancer had a lower ratio of EGFR gene mutation, some patients with mutation had their prognosis improved significantly. Therefore, gene detection should also be conducted for patients without adenocarcinoma. In this study, the correlation between the expression of ALK gene and factors including, gender, age and pathological differentiation degree was not found (P>0.05). Fifteen cases of patients with positive ALK gene were all non-smokers and patients with adenocarcinoma, which was identical to the reports of others (28). Clinical study showed that ALK positive patients, as particular subtype of lung cancer, were characterized by adenocarcinoma, non-smoking, female and younger patients. The expression of ALK gene was also related to some histopathological characteristics, such as dominated by alveolar type, poorly differentiated and positive expression of TTF-1 (29). In our study, the correlation between ALK gene expression and factors, including gender, age and pathological differentiation degree, was not found, which was considered to be mainly related to less patients with positive expression of ALK. We found that the mutation of ALK gene of phase IV patients was significantly higher than that of non-phase IV patients (18.5 and 1.8%, P<0.01), which may be because patients in advanced stage could not be operated on, and needed to specify pathology through aspiration biopsy.

The main objective of this study was to assess factors related to improving the rate of detections of EGFR and ALK gene mutations. The results showed that the rate of detection of EGFR gene was 83.2% (208/250). The rate of detection of coarse needle biopsy aspiration was higher than that of fine needle (91 and 52%, P<0.01) and the positive rate of coarse needle biopsy aspiration was also higher than that of fine needle (45.5 and 24%, P<0.01). The high rate of detection of coarse needle aspiration was related to that the number of tumor cells by coarse needle aspiration was more than that of tumor cells by fine needle aspiration (P<0.05), while it was irrelevant to the ratio of tumor cells of coarse and fine needles (P>0.05). The rate of detection of patients with the number of tumor cells of more than 100 was high. The rate of detection of ALK IHC was 87.2%. The rate of detection of coarse needle biopsy aspiration was higher than that of fine needle (91 and 72%, P<0.01), but there were no differences in positive rate (P>0.05). The rate of detection of coarse needle biopsy aspiration was related to the differences in the number of tumor cells of coarse and fine needle aspiration (P<0.05) and was not related to the ratio of tumor cells of coarse and fine needle aspiration (P>0.05). Therefore, whether EGFR gene or ALK gene, the main factor that affects the rate of detection is the number of tumor cells. The rate of detection increases with increasing number of tumor cells. Moreover, the more the cases with the number of tumor cells of ≥50 are, the higher the rate of detection is. Whether the ratio of tumor cells was ≥10% had no effects on the rate of detection (P>0.05) and most specimens complied with the ratio of tumor cells of ≥10%. Therefore, the main factor that affected the rate of detection was still the number of tumor cells, which was consistent with other studies (28,29).

Therefore, in case of conducting CT-guided aspiration biopsy gene detection in clinical practical application, it is required to adjust direction with lesion and conduct aspiration at multiple points so as to obtain sufficient specimens and improve the number of tumor cells, thus to increase the success rate of gene detection.

In conclusion, in 250 specimens, the EGFR gene mutation rate was 41.2% and ALK fusion gene was detected in a total of 15 cases (6%). The rate of detections of EGFR gene and ALK gene were 83.2 and 87.2%, respectively. Their rate of detections of coarse biopsy aspiration were higher than those of fine needle, but the rate of detection of fine needle was not low. For patients with only indications of fine needle aspiration, the implementation of cell wax block through fine needle aspiration was still the best choice. Gene rate of detection was related to the number of tumor cells and was not related to the ratio of tumor cells. The rate of detection of patients with the number of tumor cells ≥50 was higher. Therefore, in clinical practical application, in case of conducting CT-guided aspiration biopsy, especial cell wax block embedding by fine needle aspiration biopsy, it is required to adjust direction with lesion and conduct aspiration at multiple points so as to obtain sufficient specimens and improve the number of tumor cells, thus to increase the success rate of gene detection.

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Volume 13 Issue 5

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Lian W and Lian W: CT-guided aspiration lung biopsy for EGFR and ALK gene mutation analysis of lung cancer. Oncol Lett 13: 3415-3422, 2017
APA
Lian, W., & Lian, W. (2017). CT-guided aspiration lung biopsy for EGFR and ALK gene mutation analysis of lung cancer. Oncology Letters, 13, 3415-3422. https://doi.org/10.3892/ol.2017.5921
MLA
Lian, W., Ouyang, Y."CT-guided aspiration lung biopsy for EGFR and ALK gene mutation analysis of lung cancer". Oncology Letters 13.5 (2017): 3415-3422.
Chicago
Lian, W., Ouyang, Y."CT-guided aspiration lung biopsy for EGFR and ALK gene mutation analysis of lung cancer". Oncology Letters 13, no. 5 (2017): 3415-3422. https://doi.org/10.3892/ol.2017.5921