Significance of RASSF1A and SHOX2 methylation in bronchoalveolar lavage fluid combined with radial ultrasonic features in differentiating the property of pulmonary nodules

doi:10.3877/cma.j.issn.1674-6902.2024.04.001

Abstract

Abstract:

Objective

To analyse the significance of methylation test of Ras association family 1 isoform A (RASSF1A) and short stature homeobox 2 (SHOX2) in bronchoalveolar lavage fluid(BALF) combined with radial ultrasonic features in the differential diagnosis between malignant and benign pulmonary nodules.

Methods

Ninety patients with pulmonary nodules admitted to our hospital from September 2022 to March 2024 were selected, 54 cases of malignant pulmonary nodules diagnosed by histopathology were in the observation group, and 36 cases of benign pulmonary nodules were in the control group, and BALF was collected for cytological examination and methylation detection of the RASSF1A and SHOX2 genes to compare the methylation positivity rate of the two groups and analyse the sensitivity and specificity of pulmonary nodules. Logistic regression analysis was used to screen some clinical characteristics, radial ultrasonic features and methylation indexes as predictors to construct a prediction model of pulmonary nodules.

Results

In the observation group, 22 cases (40.74%) of RASSF1A positivity were higher than 1 case (2.78%) in the control group(P<0.01); 25 cases (46.30%) of SHOX2 positivity were higher than 2 cases (5.56%) in the control group(P<0.01); 14 cases (25.93%) of both RASSF1A and SHOX2 positivity were higher than 1 case(2.78%) in the control group(P<0.05); 33 cases (61.11%) of RASSF1A or SHOX2 positivity were higher than 2 cases (5.56%) in the control group(P<0.01; The sensitivity for diagnosing malignant lung nodules was 61.11% and the specificity was 94.44% for the positivity of RASSF1A or SHOX2. 33 cases (61.11%) of RASSF1A or SHOX2 positivity were significantly higher than 17 cases(31.48%) of BALF cytology positivity(P<0.05); Radial ultrasound characteristics of the observation group in the ratio of the continuous margins of 81.40%, the ratio of the uneven internal echo of 83.72% and the ratio of hypoechogenic shadows of 72.09% were higher than that of the control group of 40.00%, 40.00%, 45.71% (P<0.05); Multifactorial logistic regression analysis showed that two-gene methylation, continuous margins and uneven internal echo were the risk factors for predicting malignant lung nodules, and the area under the curve (AUC) of the working characteristics of the subjects was 0.886.

Conclusion

RASSF1A combined with SHOX2 methylation detection of BALF is valuable for the diagnosis of malignant lung nodules, and RASSF1A and SHOX2 methylation combined with radial ultrasound features are clinically relevant for the differential diagnosis of the property of lung nodules.

Key words: Pulmonary nodule, Bronchoalveolar lavage fluid, Ras association family 1 isoform A methylation, Short stature homeobox 2 methylation, Radial ultrasound features

Jincheng Liu, Bin Wang, Wen Zhang, Mingzhou Zhang, Yu Liu, Dongfan Ye, Zansheng Huang, Lingxiao Qiu, Bin Qing, Chuangye Wang, Nanbo Wang, Ping Wang, Yuhang Guo, Peihua Zhou, Qiuxia Cheng, Zhi Xu. Significance of RASSF1A and SHOX2 methylation in bronchoalveolar lavage fluid combined with radial ultrasonic features in differentiating the property of pulmonary nodules[J]. Chinese Journal of Lung Diseases(Electronic Edition), 2024, 17(04): 505-511.

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URL: https://zhfbjbzz.cma-cmc.com.cn/EN/10.3877/cma.j.issn.1674-6902.2024.04.001

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Figures/Tables 7

References 30

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甲基化指标		组织病理学		合计(n＝90)	灵敏度	特异性	PPV	NPV
甲基化指标		恶性(n＝54)	良性(n＝36)	合计(n＝90)	灵敏度	特异性	PPV	NPV
RASSF1A	阳性	22	1	23	40.74	97.22	95.65	52.24
	阴性	32	35	67
SHOX2	阳性	25	2	27	46.30	94.44	92.59	53.97
	阴性	29	34	63
RASSF1A及SHOX2	阳性	14	1	15	25.93	97.22	93.33	46.67
	阴性	40	35	75
RASSF1A或SHOX2	阳性	33	2	35	61.11	94.44	94.29	61.82
	阴性	21	34	55

甲基化指标		组织病理学		合计(n＝90)	灵敏度	特异性	PPV	NPV
甲基化指标		恶性(n＝54)	良性(n＝36)	合计(n＝90)	灵敏度	特异性	PPV	NPV
RASSF1A	阳性	22	1	23	40.74	97.22	95.65	52.24
	阴性	32	35	67
SHOX2	阳性	25	2	27	46.30	94.44	92.59	53.97
	阴性	29	34	63
RASSF1A及SHOX2	阳性	14	1	15	25.93	97.22	93.33	46.67
	阴性	40	35	75
RASSF1A或SHOX2	阳性	33	2	35	61.11	94.44	94.29	61.82
	阴性	21	34	55

病理类型	例数	RASSF1A阳性	SHOX2阳性	RASSF1A及SHOX2阳性	RASSF1A或SHOX2阳性
肺腺癌	33	11(33.33)	8(24.24)	3(9.09)	16(48.48)
肺鳞癌	13	4(30.76)	10(76.92)	4(30.76)	10(76.92)
小细胞肺癌	6	6(100.00)	6(100.00)	6(100.00)	6(100.00)
未明确类型	2	1(50.00)	1(50.00)	1(50.00)	1(50.00)
统计量		10.082	18.633	20.756	7.557
P值		0.009	0.000	0.000	0.031

病理类型	例数	RASSF1A阳性	SHOX2阳性	RASSF1A及SHOX2阳性	RASSF1A或SHOX2阳性
肺腺癌	33	11(33.33)	8(24.24)	3(9.09)	16(48.48)
肺鳞癌	13	4(30.76)	10(76.92)	4(30.76)	10(76.92)
小细胞肺癌	6	6(100.00)	6(100.00)	6(100.00)	6(100.00)
未明确类型	2	1(50.00)	1(50.00)	1(50.00)	1(50.00)
统计量		10.082	18.633	20.756	7.557
P值		0.009	0.000	0.000	0.031

临床分期	例数	RASSF1A阳性	SHOX2阳性	RASSF1A及SHOX2阳性	RASSF1A或SHOX2阳性
Ⅰ＋Ⅱ	26	8(30.80)	11(42.30)	6(23.10)	13(50.00)
Ⅲ＋Ⅳ	24	10(41.70)	11(45.80)	5(20.80)	16(66.70)
未明确分期	4	4(100.00)	3(75.00)	3(75.00)	4(100.00)
Fisher确切法		6.414	1.440	4.626	3.804
P值		0.039	0.596	0.099	0.130

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