Analysis of dosimetric characteristics of proton radiotherapy in 3 cases of lung cancer

doi:10.3760/cma.j.cn371439-20250217-00112

Abstract

Abstract:

Objective To investigate the dosimetric characteristics of intensity modulated proton therapy （IMPT） and intensity modulated radiation therapy （IMRT） for lung cancers. Methods Three lung cancer patients （central-lower， central， and peripheral types） admitted to Shandong Cancer Hospital and Institute from January 2024 to May 2024 were selected as the research subjects. IMPT and IMRT plans were designed for each case based on the anatomical location of the clinical target volume and the dose constraints for organs at risk （OARs）. Dosimetric parameters， including conformity index （CI）， homogeneity index （HI）， and gradient index （GI） for target coverage， as well as OARs dosimetric parameters were evaluated. The volume of additional dose deposition in the body was compared by assessing regions receiving 10%， 30%， and 50% of the prescription dose. Results For all three cases， IMRT plans demonstrated higher CI values （0.80， 0.60， and 0.79） compared to IMPT plans （0.61， 0.57， and 0.34）. IMPT plans yielded lower HI values （0.07， 0.06， and 0.06） than IMRT plans （0.09， 0.15， and 0.09） and lower GI values （2.84， 2.47， and 4.56 vs. 4.91， 3.09， and 4.99 for IMRT plans）. Compared with the IMRT plans， the low-dose region in the ipsilateral lung was significantly reduced in IMPT plans （V₅ of the IMPT plans were 20.59%， 46.29%， 10.94%， respectively； V₅ of the IMRT plans were 48.91%， 60.63%， 19.92%， respectively）， but there was no significant advantage in the high-dose region compared to IMRT plans （V₂₀ of the IMPT plans were 12.88%， 34.75%， 5.21%， respectively；V₂₀ of the IMRT plans were 21.70%， 36.50%， 5.31%， respectively）. The dose to the contralateral lung and heart was significantly reduced in IMPT plans [the D_mean of the contralateral lung in the IMPT plans were 0.08， 0.04， and 0.00 Gy （RBE）， respectively， and those in the IMRT plans were 3.25， 1.18， and 0.55 Gy， respectively； the heart D_mean in the IMPT plans were 6.23， 7.04， and 0.00 Gy （RBE）， respectively， while those of the IMRT plans were 18.33， 10.27， and 0.08 Gy， respectively）. IMPT plans significantly reduced the volumes receiving 10% of the prescription dose by 65.94%， 25.57% and 72.47%， respectively， compared to IMRT plans. The volumes IMPT plans occupied by 30% of the prescription dose area in the body were reduced by 54.97%， 26.47% and 39.04%， respectively， compared to the IMRT plans. The volumes IMPT plans occupied by 50% of the prescription dose area in the body were reduced by 54.49%， 30.43% and 28.89%， respectively， compared to the IMRT plans. Conclusions IMPT plan significantly reduces the V₅ of the ipsilateral lung， the D_mean of the contralateral lung and the heart， while maintaining target coverage compared with IMRT plan for lung cancers. However， IMPT plan does not show much more advantage than IMRT plan in the ipsilateral lung V₂₀. IMPT can reduce the additional exposure volume within the body.

Key words: Lung neoplasms, Radiotherapy, Proton therapy, Radiotherapy dosage

Tao Cheng, Fan Bingjie, Li Chengqiang, Wu Shizhang, Duan Jinghao, Dai Tianyuan, Bai Tong, Chen Jinhu, Zhu Jian. Analysis of dosimetric characteristics of proton radiotherapy in 3 cases of lung cancer[J]. Journal of International Oncology, 2025, 52(10): 653-658.

Figures/Tables 5

References 11

[1]	Nichols RC Jr, Henderson RH, Huh S, et al. Proton therapy for lung cancer[J]. Thorac Cancer, 2012, 3: 109-116. DOI: 10.1111/j.1759-7714.2011.00098.x.
[2]	Amstutz F, Fabiano S, Marc L, et al. Combined proton-photon therapy for non-small cell lung cancer[J]. Med Phys, 2022, 49(8): 5374-5386. DOI: 10.1002/mp.15715. pmid: 35561077
[3]	Cortiula F, Hendriks LEL, Wijsman R, et al. Proton and photon radiotherapy in stage Ⅲ NSCLC: effects on hematological toxicity and adjuvant immune therapy[J]. Radiother Oncol, 2024, 190: 110019. DOI: 10.1016/j.radonc.2023.110019.
[4]	Paganetti H. Range uncertainties in proton therapy and the role of monte carlo simulations[J]. Phys Med Biol, 2012, 57(11): R99-R117. DOI: 10.1088/0031-9155/57/11/R99.
[5]	Taasti VT, Hattu D, Vaassen F, et al. Treatment planning and 4D robust evaluation strategy for proton therapy of lung tumors with large motion amplitude[J]. Med Phys, 2021, 48(8): 4425-4437. DOI: 10.1002/mp.15067. pmid: 34214201
[6]	Tominaga Y, Suga M, Takeda M, et al. Comparing interplay effects in scanned proton therapy of lung cancer: free breathing with various layer and volume rescanning versus respiratory gating with different gate widths[J]. Phys Med, 2024, 120: 103323. DOI: 10.1016/j.ejmp.2024.103323.
[7]	Zenklusen SM, Pedroni E, Meer D. A study on repainting strategies for treating moderately moving targets with proton pencil beam scanning at the new gantry 2 at PSI[J]. Phys Med Biol, 2010, 55(17): 5103-5121. DOI: 10.1088/0031-9155/55/17/014. pmid: 20702927
[8]	Li X, Liu G, Janssens G, et al. The first prototype of spot-scanning proton arc treatment delivery[J]. Radiother Oncol, 2019, 137: 130-136. DOI: 10.1016/j.radonc.2019.04.032. pmid: 31100606
[9]	Liu P, Zhao L, Liu G, et al. The first investigation of the dosimetric perturbations from the spot position errors in spot-scanning arc therapy (SPArc)[J]. Phys Med Biol, 2024, 69(13): 135012. DOI: 10.1088/1361-6560/ad5827.
[10]	于新生, 任磊, 卢晓光. 现代质子放疗和光子放疗的争论与思考[J]. 国际肿瘤学杂志, 2024, 51(7): 411-416. DOI: 10.3760/cma.j.cn371439-20240619-00068.
[11]	孔琳, 陆嘉德. 突破与挑战: 恶性肿瘤质子重离子放疗的临床应用与进展[J]. 国际肿瘤学杂志, 2024, 51(7): 417-423. DOI: 10.3760/cma.j.cn371439-20240621-00069.

序号	年龄（岁）	性别	靶区位置	处方剂量	危及器官限制标准
1	66	男	右侧中央偏下型	IMRT：60 Gy/30 f；IMPT：60 Gy（RBE）/30 f	患侧肺（V₅<65%，V₂₀<35%），健侧肺（V₅<65%，V₂₀<35%），心脏（V₃₀<40%，V₄₀<30%，D_max<26 Gy），脊髓D_max<45 Gy
2	71	男	左侧中央型	IMRT：60 Gy/30 f；IMPT：60 Gy（RBE）/30 f	患侧肺（V₅<65%，V₂₀<35%），健侧肺（V₅<65%，V₂₀<35%），心脏（V₃₀<40%，V₄₀<30%，D_max<26 Gy），脊髓D_max<45 Gy
3	74	男	左侧周围型	IMRT：50 Gy/10 f；IMPT：50 Gy（RBE）/10 f	患侧肺（V₅<65%，V₂₀<35%），健侧肺（V₅<65%，V₂₀<35%），心脏（V₃₀<40%，V₄₀<30%，D_max<26 Gy），脊髓D_max<45 Gy

剂量学指标	病例1（右侧中央偏下型）		病例2（左侧中央型）		病例3（左侧周围型）
剂量学指标	IMPT	IMRT	IMPT	IMRT	IMPT	IMRT
靶区
CI	0.61	0.80	0.57	0.60	0.34	0.79
HI	0.07	0.09	0.06	0.15	0.06	0.09
GI	2.84	4.91	2.47	3.09	4.56	4.99
肺（左）
V₅（%）	0.24	19.19	46.29	60.63	10.94	19.92
V₁₀（%）	0.00	8.23	42.12	46.24	8.54	12.20
V₂₀（%）	0.00	2.68	34.75	36.50	5.21	5.31
D_mean[Gy（RBE）/Gy]	0.08	3.25	19.42	21.82	2.60	3.91
肺（右）
V₅（%）	20.59	48.91	0.22	2.23	0.00	1.29
V₁₀（%）	17.32	37.52	0.12	0.92	0.00	0.00
V₂₀（%）	12.88	21.70	0.03	0.32	0.00	0.00
D_mean[Gy（RBE）/Gy]	6.57	12.61	0.04	1.18	0.00	0.55
心脏
V₃₀（%）	8.33	22.16	10.87	13.98	0.00	0.00
V₄₀（%）	5.66	13.98	8.92	12.40	0.00	0.00
D_mean[Gy（RBE）/Gy]	6.23	18.33	7.04	10.27	0.00	0.08
脊髓
D_max[Gy（RBE）/Gy]	25.60	41.99	31.95	45.98	0.00	7.04
body（cm³）
10%D_处方剂量	1 226	3 600	1 761	2 366	305	1 108
30%D_处方剂量	870	1 932	1 297	1 764	153	251
50%D_处方剂量	491	1 079	960	1 380	64	90

[1]	Wu Songyou, Wang Gang, Wang Wenling, Dong Hongmin, Chen Weiwei, Li Xiaokai, Chen Wanghua, Zuo Kai. Prospective cohort study on the effect of abdominal circumference on the intestinal radiation dose volume and the acute intestinal toxicity in pelvic intensity modulated radiation therapy for rectal cancer patients [J]. Journal of International Oncology, 2025, 52(9): 566-575.
[2]	Radiation Oncology Professional Committee of the Chinese Research Hospital Association, Hebei Society of Mathematical and Physical Medicine, Tianjin Precision Medicine Society. Expert consensus on the clinical diagnosis and treatment of post-obstructive pneumonia in newly diagnosed lung cancer patients [J]. Journal of International Oncology, 2025, 52(8): 484-494.
[3]	Liu Qi, Qu Guobin, Zhu Jian, Wu Fan. Feasibility study of using dual-energy CT virtual non-contrast images to replace true non-contrast images in photon and proton radiotherapy dose calculations [J]. Journal of International Oncology, 2025, 52(7): 401-408.
[4]	Li Xiaoxuan, Xia Zhipeng, Luan Rumei, Wan Yunyan, Yao Zhouhong, Lin Xinshan, Lin Dianjie. Clinical value of metabolomics in assessing the malignant risk of pulmonary nodules [J]. Journal of International Oncology, 2025, 52(7): 409-413.
[5]	Zhu Jian. Preface to the dosimetric characteristic of proton radiotherapy for tumors [J]. Journal of International Oncology, 2025, 52(7): 432-433.
[6]	Wu Shizhang, Hu Man, Dai Tianyuan, Li Chengqiang, Tao Cheng, Duan Jinghao, Chen Jinhu, Bai Tong, Kong Tian, Zhu Jian. Analysis of dosimetric characteristics of proton radiotherapy in 1 case of whole central nervous system tumor [J]. Journal of International Oncology, 2025, 52(7): 434-440.
[7]	Xu Jian, Duan Jinghao, Liu Qingzeng, Zhu Jian. Correlation study of spectral CT parameters and MRI ADC changes in proton radiotherapy for chordoma [J]. Journal of International Oncology, 2025, 52(7): 441-447.
[8]	Li Chengqiang, Wang Yungang, Yu Yishan, Wu Shizhang, Tao Cheng, Ma Xingmin, Dai Tianyuan, Duan Jinghao, Chen Jinhu, Bai Tong, Zhu Jian. Analysis of dosimetric characteristics of proton radiotherapy in 4 cases of breast cancer [J]. Journal of International Oncology, 2025, 52(7): 448-454.
[9]	Duan Jinghao, Yue Jinbo, Tao Cheng, Wu Shizhang, Li Chengqiang, Dai Tianyuan, Chen Jinhu, Bai Tong, Zhu Jian. Analysis of dosimetric characteristics of proton radiotherapy in 3 cases of abdominal and pelvic tumors [J]. Journal of International Oncology, 2025, 52(7): 455-461.
[10]	Zhong Xiao, Li Butuo, Wang Linlin. Research progress of radiotherapy for brain metastases from ALK-positive NSCLC [J]. Journal of International Oncology, 2025, 52(6): 374-378.
[11]	Lyu Xiaoyan, Wang Yuan, Wang Jun. Advances in precision radiotherapy for esophageal squamous cell carcinoma [J]. Journal of International Oncology, 2025, 52(5): 268-272.
[12]	Liu Qianyi, Dong Hongmin, Wang Wenling, Wang Gang, Chen Wanghua. Clinical efficacy and safety of radiotherapy combined with chemotherapy and immunotherapy for HER2-negative locally advanced or advanced gastric cancer [J]. Journal of International Oncology, 2025, 52(4): 209-216.
[13]	Wen Yingmei, Xia Jinxiong, Wang Yuanyuan, Yao Yi. Impacts of radiotherapy on anti-tumor immunity：a comprehensive review from the fundamental to the clinical [J]. Journal of International Oncology, 2025, 52(4): 231-236.
[14]	Lu Bing, Xiong Siyu, Jiang Wenhong, Yu Tingting. Progress in the study of fructose-bisphosphate aldolase A in lung cancer [J]. Journal of International Oncology, 2025, 52(4): 242-245.
[15]	Chen Danlei, Deng Junjun, Li Miao. Progress of clinical application of circulating tumor cells in lung cancer [J]. Journal of International Oncology, 2025, 52(2): 119-123.