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Radiotherapy plays an important role in non-small cell lung cancer (NSCLC), and concurrent chemoradiation is considered to be the standard treatment for locally advanced NSCLC. However, due to the patient's physical condition, comorbidities and other reasons, only about 1/3 of patients can receive concurrent chemoradiation. Radiotherapy alone or sequential chemoradiation has become the treatment protocol for most patients. Hypofractionated radiotherapy can be used in NSCLC because it can shorten the over treatment time and may potentially reduce the effect of accelerated repopulation and obtain higher biological effective dose(BED). So far, the vast majority of radiotherapy prescriptions have given a uniform dose of 60 Gy. This unified prescription dosage approach is completely inconsistent with the concept of precision treatment. The Netherlands MAASTRO put forward the concept of in silico radiotherapy prescription, that is: the normal tissue limits are uniform, such as: V20% ≤ 30%, spinal cord V0> 45Gy, etc., and each patient receives a different dose of radiation therapy. This radiation prescription could reach the limits of the normal tissue of every patient; if no one tissue limits were reached, the highest dose was set up to 79.2 Gy (1.8 Gy, BID). MAASTRO applied this "iso-toxic" radiotherapy prescription and used accelerated hyperfractionation technology so that each patient received the maximum individualized radiation dose as possible. We will integrate this concept with hypofractionated radiotherapy in order to further improve efficacy.
Radiotherapy plays an important role in non-small cell lung cancer (NSCLC), and concurrent chemoradiation is considered to be the standard treatment for locally advanced NSCLC. However, due to the patient's physical condition, comorbidities and other reasons, only about 1/3 of patients can receive concurrent chemoradiation. Radiotherapy alone or sequential chemoradiation has become the treatment protocol for most patients. Hypofractionated radiotherapy can be used in NSCLC because it can shorten the total treatment time and may potentially reduce the effect of accelerated repopulation and obtain higher BED. So far, the vast majority of radiotherapy prescriptions have given a uniform dose of radiotherapy to all patients, regardless of individual factors such as tumor size, location, and adjacent vital organs, which may cause two consequences: First, small-volume tumors may, not receive enough radiation dose, resulting in a decrease in local control rate. Second, for large volumes of tumors or tumors adjacent to vital organs, even the "so-called" standard dose (60 Gy) may cause serious damage to normal tissues. This unified prescription dosage approach is completely inconsistent with the concept of precision treatment. The Netherlands MAASTRO put forward the concept of in silico radiotherapy prescription, that is: the normal tissue limits are uniform, such as: V20% ≤ 30%, spinal cord V0> 45Gy, etc., and each patient receives a different dose of radiation therapy.This radiation prescription could reach the limits of the normal tissue of every patient; if no one tissue limits were reached, the highest dose was set up to 79.2 Gy (1.8 Gy, BID). MAASTRO applied this "iso-toxic" radiotherapy prescription and used accelerated hyperfractionation technology so that each patient received the maximum individualized radiation dose as possible.From the model study to the long-term survival results, a series of encouraging results were achieved. The use of an individualized radiotherapy prescription based on iso-toxicity for the treatment of NSCLC in large-segment radiotherapy is expected to achieve: 1. For patients with small tumor volumes and no adjacent to vital organs, a higher radiation dose is given under safe conditions. 2. For patients with larger volumes of tumors or adjacent to vital organs, give safer doses.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| isotoxic hypofractionated group | Experimental | Hypofractionated radiation: 1. Split mode: 3Gy/f. 2,Individualized prescriptions for different patients: (1) Spinal cord: 0%>45 Gy, and ≤2 Gy each time Lung: V20≤30%, V5≤65%, MLD≤16Gy Esophagus: highest dose ≤ 69Gy 3. Maximum limit: If the limit of any "A" is not reached, the maximum radiation dose is 69 Gy. The lowest radiation dose: 45Gy. Chemotherapy: Platinum-containing two-drug regimen: docetaxel + lobaplatin: Docetaxel 60 mg/m2, d1; Lobaplatin 30 mg/m2, d1; repeated every 28 days. The first cycle of chemotherapy started on the first day of radiotherapy. The same chemotherapy regimen is used up to 4 cycles as consolidation after the completion of radiotherapy. |
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| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| isotoxic hypofractionated group | Radiation | the normal tissue limits are uniform, such as: V20% ≤ 30%, spinal cord 0> 45Gy, etc., and used hypofractionated radiotherapy technology so that each patient received the maximum individualized radiation dose as possible,and the same time use the Platinum-containing drugs: docetaxel + lobaplatin Docetaxel 60 mg/m2, d1; Lobaplatin 30 mg/m2, d1, repeated every 28 days. The first cycle of chemotherapy started on the first day of radiotherapy.Consolidate chemotherapy up to 4 cycles after radiotherapy, as above. |
| Measure | Description | Time Frame |
|---|---|---|
| radiation induced esophagitis and radiation induced pneumonitis | Number of participants with treatment-related severe adverse events:Grade IV radiation esophagitis, Grade III radiation esophagitis which results in interruption of radiotherapy for 7 days or more, and Grade III or above radiation pneumonitis | 2 years |
| Measure | Description | Time Frame |
|---|---|---|
| time to disease progression (TTP) | Record the time from the start of enrollment to the objective progression of the tumor | 5 years |
| progression-free survival(PFS) | Record the time from the start of enrollment to the progression of disease or death |
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Inclusion Criteria:
Exclusion Criteria:
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| Name | Role | Phone | Extension | |
|---|---|---|---|---|
| Xiao-Ying Xue, Professor | Contact | +86-158-0321-0636 | xxy0636@163.com |
| Name | Affiliation | Role |
|---|---|---|
| Xiao-Ying Xue, Professor | The Second Hospital of Hebei Medical University | Study Chair |
| Qiang Lin, Professor | North China Petroleum Bureau General Hospital, Hebei Medical University | Study Director |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| The Second Hospital of Hebei Medical University | Recruiting | Shijiazhuang | Hebei | 050000 | China |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 33099491 | Derived | Liu YE, Xue XY, Zhang R, Chen XJ, Ding YX, Liu CX, Qin YL, Li WQ, Ren XC, Lin Q. Study protocol: a multicentre, prospective, phase II trial of isotoxic hypofractionated concurrent chemoradiotherapy for non-small cell lung cancer. BMJ Open. 2020 Oct 23;10(10):e036295. doi: 10.1136/bmjopen-2019-036295. |
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After the publication of this study, we could share the IPD. However, this sharing is limited to academic research.
Person to be contacted: Study Chair: Professor Xiao Ying Xue. Contact information: zyy_lq@petrochina.com.cn
After the publication of this study, we could share the IPD
However, this sharing is limited to academic research. Person to be contacted: Study Chair: Professor Xiao Ying Xue.
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| ID | Term |
|---|---|
| D002289 | Carcinoma, Non-Small-Cell Lung |
| ID | Term |
|---|---|
| D002283 | Carcinoma, Bronchogenic |
| D001984 | Bronchial Neoplasms |
| D008175 | Lung Neoplasms |
| D012142 | Respiratory Tract Neoplasms |
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|
| 5 years |
| overall survival (OS) | Record the time from the start of enrollment to progression or primary tumors | 5 years |
| local control(LC) | record the proportion of no increase in primary tumor | 5 years |
| Chao-Xing Liu, Professor | No.1 Hospital of Shijiazhuang City | Study Director |
| D013899 |
| Thoracic Neoplasms |
| D009371 | Neoplasms by Site |
| D009369 | Neoplasms |
| D008171 | Lung Diseases |
| D012140 | Respiratory Tract Diseases |