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Brief Title: The Effect of Bone Marrow-sparing Intensity-Modulated Radiotherapy to GI Cancer
Official Title: Phase II Clinical Trial: The Effect of Bone Marrow-sparing Intensity-Modulated Radiotherapy (BMS-IMRT) on Reduction Acute Hematologic Toxicity in Gastric and Rectal Cancer Patients Treated With Concurrent Chemotherapy and IMRT
Study ID: NCT01863420
Brief Summary: Concurrent chemotherapy with external beam radiotherapy is the standard treatment of bulky or locally advanced cervical cancer, gastric cancer and rectal cancer.Despite excellent therapeutic results, acute hematologic toxicity (HT) is common with this regimen. Previous studies have founded acute HT was significantly associated the volume of pelvic (PBM) and lumbosacral bone marrow (LSBM) receiving 10 and 20 Gy radiation (RT). Therefore, reducing the volume of BM receiving low-dose RT might prevent HT. More than one-half of the body's bone marrow (BM) is located in the PBM, LSBM and proximal, where is just in the low dose of RT in patients with gastric, rectal and cervical cancer. Previous study have demonstrated highly conformal IMRT treatment plans reduced the volume of PBM irradiated resulting in less HT. We have since assumed that even better BM sparing is possible when the BM is entered as a separate constraint in the planning process. However, it is well known that hematopoietically active (red) BM is poorly visualized with computed tomography (CT). Consequently, the entire contents of the medullary canals must be entered as BM. Yet, a considerable portion of the medullary canal is comprised of inactive (yellow) marrow, which is composed primarily of fat. Contouring the entire medullary canals on CT thus overestimates the volume of active BM, unnecessarily constraining the IMRT plan. An alternative approach is the incorporation of functional BM imaging into the treatment planning process. One economical and efficiency approach involves the use of T1-weighted magnetic resonance (MR) images. Therefore, we designed this study to test whether a separate constraint of active BM identified by MR could reduce acute HT in course of concurrent chemoradiotherapy for patients with gastric and rectal cancer.
Detailed Description: 1、Simulation All patients underwent computed tomography (CT) simulation in the supine position for gastric cancer patients and The CT scan was obtained from the T4 vertebral body to L5 cm. Oral contrast and intravenous contrast were administered prior to the CT scan. All patients underwent computed tomography (CT) simulation in the prone position for rectal cancer patients with a full bladder and using a belly board to minimize exposure of the small bowel. Oral contrast and intravenous contrast were administered prior to the CT scan. A radio-opaque marker was placed at the anal margin. The superior and inferior limits of the acquired transaxial data (set by the topogram) were the iliac crests and 5 cm inferior to the anal marker, respectively. Intravenous contrast were administered prior to the CT scan. 2.Radiotherapy and chemotherapy For gastric cancer patients after surgery and chemotherapy,the 4500 cGy of radiation was delivered in 25 fractions, five days per week, to the tumor bed, to the regional nodes, and 2 cm beyond the proximal and distal margins of resection. The tumor bed was defined by preoperative computed tomographic (CT) imaging, barium roentgenography, and in some instances, surgical clips. Perigastric, celiac, local paraaortic, splenic, hepatoduodenal or hepatic-portal, and pancreaticoduodenal lymph nodes were included in the radiation fields. In patients with tumors of the gastroesophageal junction, paracardial and paraesophageal lymph nodes were included in the radiation fields. Concurrent chemotherapy regimen is monotherapy with capecitabine 1600mg∙m2 twice a day (b.i.d.). For rectal cancer patients before surgery, The rectum was not opacified with barium in order to avoid contour artifacts. The gross tumor volume (GTV) was generated with the CT scan, MR scan and endoscopic ultrasonography results. Only a clinical target volume (CTV) was delineated, encompassing the entire mesorectum, Pararectal nodes were also included, together with the presacral and promontory nodes (limit to L5-S1 interspace ), and the internal iliac nodes up to the venous bifurcation. External iliac nodes were not included as they have not been a site for recurrence in our experience. On the contrary, internal pudendal nodes were included in the CTV. Organs at risk were also contoured: bladder (with intravenous contrast), small bowel (with oral contrast) and femoral heads. The small bowel was contoured on all CT slices where it could be visualized, which was highly variable among patients. IMRT is given with 5000 cGy in 25 fractions (5 weeks). Concurrent chemotherapy consists of oxaliplatin (50 mg/m2 ) intravenously over 2 h on days 1, 8, 15, 22 and 29, and capecitabine (825 mg/m2 twice day) was given orally on each day of radiation. 3. Active bone marrow definition All the patient was scanned in the supine position on a 1.5 T MR scanner. For gastric cancer patients, the images were obtained from the T8 to L4 for gastric cancer patients. For rectal cancer patients, the images were obtained from the L3-4 interspace to below the ischial tuberosities for rectal cancer patients. The MR images were subsequently fused with the planning CT scan using commercially available image fusion software. The interactive mode of the fusion software was used whereby the user manually translates and rotates the MR scan to produce the best visual overlay of the two image sets. A mutual information algorithm was then used to perform a fine adjustment. The CT and MR images (resliced along the planes of the CT scan) were subsequently displayed side-by-side. BM regions on the T1-weighted images that showed a signal intensity equal to or slightly higher than that of muscle were contoured as active BM. The range of active BM was 3cm beyond the upper limit of PTV and 3cm below the lower limit of PTV.
Minimum Age: 18 Years
Eligible Ages: ADULT, OLDER_ADULT
Sex: ALL
Healthy Volunteers: No
Department of Radiation Oncology, Cancer Institute and Hospital, Chinese Academy of Medical Sciences & Peking Union Medical College, Beijing, Beijing, China
Name: Jing Jin, MD
Affiliation: Cancer Institute and Hospital, Chinese Academy of Medical Sciences & Peking Union Medical College
Role: PRINCIPAL_INVESTIGATOR
Name: Jianyang Wang, MD
Affiliation: Cancer Institute and Hospital, Chinese Academy of Medical Sciences & Peking Union Medical College
Role: STUDY_DIRECTOR