Advanced Radiotherapy Delivers Total Marrow Irradiation Treatments for Patients with Blood Cancers
|
By MedImaging International staff writers Posted on 23 Aug 2011 |
|
Advanced radiotherapy can be used to treat patients with blood cancers by delivering rapidly and accurately “clinically favorable” total marrow irradiation (TMI), according to a team of noted cancer treatment experts.
The investigators presented their findings at the 2011 joint meeting of the American Association of Physicists in Medicine (AAPM) and the Canadian Organization of Medical Physicists (COMP) in Vancouver, Canada, in August 2011. Their recent study on this RapidArc radiotherapy, developed by Varian Medical Systems (Palo Alto, CA, USA), was published online in August 2011 as an article in press, ahead of publication, is slated to appear in an upcoming issue of the International Journal of Radiation Oncology*Biology*Physics.
“Compared to conventional IMRT and tomotherapy, RapidArc appears to improve on the dose distribution, in terms of normal tissue sparing, as well as on the efficiency of treatment,” said Bulent Aydogan, PhD, associate professor of medical physics at the University of Chicago (IL, USA) and the director of medical physics at the University of Illinois at Chicago (UIC; USA).
Dr. Aydogan and his collaborators planned and delivered, in their recent dosimetric feasibility study, RapidArc TMI treatments for six patients, and then compared the treatment plan parameters, including median dose, mean dose, and maximum dose, to fixed-gantry and tomotherapy plans for the same cases. They found that RapidArc generates dose distributions that are comparable to traditional intensity-modulated radiotherapy (IMRT) in terms of target coverage, but with improved normal tissue sparing.
The RapidArc treatments could also be delivered much more efficiently, requiring approximately 18 minutes once a patient was positioned for treatment. By comparison, treatment times of 45 to 50 minutes have been reported for TMI delivered using conventional IMRTand tomotherapy. “The data presented in this study demonstrate the utility of RapidArc technology in providing exceptional target coverage and normal tissue sparing even for difficult techniques like TMI,” the study authors emphasized. Based on their findings, the authors are planning to test the clinical feasibility of RapidArc for treating patients with multiple myeloma at the University of Chicago.
Radiotherapy, in combination with chemotherapy, can be employed to destroy tumor cells and suppress the immune system in preparation for a bone marrow transplant. Healthy bone marrow stem cells are then infused into the patient’s bloodstream. The new cells migrate to the bone cavities and begin producing normal blood cells.
“Historically, radiation oncologists used total body irradiation, or TBI, to prepare patients for these transplants. But TBI is not ideal, as it targets the entire body and causes too much damage to surrounding healthy tissues and organs, especially at dose levels high enough to be effective,” explained Dr. Aydogan. “Our studies have examined the feasibility of using linear accelerators to deliver IMRT to target not the whole body, but the bone marrow, and to minimize exposure of surrounding organs like the lungs, heart, liver, kidneys, brain, eyes, oral cavity, and bowel.”
As part of a phase I clinical trial at UIC, Dr. Aydogan and his colleagues have collaborated with Damiono Rondell, MD, professor of hematology oncology and the director of stem cell transplant program, to treat seven patients with advanced disease using intensity-modulated total marrow technique (IM-TMI). “The major drawback of the IM-TMI technique is the amount of time it takes to deliver the treatment. In this latest study, we looked specifically at RapidArc and found it to be a viable approach for accomplishing TMI within a clinically acceptable timeframe,” Dr. Aydogan said. “While patients at high risk of hematologic malignancy often do better after stem cell transplants, they still have had a high rate of disease relapse, particularly when treated using radiation-free regimens. We are hopeful that TMI will enable us to add targeted radiotherapy into the mix, for a better chance at disease-free survival with fewer complications.”
Since the technology was introduced in 2007, over 1,000 RapidArc radiotherapy-enabled systems have been installed at hospitals and clinics around the world. RapidArc treatment plans are produced using Varian’s Eclipse treatment planning software, which is cleared by the US Food and Drug Administration (FDA) for planning photon, electron, and proton beam radiotherapy for patients with malignant or benign diseases.
Related Links:
Varian Medical Systems
University of Chicago
University of Illinois at Chicago
The investigators presented their findings at the 2011 joint meeting of the American Association of Physicists in Medicine (AAPM) and the Canadian Organization of Medical Physicists (COMP) in Vancouver, Canada, in August 2011. Their recent study on this RapidArc radiotherapy, developed by Varian Medical Systems (Palo Alto, CA, USA), was published online in August 2011 as an article in press, ahead of publication, is slated to appear in an upcoming issue of the International Journal of Radiation Oncology*Biology*Physics.
“Compared to conventional IMRT and tomotherapy, RapidArc appears to improve on the dose distribution, in terms of normal tissue sparing, as well as on the efficiency of treatment,” said Bulent Aydogan, PhD, associate professor of medical physics at the University of Chicago (IL, USA) and the director of medical physics at the University of Illinois at Chicago (UIC; USA).
Dr. Aydogan and his collaborators planned and delivered, in their recent dosimetric feasibility study, RapidArc TMI treatments for six patients, and then compared the treatment plan parameters, including median dose, mean dose, and maximum dose, to fixed-gantry and tomotherapy plans for the same cases. They found that RapidArc generates dose distributions that are comparable to traditional intensity-modulated radiotherapy (IMRT) in terms of target coverage, but with improved normal tissue sparing.
The RapidArc treatments could also be delivered much more efficiently, requiring approximately 18 minutes once a patient was positioned for treatment. By comparison, treatment times of 45 to 50 minutes have been reported for TMI delivered using conventional IMRTand tomotherapy. “The data presented in this study demonstrate the utility of RapidArc technology in providing exceptional target coverage and normal tissue sparing even for difficult techniques like TMI,” the study authors emphasized. Based on their findings, the authors are planning to test the clinical feasibility of RapidArc for treating patients with multiple myeloma at the University of Chicago.
Radiotherapy, in combination with chemotherapy, can be employed to destroy tumor cells and suppress the immune system in preparation for a bone marrow transplant. Healthy bone marrow stem cells are then infused into the patient’s bloodstream. The new cells migrate to the bone cavities and begin producing normal blood cells.
“Historically, radiation oncologists used total body irradiation, or TBI, to prepare patients for these transplants. But TBI is not ideal, as it targets the entire body and causes too much damage to surrounding healthy tissues and organs, especially at dose levels high enough to be effective,” explained Dr. Aydogan. “Our studies have examined the feasibility of using linear accelerators to deliver IMRT to target not the whole body, but the bone marrow, and to minimize exposure of surrounding organs like the lungs, heart, liver, kidneys, brain, eyes, oral cavity, and bowel.”
As part of a phase I clinical trial at UIC, Dr. Aydogan and his colleagues have collaborated with Damiono Rondell, MD, professor of hematology oncology and the director of stem cell transplant program, to treat seven patients with advanced disease using intensity-modulated total marrow technique (IM-TMI). “The major drawback of the IM-TMI technique is the amount of time it takes to deliver the treatment. In this latest study, we looked specifically at RapidArc and found it to be a viable approach for accomplishing TMI within a clinically acceptable timeframe,” Dr. Aydogan said. “While patients at high risk of hematologic malignancy often do better after stem cell transplants, they still have had a high rate of disease relapse, particularly when treated using radiation-free regimens. We are hopeful that TMI will enable us to add targeted radiotherapy into the mix, for a better chance at disease-free survival with fewer complications.”
Since the technology was introduced in 2007, over 1,000 RapidArc radiotherapy-enabled systems have been installed at hospitals and clinics around the world. RapidArc treatment plans are produced using Varian’s Eclipse treatment planning software, which is cleared by the US Food and Drug Administration (FDA) for planning photon, electron, and proton beam radiotherapy for patients with malignant or benign diseases.
Related Links:
Varian Medical Systems
University of Chicago
University of Illinois at Chicago
Computed Tomography System
Aquilion ONE / INSIGHT Edition
Radiology Software
DxWorks
Portable Color Doppler Ultrasound System
S5000
Ultrasound Imaging System
P12 Elite
Latest Nuclear Medicine News
- Novel Radiolabeled Antibody Improves Diagnosis and Treatment of Solid Tumors
- Novel PET Imaging Approach Offers Never-Before-Seen View of Neuroinflammation
- Novel Radiotracer Identifies Biomarker for Triple-Negative Breast Cancer
- Innovative PET Imaging Technique to Help Diagnose Neurodegeneration
- New Molecular Imaging Test to Improve Lung Cancer Diagnosis
- Novel PET Technique Visualizes Spinal Cord Injuries to Predict Recovery
- Next-Gen Tau Radiotracers Outperform FDA-Approved Imaging Agents in Detecting Alzheimer’s
- Breakthrough Method Detects Inflammation in Body Using PET Imaging
- Advanced Imaging Reveals Hidden Metastases in High-Risk Prostate Cancer Patients
- Combining Advanced Imaging Technologies Offers Breakthrough in Glioblastoma Treatment
- New Molecular Imaging Agent Accurately Identifies Crucial Cancer Biomarker
- New Scans Light Up Aggressive Tumors for Better Treatment
- AI Stroke Brain Scan Readings Twice as Accurate as Current Method
- AI Analysis of PET/CT Images Predicts Side Effects of Immunotherapy in Lung Cancer
- New Imaging Agent to Drive Step-Change for Brain Cancer Imaging
- Portable PET Scanner to Detect Earliest Stages of Alzheimer’s Disease
Channels
MRI
view channel
Cutting-Edge MRI Technology to Revolutionize Diagnosis of Common Heart Problem
Aortic stenosis is a common and potentially life-threatening heart condition. It occurs when the aortic valve, which regulates blood flow from the heart to the rest of the body, becomes stiff and narrow.... Read more
New MRI Technique Reveals True Heart Age to Prevent Attacks and Strokes
Heart disease remains one of the leading causes of death worldwide. Individuals with conditions such as diabetes or obesity often experience accelerated aging of their hearts, sometimes by decades.... Read more
AI Tool Predicts Relapse of Pediatric Brain Cancer from Brain MRI Scans
Many pediatric gliomas are treatable with surgery alone, but relapses can be catastrophic. Predicting which patients are at risk for recurrence remains challenging, leading to frequent follow-ups with... Read more
AI Tool Tracks Effectiveness of Multiple Sclerosis Treatments Using Brain MRI Scans
Multiple sclerosis (MS) is a condition in which the immune system attacks the brain and spinal cord, leading to impairments in movement, sensation, and cognition. Magnetic Resonance Imaging (MRI) markers... Read moreUltrasound
view channel.jpeg "Image: The AI-powered lung ultrasound tool outperformed human experts by 9% in diagnosing TB (Photo courtesy of Adobe Stock)")
AI-Powered Lung Ultrasound Outperforms Human Experts in Tuberculosis Diagnosis
Despite global declines in tuberculosis (TB) rates in previous years, the incidence of TB rose by 4.6% from 2020 to 2023. Early screening and rapid diagnosis are essential elements of the World Health... Read more
AI Identifies Heart Valve Disease from Common Imaging Test
Tricuspid regurgitation is a condition where the heart's tricuspid valve does not close completely during contraction, leading to backward blood flow, which can result in heart failure. A new artificial... Read more
Nuclear Medicine
view channel
Novel Radiolabeled Antibody Improves Diagnosis and Treatment of Solid Tumors
Interleukin-13 receptor α-2 (IL13Rα2) is a cell surface receptor commonly found in solid tumors such as glioblastoma, melanoma, and breast cancer. It is minimally expressed in normal tissues, making it... Read more
Novel PET Imaging Approach Offers Never-Before-Seen View of Neuroinflammation
COX-2, an enzyme that plays a key role in brain inflammation, can be significantly upregulated by inflammatory stimuli and neuroexcitation. Researchers suggest that COX-2 density in the brain could serve... Read more
General/Advanced Imaging
view channel
AI-Based CT Scan Analysis Predicts Early-Stage Kidney Damage Due to Cancer Treatments
Radioligand therapy, a form of targeted nuclear medicine, has recently gained attention for its potential in treating specific types of tumors. However, one of the potential side effects of this therapy... Read more
CT-Based Deep Learning-Driven Tool to Enhance Liver Cancer Diagnosis
Medical imaging, such as computed tomography (CT) scans, plays a crucial role in oncology, offering essential data for cancer detection, treatment planning, and monitoring of response to therapies.... Read more
Imaging IT
view channel
New Google Cloud Medical Imaging Suite Makes Imaging Healthcare Data More Accessible
Medical imaging is a critical tool used to diagnose patients, and there are billions of medical images scanned globally each year. Imaging data accounts for about 90% of all healthcare data1 and, until... Read more
Global AI in Medical Diagnostics Market to Be Driven by Demand for Image Recognition in Radiology
The global artificial intelligence (AI) in medical diagnostics market is expanding with early disease detection being one of its key applications and image recognition becoming a compelling consumer proposition... Read more
Industry News
view channel
GE HealthCare and NVIDIA Collaboration to Reimagine Diagnostic Imaging
GE HealthCare (Chicago, IL, USA) has entered into a collaboration with NVIDIA (Santa Clara, CA, USA), expanding the existing relationship between the two companies to focus on pioneering innovation in... Read more
Patient-Specific 3D-Printed Phantoms Transform CT Imaging
New research has highlighted how anatomically precise, patient-specific 3D-printed phantoms are proving to be scalable, cost-effective, and efficient tools in the development of new CT scan algorithms... Read more
Siemens and Sectra Collaborate on Enhancing Radiology Workflows
Siemens Healthineers (Forchheim, Germany) and Sectra (Linköping, Sweden) have entered into a collaboration aimed at enhancing radiologists' diagnostic capabilities and, in turn, improving patient care... Read more