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Clinical Trial Details — Status: Completed

Administrative data

NCT number NCT01934855
Other study ID # J1370
Secondary ID NA_00085958
Status Completed
Phase N/A
First received August 30, 2013
Last updated October 9, 2015
Start date October 2013
Est. completion date October 2015

Study information

Verified date October 2015
Source Sidney Kimmel Comprehensive Cancer Center
Contact n/a
Is FDA regulated No
Health authority United States: Institutional Review Board
Study type Observational

Clinical Trial Summary

The main goal of this research is to characterize patient-specific respiration-induced tumor and surrogate motion to evaluate the accuracy and effectiveness of the surrogate-based motion management strategies currently used in clinics. Specifically, the investigators hypothesize that dynamic MRI (Magnetic Resonance Imaging) obtained over a temporal duration consistent with radiotherapy treatments will provide spatio-temporal information of both the tumor and surrogate, and therefore can serve as a means to assess the quality of the tumor motion tracking with the surrogate. To test this hypothesis, the investigators specifically propose to 1) track and characterize the tumor and surrogate motion with 4D (4 dimensional)-MRI and 2) evaluate surrogate-based motion tracking in a cohort of patients with thoracic tumors.

External and internal surrogate-based strategies commonly used in clinics have not been appropriately validated. With the increasing adaptation of these surrogate methods for motion management, the proposed research addresses these urgent issues in clinical radiotherapy while providing a means to achieve patient-specific motion management.


Description:

Respiration-induced patient motion has become a major obstacle for achieving high-precision radiotherapy of cancers especially in the thorax and upper abdomen. As the target is continuously moving, an additional margin has to be added to the clinical target volume to compensate for the uncertainty in the tumor and organ motion, causing toxicity to the normal tissue and limiting the dose delivered to the target. To account for the tumor motion, surrogate tracking methods are commonly used in clinics during radiotherapy. However, the relationship between the surrogate and tumor motion is hard to generalize as it depends on individual patients, tumor location, treatment fractions, and sometimes shows complex patterns or transient, unpredictable changes. Hence, there is an urgent need to better scrutinize the current surrogate-based motion management strategies. Moreover, the most robust motion management strategy for the given patient should be determined in the pre-treatment setting but the investigators currently lack a sufficient tool to provide this information.

4D-CT is typically used to characterize the tumor motion over the course of the radiotherapy. However, 4D-CT is an oversimplified snapshot representation of a single-breathing cycle with low soft tissue contrast while imparting a considerable amount of radiation dose to the patient. Consequently, the limitations of 4D-CT prevent applicability in acquiring information over timescales that represent a treatment session. MRI is highly advantageous as it is non-ionizing and provides excellent soft tissue contrast. Although real-time 3D dynamic MRI is limited by low image quality and temporal resolution, 2D dynamic MRI techniques have high fidelity and spatio-temporal resolution requisite for real-time tracking of the moving target. Furthermore, a respiration-correlated 4D-MRI can be reconstructed from multi-slice 2D dynamic MR images, enabling volumetric image processing and analysis. Therefore, 4D-MRI is an attractive solution to address breathing motion and tumor tracking obstacles in radiotherapy.

The main goal of this research is to characterize patient-specific respiration-induced tumor and surrogate motion to evaluate the accuracy and effectiveness of the surrogate-based motion management strategies currently used in clinics. Specifically, the investigators hypothesize that dynamic MRI obtained over a temporal duration consistent with radiotherapy treatments will provide spatio-temporal information of both the tumor and surrogate, and therefore can serve as a means to assess the quality of the tumor motion tracking with the surrogate. To test their hypothesis, the investigators specifically propose to 1) track and characterize the tumor and surrogate motion with 4D-MRI and 2) evaluate surrogate-based motion tracking in a cohort of patients with thoracic tumors.

External and internal surrogate-based strategies commonly used in clinics have not been appropriately validated. With the increasing adaptation of these surrogate methods for motion management, the proposed research addresses these urgent issues in clinical radiotherapy while providing a means to achieve patient-specific motion management.


Recruitment information / eligibility

Status Completed
Enrollment 32
Est. completion date October 2015
Est. primary completion date October 2015
Accepts healthy volunteers No
Gender Both
Age group 18 Years to 100 Years
Eligibility Inclusion Criteria:

- Histologically-confirmed primary lung cancer (non-small cell OR small cell)

- Plan to undergo external radiation treatment of lung cancer

Exclusion Criteria:

- Patients who cannot undergo MRIs.

- Patients who have a cardiac device or other electronic or metal implant

Study Design

Observational Model: Cohort, Time Perspective: Prospective


Related Conditions & MeSH terms


Locations

Country Name City State
United States The Sidney Kimmel Comprehensive Cancer Center at Johns Hopkins Baltimore Maryland

Sponsors (1)

Lead Sponsor Collaborator
Sidney Kimmel Comprehensive Cancer Center

Country where clinical trial is conducted

United States, 

Outcome

Type Measure Description Time frame Safety issue
Primary Tumor motion characterization during radiation therapy To characterize patient-specific respiration-induced tumor and surrogate motion to evaluate the accuracy and effectiveness of the surrogate-based motion management strategies currently used in radiotherapy. 1 year No
Secondary Correlation of tumor and surrogate motion Tumor and surrogate motion will be quantified by measuring the displacements from their end-exhale positions. Since the tumor may deform during motion, we will not only consider the trajectories of the center of mass but also the tumor borders. The tumor position as a function of the surrogate position will be analyzed along each moving direction. Pearson correlation coefficients and the sum of squared residual errors based on a regression analysis will be computed to provide a quantitative measure of the correlation between the surrogate and tumor positions. To measure the tumor deformation, correlations of the motion between the SI borders, AP borders, LR borders will also be computed. Although lung tumor likely does not significantly deform, this analysis will be useful for tumors that may deform significantly during motion. The motion under the different breathing patterns will be analyzed separately, and compared to each other. 1 year No
Secondary Sensitivity and specificity of gating Respiratory gating is one predominant technique for managing respiratory motion. Gating attempts to minimize normal tissue dose by delivering radiation during a portion of the respiratory cycle where the respiratory state is typically determined from an external surrogate as an optical signal. We will use different gating boundaries, e.g. 10%, 20% of the surrogate motion range (from mean exhale to mean inhale) on each axes as commonly used in clinical practice. Sensitivity and specificity of the gating will be computed by comparing the portion of time the surrogate is below/above the gating boundary and that the tumor is below/above the gating boundary. 1 year No
Secondary Pre- and intra-treatment motion variability MRI scans of the patient will be acquired pre- and intra-treatment. Tumor motion variability will be computed between these two scans. We will evaluate the correlation of the target location captured at different time points by computing target volume overlap and systematic volume shift. We will also analyze the tumor position as a function of the surrogate position for both pre- and intra-treatment scans, and will investigate how well these two distributions match. To quantitatively measure the differences, we will compute various statistical similarity measures such as correlation coefficient and mutual information. We will also calculate pre-treatment margins to account for the tumor motion using the pre-treatment retrospective 4D-MRI reconstruction, and calculate the portion of treatment time the tumor moves within or outside the specified margins during the successive scans. 1 year No
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