Surgical Planning for Reconstruction of Complex Heart Defects
Status: | Recruiting |
---|---|
Conditions: | Cardiology |
Therapuetic Areas: | Cardiology / Vascular Diseases |
Healthy: | No |
Age Range: | Any - 18 |
Updated: | 8/26/2018 |
Start Date: | August 2009 |
End Date: | February 2021 |
Contact: | Jan Fernandez, BS,RRT,CCRC |
Email: | janet.fernandez@choa.org |
Phone: | 404-785-1731 |
The purpose of this study is to utilize cardiac imaging data acquired as part of the standard
of care for these patients, such as MRI, 3D echo, and CT, and existing 3D reconstruction
protocols to assess the feasibility of using surgical planning in the treatment of patients
with complex cardiac defects. The specific aims of the project are as follows:
1. Develop a protocol to reconstruct heart models from patient imaging data and perform
"virtual" surgery on reconstructed 3D anatomy using appropriate, pre-existing patient
datasets.
2. Use the developed protocol to prospectively plan and evaluate the possible surgical
options for new patients.
3. Validate that the optimal virtual anatomy agrees with what was surgically implemented
using post-operative patient scans, when available.
of care for these patients, such as MRI, 3D echo, and CT, and existing 3D reconstruction
protocols to assess the feasibility of using surgical planning in the treatment of patients
with complex cardiac defects. The specific aims of the project are as follows:
1. Develop a protocol to reconstruct heart models from patient imaging data and perform
"virtual" surgery on reconstructed 3D anatomy using appropriate, pre-existing patient
datasets.
2. Use the developed protocol to prospectively plan and evaluate the possible surgical
options for new patients.
3. Validate that the optimal virtual anatomy agrees with what was surgically implemented
using post-operative patient scans, when available.
In the United States, approximately 1 in 200 babies are born each year with harmful
congenital heart defects (CHD) that require some form of medical management. Often, these
defects consist of holes in the septum (the walls between the heart chambers) and/or abnormal
development of the heart chambers or major blood vessels. Surgery is the primary treatment
course for many of these patients and, through the use of patches and artificial vessels, it
is often possible to repair the defects and recreate the normal blood flow path through the
heart.
These techniques are not always simple, however, and the surgeon must take great care not to
harm the pumping function of the heart. In more complex cases, the surgeon must decide
between multiple repair strategies that will have a major effect on the long-term health of
the patient. It would be helpful in such cases for the surgeon to be able to assess the
repair options prior to the operation using virtual 3-dimensional representations of that
patient's anatomy. Having this ability would remove some of the uncertainty from the
decision-making process by providing accurate predictions of post-surgical anatomy.
In fact, the technology exists to include such a surgical planning tool into the standard
treatment course for these patients. Using 3D anatomical images, acquired from basic,
techniques such as magnetic resonance (MR), computed tomography (CT), and echocardiography,
engineers at Georgia Tech have the ability to build accurate 3D models of patient anatomy,
such as the heart. Using these models with a state-of-the-art graphics manipulation tool,
surgeons would have the ability to virtually operate on the patient and select the optimal
treatment approach, as previously discussed. Similar techniques have already been developed
and used to plan surgeries for a limited subset of CHD patients with a single ventricle
physiology.
The purpose of this study is to further develop these techniques and apply them to a broader
range of CHD patients. To do this, patients undergoing an appropriate surgical repair will be
recruited to participate in the study. Images obtained from pre-operative scans will be used
to build the anatomical model, which the surgeon will manipulate to test the different
available options. By successfully testing and eventually implementing these techniques in
the standard of care for CHD patients, the optimal approach for reconstruction will be
implemented more frequently, and thus patient outcomes will improve.
congenital heart defects (CHD) that require some form of medical management. Often, these
defects consist of holes in the septum (the walls between the heart chambers) and/or abnormal
development of the heart chambers or major blood vessels. Surgery is the primary treatment
course for many of these patients and, through the use of patches and artificial vessels, it
is often possible to repair the defects and recreate the normal blood flow path through the
heart.
These techniques are not always simple, however, and the surgeon must take great care not to
harm the pumping function of the heart. In more complex cases, the surgeon must decide
between multiple repair strategies that will have a major effect on the long-term health of
the patient. It would be helpful in such cases for the surgeon to be able to assess the
repair options prior to the operation using virtual 3-dimensional representations of that
patient's anatomy. Having this ability would remove some of the uncertainty from the
decision-making process by providing accurate predictions of post-surgical anatomy.
In fact, the technology exists to include such a surgical planning tool into the standard
treatment course for these patients. Using 3D anatomical images, acquired from basic,
techniques such as magnetic resonance (MR), computed tomography (CT), and echocardiography,
engineers at Georgia Tech have the ability to build accurate 3D models of patient anatomy,
such as the heart. Using these models with a state-of-the-art graphics manipulation tool,
surgeons would have the ability to virtually operate on the patient and select the optimal
treatment approach, as previously discussed. Similar techniques have already been developed
and used to plan surgeries for a limited subset of CHD patients with a single ventricle
physiology.
The purpose of this study is to further develop these techniques and apply them to a broader
range of CHD patients. To do this, patients undergoing an appropriate surgical repair will be
recruited to participate in the study. Images obtained from pre-operative scans will be used
to build the anatomical model, which the surgeon will manipulate to test the different
available options. By successfully testing and eventually implementing these techniques in
the standard of care for CHD patients, the optimal approach for reconstruction will be
implemented more frequently, and thus patient outcomes will improve.
Inclusion Criteria:
- any pre-operative patient with a complex heart lesion treated at Children's Healthcare
of Atlanta by Dr. Kanter or his team that is appropriate for surgical planning
Exclusion Criteria:
- upon review by engineers at Georgia Tech, the image quality of the acquired scans is
deemed insufficient to reconstruct an accurate 3D model
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