Abstract

? Modem cardiac surgical practice involves the routine use of cardiopulmonary bypass (CPB) for performing both coronary artery bypass graft (CABG) procedures on the heart surface as well as procedures inside the heart, classified broadly as intracardiac surgery. However, recent studies indicate that CPB carries important risks that can lead to reduced neuropsychiatric function and stroke in adults, and neurodevelopmental deficits with impaired fine motor skills in children. Other adverse effects of CPB include activation of inflammatory mediators and the complement cascade, showers of particulate emboli with aortic manipulation and crossclamp release, and air embolus. To avoid these risks of CPB, several investigators have begun to evaluate the results of CABG procedures performed without CPB. Early results of these """"""""beating heart"""""""" procedures indicate equivalent patency rates, comparable mortality rates, and significant savings. Development of techniques for intracardiac beating heart surgery, however, must overcome the unique challenge of the inability to image the anatomic features of the heart with sufficient detail and time resolution to permit instrument navigation and precise tissue manipulation. Real time 3D echo has the potential for overcoming these issues thereby enabling intracardiac beating heart surgery. The overall aim of this proposal is to adapt real time 3-D ultrasound imaging specifically for image-guided interventions and integrate this technology with safety measures through instrument tracking, tactile sensing, and acoustic tissue analysis to permit safe and accurate intracardiac beating heart surgery. The complexity of this problem is well suited to a BRP approach. The PI has assembled a multidisciplinary team and established a unique partnership among industry-based engineers (Philips Medical Systems), university-based engineers (Harvard University; Boston University), and clinical investigators (Children's Hospital; Brigham and Women's Hospital). Together, we will approach this problem by addressing the following specific aims:
AIM I : Modify real-time 3-D ultrasound to optimize image presentation for guiding intracardiac surgical procedures in a beating heart.
AIM II : Adapt high-resolution electromagnetic tracking equipment for precise intracardiac navigation and modify surgical instruments to limit interference with ultrasound imaging during beating heart surgical procedures.
AIM III : Develop instruments to provide both tactile sensing and acoustic tissue analysis for increased procedure safety.
AIM I V: Integrate real time 3-D ultrasound imaging and tracking equipment with computer-enhanced instrument control for improved task performance and safety during image-guided surgery. ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL073647-02
Application #
6772599
Study Section
Special Emphasis Panel (ZRG1-SRB (09))
Program Officer
Hoke, Tracey R
Project Start
2003-07-15
Project End
2008-06-30
Budget Start
2004-07-01
Budget End
2005-06-30
Support Year
2
Fiscal Year
2004
Total Cost
$712,899
Indirect Cost

  Institution

Name
Children's Hospital Boston
Department
Type
DUNS #
076593722
City
Boston
State
MA
Country
United States
Zip Code
02115

  Publications

Loschak, Paul M; Brattain, Laura J; Howe, Robert D (2017) Algorithms for Automatically Pointing Ultrasound Imaging Catheters. IEEE Trans Robot 33:81-91
Loschak, Paul M; Burke, Stephen F; Zumbro, Emiko et al. (2015) A Robotic System for Actively Stiffening Flexible Manipulators. Rep U S 2015:216-221
Roche, Ellen T; Fabozzo, Assunta; Lee, Yuhan et al. (2015) A light-reflecting balloon catheter for atraumatic tissue defect repair. Sci Transl Med 7:306ra149
Brattain, Laura J; Loschak, Paul M; Tschabrunn, Cory M et al. (2014) Instrument Tracking and Visualization for Ultrasound Catheter Guided Procedures. Augment Environ Comput Assist Interv (2014) 8678:41-50
Lang, Nora; Pereira, Maria J; Lee, Yuhan et al. (2014) A blood-resistant surgical glue for minimally invasive repair of vessels and heart defects. Sci Transl Med 6:218ra6
Jentoft, Leif P; Dollar, Aaron M; Wagner, Christopher R et al. (2014) Intrinsic embedded sensors for polymeric mechatronics: flexure and force sensing. Sensors (Basel) 14:3861-70
Feins, Eric N; Yamauchi, Haruo; Marx, Gerald R et al. (2014) Repair of posterior mitral valve prolapse with a novel leaflet plication clip in an animal model. J Thorac Cardiovasc Surg 147:783-90; discussion 790-1
Tenenholtz, Neil A; Hammer, Peter E; Fabozzo, Assunta et al. (2013) Fast Simulation of Mitral Annuloplasty for Surgical Planning. Funct Imaging Model Heart 7945:106-113
Yuen, Shelten G; Vasilyev, Nikolay V; del Nido, Pedro J et al. (2013) Robotic tissue tracking for beating heart mitral valve surgery. Med Image Anal 17:1236-42
Arabagi, Veaceslav; Gosline, Andrew; Wood, Robert J et al. (2013) Simultaneous Soft Sensing of Tissue Contact Angle and Force for Millimeter-scale Medical Robots. IEEE Int Conf Robot Autom :

Showing the most recent 10 out of 83 publications