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Valve job W. Randolph Chitwood MD

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Presentation on theme: "Valve job W. Randolph Chitwood MD"— Presentation transcript:

1 Valve job W. Randolph Chitwood MD
Professor and Chairman, Department of Surgery East Carolina University School of Medicine Greenville, NC Wylie Nifong MD Assistant Professor, Cardiothoracic Surgery

2 Cardiac surgery Minimally invasive procedures
Despite rapid advances in minimally invasive techniques in other surgical specialties, cardiac surgeons have lagged behind in developing minimal access methods. Cardiac surgery has traditionally been done through larger breast-bone incisions to allow full access to the heart. Advances in less invasive cardiac surgery are now being made both in Europe and the United States. The earliest minimally invasive procedures were done through smaller incisions, using the surgeon's eyes and hands. Procedures then developed using videoscopic screens, but still using long instruments.

3 The da Vinci EndoWrist™
Robotic surgery The next step Robotic or computer-enhanced operations are the next step. Hand motions the surgeon makes while sitting at a console are transmitted through computer to instruments within the patient’s chest cavity. Instead of long instruments, microwrists, extensions of the human wrist, are used to perform procedures. The da Vinci EndoWrist™ ©1998 Intuitive Surgical

4 The German experience 2 years of mitral valve surgery
From June 1996 to December 1998, 129 patients with non-ischemic mitral valve disease underwent 3D-video- assisted mitral valve surgery via a 4-cm right lateral minithoracotomy using femoro-femoral bypass and endoaortic clamping. Group 1: port-access minimally invasive surgery the first 62 patients who underwent the procedure Group 2: port-access robot-assisted solo surgery catheter design was modified and the procedure was redefined and simplified after the initial 62 patients the procedure was completed as robot-assisted solo surgery, without an additional assistant Mohr FW, et al. Eur J Cardiothorac Surg 1999;15(3):

5 The German experience Results p value Time for surgery (min) 188  52
Group 1 (n=62) Group 2 (n=67) p value Time for surgery (min) 188  52 152  56 <0.005 Clamp time (min) 69  26 48  16 <0.002 Intubation time (h) 19  7 14  6 ICU time (days) 2.3  1.6 1.3  0.9 Hospitalization (days) 13  3 10  3 Mean survival (95% CI) Group 1 (n=62) 88.7%* at 804  35 days (735–873) Group 2 (n=37) 97.0% at 568  12 days (553–600) *partially procedure related (aortic dissection in 2 patients) Mohr FW, et al. Eur J Cardiothorac Surg 1999;15(3):

6 FDA-approved trial Microvalve surgery using the articulated wrist
The first Specific Investigational Device Exemption (IDE) clinical trials are being performed with the da Vinci device at the Ohio State University Medical Center in Columbus, Ohio, and at East Carolina University/Pitt Memorial Hospital in Greenville, North Carolina. The FDA approved a protocol for 10 microvalve operations.

7 Robotic surgery A tiny camera with multiple lenses, inserted into the patient's chest, provides a 3-dimensional image of the heart. The surgeon, at a nearby computer workstation, can see inside the chest through a viewport and uses a pair of joysticks to control the robotic arms. ©1999. Courtesy The Ohio State University Medical Center, used by permission.

8 The American experience
©1999. Courtesy The Ohio State University Medical Center, used by permission Minimally invasive heart surgery using the da Vinci computer-enhanced surgical system being performed at The Ohio State University Medical Center.

9 Robotic surgery Smaller incisions
The camera is inserted through a 5-cm incision. 2 additional incisions (ports) are made, 1 for each robotic arm. A 5-mm incision is made in which to place a clamp that goes across the chest wall to interrupt the heart. ©2000 Computer Motion. Photography B. Benett

10 Robotic surgery OR setup
©1999 J Thorac Cardiovasc Surg Schematic illustration of a robotic operative setup. Surgeon seated at console operating on the master manipulator controlling motions of the robotic arms via computer interface. Damiano RJ. J Thorac Cardiovasc Surg 1999;117:

11 Robotic surgery Faster recovery
The ultimate goals are to make cardiac surgery less debilitating and to shorten the recovery period. With videoscopic procedures, the hospitalization period dropped from 7 days to 3.5 days. With robotic devices, the hospitalization period will probably drop to 2.5–3 days.

12 The AESOP scope The FDA-approved AESOP (Automated Endoscope System for Optimal Positioning) is a single voice-controlled robotic arm that understands 23 simple commands such as "move up," "right," "left," "back," "return," and "move in." ©2000 Computer Motion ©2000 Computer Motion

13 The AESOP scope Faster recovery and cost effective
Patients who had surgery with the AESOP did much better significantly shorter stay in ICU significantly reduced time on ventilator significantly fewer blood transfusions shorter hospital stay (mean of 3.8–3.9 days vs 8 days for conventional sternotomy incision) Because patients had fewer complications and were discharged from hospital sooner, AESOP procedures actually cost 28%–33% less than standard mitral valve surgery.

14 Micro-mitral operation
The Micro-mitral operation begins with cardiopulmonary bypass established through femoral arterial and venous cannulas inserted under direct vision using the Seldinger technique. The heart is accessed through a 6-cm right lateral minithoracotomy (or "instrumentation port") made in the 4th intercostal space at the anterior axillary line. ©1999 J Thorac Cardiovasc Surg Chitwood WR. J Thorac Cardiovasc Surg 1997;114(5):

15 Micro-mitral operation
Either a 5-mm 2-dimensional endoscopic rod-lens camera with screen monitor or a 3-dimensional digital camera with a head-mounted display is used for intracardiac visualization and to guide instrument manipulation. Aortic cross clamping is performed through the intact chest wall using a special transthoracic clamp with sliding rod design. Standard anterograde cardioplegic arrest is used for myocardial preservation. Valve excision, suture placement, valve or annuloplasty ring seating, and knot tying are performed with videoscopic visualization and instrumentation. Transthoracic clamp ©1999 J Thorac Cardiovasc Surg Chitwood WR. J Thorac Cardiovasc Surg 1997;114(5):

16 The AESOP scope Learning curve
In the US, all cardiac surgeons have general surgery training with experience in endoscopic and laproscopic surgery (operating from a monitor). Most surgeons involved with robotics have experience with less invasive approaches using cameras and videoscopic technology. Although robotic technology provides 3- dimensional images, it is a leap in the procedure to operate on the heart looking at a monitor.

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