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New
Techniques for Coronary Artery Bypass Surgery
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MIDCAB
(Minimally Invasive Direct Coronary Artery Bypass Surgery) |
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This was the first “minimally invasive heart surgery.”
And, I was the first to perform this procedure in the region on July 11, 1996.
Though my experience was written about in The Morning Call and The Wall Street
Journal, I responded with an editorial cautioning the public that conventional
surgery was still the best choice for the overwhelming majority of patients
which, indeed, turned out to be correct. |
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The procedure involved making a small incision, usually
under the left breast. The surgeon would then sew the left internal mammary
artery directly to the left anterior descending coronary artery while the heart
was beating. |
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The procedure quickly lost favor because it was limited to
one bypass. It was difficult to harvest the left internal mammary artery
through the small incision. And, the results were marginal at best, despite
some large series showing good results. Some patients suffered complications
specific to this procedure, including intercostal nerve pain, wound
complications, and most of all, anastomotic complications.
Keep in mind; this was the hot new thing only a few years
back with a report on the front page of many newspapers, but how many are being
doing now? You can ask surgeons in the region, but I suspect none.
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OPCAB
(Off
Pump Coronary Artery Bypass Surgery) |
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This procedure asks the question, “What is the most
invasive part of bypass surgery? Is it the incision? Or, is it the use of the
heart-lung machine?” The advocates of this procedure answer by saying that the
most dangerous part of bypass surgery is the heart-lung machine. Of note, I
don’t agree with this philosophy, but instead would say that the most important
part of the operation is a perfect, complete job for which the heart-lung
machine provides the best opportunity.
The technique of OPCAB uses the same incision as
conventional surgery, the median sternotomy (sternal split). However, instead
of stopping the heart, this procedure uses a variety of “stabilizing devices”
to hold a vessel still so that the surgeon can sew to that vessel while the
rest of the heart is beating. The reason these surgeons use the median
sternotomy is because they know that this conventional incision gives you the
best access to the entire heart and is remarkably well tolerated (see later).
Here is one of the stabilizing devices that are placed on
the heart:
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OPCAB has had variable acceptance. Overall, only 10-30%
of all CABG procedures done in the United States are done with this technique,
probably now closer to only 10%. However, there are some institutions that the
surgeons have taken a particular interest in the procedure and perform 90%
“off-pump.” In Philadelphia, Einstein and Lankenau are two such places.
And yet, their results are no better than mine using conventional techniques.
On the contrary, neither Einstein nor Lankenau has ever received the
recognition Lehigh Valley Hospital has received for excellence in cardiac care.
The results are also variable. Keep in mind, coronary
artery bypass surgery is actually one of the most studied and of the safest
surgical procedures performed with results of only 1-3% mortality and 1-5%
complication rates. Imagine for a moment how difficult it would then be for
any new technique to improve on these results. In fact, at best the results
are as good, but not better than conventional techniques. And, personally, I
do not feel the surgical anastomosis (the sewing) is as accurate because of the
movement of the heart.
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Port-Access
(Heartport®) |
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This technique uses the concept of making a small
incision, but attempted to overcome the limitations of MIDCAB by using the
heart-lung machine and thus allowing the surgeon to work on the arrested heart.
The technology is extremely complex, utilizing catheters
in the groin and neck. Protection of the heart is variable and there are
well-documental complications unique to this technique. This technology could
be used both for coronary artery bypass surgery and for valve surgery,
especially mitral valve surgery.
Here are how the many catheters and tubes are placed:
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The use of this procedure for coronary artery bypass
surgery has been largely abandoned by most centers in the United States.
However, there remained some interest in this technique for mitral valve
surgery. It is this platform and/or similar variations of this platform that
robotic mitral valve surgery is based. |
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TECAB
(Totally Endoscopic Coronary Artery Bypass Surgery) |
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This technique utilizes the use of the robot. There are two companies
that have developed robotics for heart surgery, Computer Motion and
Intuitive. I performed the first robotic chest surgery procedure
in our region. Your article was entitled, “Marcy, the robotic
assistant never has a bad day.” This was the first generation robot that
Computer Motion developed.
Below is this first generation robot:
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In those early procedures in 1996, I harvested the left
internal mammary artery using the robot and then made a small incision and
performed a MIDCAB procedure. The newer generation robots are more complex
with two to three working ports, as opposed to the one port that I used in
1996. Currently, the FDA has allowed the use of the robot for harvesting the
internal mammary artery, but not for doing the bypass surgery. So, for now,
the surgeon would have to open the chest using conventional incisions to
perform coronary artery bypass surgery after harvesting the internal mammary
artery using the robot. |
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As you can see below, the newer generation robots have many
more arms and instruments. The surgeon doesn't even
stand at the operating table, but instead operates the robot
while sitting at a instrument panel at a distance. When
you look closely at these pictures below, ask yourself "Does
this really look better?"
It certainly isn't simpler:
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The FDA has, however, allowed the robot to be used for
mitral valve surgery. This technique is nearly identical to the Heartport
techniques. That is to say, the surgery is done through a small incision in
the right chest. In addition, an incision is made for a camera. Finally, two
or three additional incisions are made for the instruments used for exposing
the valve, retracting, holding sutures, etc. If they do not use the Heartport®
balloon "endoclamp" (inside the aorta) to stop the heart, then they are using a
conventional clamp (known as a Chitwood clamp, named after Randy Chitwood, a
North Carolina surgeon who recently developed the clamp). This clamp is
placed through yet another incision in the right chest used to directly clamp
the aorta (outside the aorta) in order to stop the heart. Keep in mind; all of
these incisions are made between the ribs.
Randy Chitwood is an interesting guy. He is one of the
leaders involved in minimally invasive heart surgery, including robotics.
However, he required coronary artery bypass surgery only a few years ago and
chose to have it done by the conventional approach!
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With this background, let me
summarize by telling you my philosophy on these new techniques:
I believe that as surgeons we need to continue to find
ways to lessen the pain of surgery and enhance recovery.
In many fields, such as general surgery and gynecology,
there has been great success with laparoscopic techniques which has been the
standard approach now for many procedures such as gallbladder removal,
appendectomy, and fertility procedures.
However, the abdomen is different than the chest. The
abdomen is soft and compliant. When the general surgeon performs laparoscopy,
carbon dioxide is instilled into the abdomen creating a tent with a clear view
of all of the internal structures. In addition, these internal structures do
not move. The gallbladder, appendix, and ovaries just sit there quietly.
The chest wall, on the other hand, is rigid, being guarded
by the ribs and the sternum. The chest surgeon cannot make the chest bigger by
instilling carbon dioxide. Therefore, the visualization of the organs is quite
limited. In fact, the heart sits right under the sternum (breast bone) making
it very difficult to work on through small lateral incisions. Special
breathing tubes must be placed to collapse the lungs just to see into the
chest. Most of all, everything is moving in the chest. The lungs are
breathing; the heart is beating and so on. In order to stop the lungs and
arrest the heart to do cardiac procedures through small incisions the
techniques are often a very complicated as reflected by the problems
encountered by Heartport®.
Will robotic surgery overcome these limitations in the
chest? Right now, that’s the 1.3 million dollar per machine question. I would
say that as always with new technology, I am cautiously optimistic; however,
the reality is that the technology at this point is still in its infancy. Its
advantage over conventional approaches is still yet to be proven. The fact
remains that we routinely perform large numbers of complex mitral valve
procedures without robots using conventional techniques with reproducible
results, short hospital stays, and rapid recovery.
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As far as the need to keep up with each
of the "latest-greatest" new technologies, I'm reminded of my favorite Ziggy
cartoon:
Yet, we must continue to
push the envelope and advance the science of surgery.
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Bobby
Kennedy said it best:
"Only
those who dare to fail greatly can ever achieve greatly."
--Robert F. Kennedy
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Last Modified
Tuesday, October 11, 2005 |
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