Artificial Heart Valves
Claire
Carson, Julia Richman, and Robin Creel present
Group
30's Web Project for
Mr. Deardorff's
Physics 24 lecture
December
4, 2000
Artificial Heart Valves
Claire
Carson, Julia Richman, and Robin Creel present
Group
30's Web Project for
Mr. Deardorff's
Physics 24 lecture
December
4, 2000
Through
this project we hope to shed some light upon the human heart valves, the
causes of some irregularities in their function, and the devices man has
strived to perfect to repair the heart's proper functioning. For
over half a century, doctors and scientists have been working diligently
to create the best funtioning artificial heart valve, and they have nearly
completed their task. In their trials of experimentation, doctors
have discovered the immense complexity of the physics within our own heart,
and their task of creating the perfect articial heart valve has taught
them an even greater appreciation of the intricate inner-workings of the
human body.
Anatomy:
The heart consists of four chambers. The upper two are the right
and left atria; the lower two, the right and left ventricles. In
a healthy body, deoxygenated blood is pumped from the body through the
right atria and ventricle to the lungs. From the lungs, oxygenated
blood flows through the left atria and ventricle. The blood then leaves
the heart via the aorta, and the cycle continues. Each chamber has
a sort of one-way portal, the valve, at its exit that prevents blood from
flowing backward. There are four
valves**
in the heart; the tricuspid and bicuspid (mitral) valves separate
the right and left ventricles respectively. The semilunar (also called
the pulmonary and aortic) valves precede the entry into the lungs and body
(via the aorta) respectively. If these valves do not function appropriately,
many complications can occur.
Physiology:
Cardiac valves have three functional properties: (1) preventing regurgitation
of blood flow from one chamber to another, (2) permitting rapid flow without
imposing resistance on that flow, and (3) withstanding high-pressure loads.
These valves work by a several principles related to physics. However,
this discussion is limited to pressure gradients. Fluid flows from
areas of high pressure to areas of low pressure. In the heart the
valves open and close in response to pressure gradients, i.e., valves open
when pressure in the preceding chamber is higher and close when the gradient
reverses. These one-way valves are important in ensuring that the
blood flows in the proper direction. One “heart beat” consists of
two phases, the diastolic and the systolic. During the diastolic
phase the heart muscles are “relaxed” and blood flows into the chambers
from the body and lungs. The tricuspid and the bicuspid valves are
open at this time, allowing the atria and ventricles to fill with blood
(the pulmonary and aortic valves are closed during diastole). The
heart then contracts during the systolic phase and pumps blood into the
lungs and body. At this time the pulmonary and aortic valves open
and the tricuspid and bicuspid valves “snap” shut.
Physics:
An example of how pressure gradients work in the heart is as follows:
at the beginning of systole the goal is to raise the pressure within the
ventricle chambers. As previously described, two things cause the
sharp rise in pressure: the contraction of the ventricle itself,
and the fact that for a brief moment all four valves are closed.
Thus, the contracting muscles elevate ventricular pressure without a change
in volume. This moment of contraction is termed isovolumetric, meaning
“maintenance of a constant volume.” At the point that the pressure
inside the ventricles exceeds the diastolic pressure within the preceding
tract, the aortic and pulmonary valves open and ejection begins.
In this case ejection is the movement of the blood out of the ventricles
into the lungs and body. Initially during ejection the left ventricular
pressure rises above that of the aorta and produces a very rapid flow.
Later in ejection, ventricular pressure drops below aortic pressure, resulting
in a diminished velocity of outflow. (Specific values for intracardiac
pressures are not discussed here for simplicity’s sake).
(Note: for a review
of heart anatomy, go to: www.howstuffworks.com/heart.htm).
**Image
from MedFacts.com
Valvular heart disease (VHD), a non-specific, all-encompassing name for
various diseases affecting the heart valves, can be classified into two
categories: congenital and acquired. Congenital valvular heart disease
is present from birth, and occurrs in about 0.6% of non-premature live
births. It can be caused by chromosomal abnormalities, such as trisomy
18 or trisomy 21 (known as Down syndrome). In most cases, however,
the causes of congenital valvular disease are unclear.
Acquired valvular heart disease is much more common than congential VHD.
Acquired VHD is generally caused by a disease or injury to the heart, which
affects the individual at some point in their lifetime. An autoimmune
disease related to the streptococcus virus, acute rheumatic fever is a
serious illness which can cause forms of VHD such as valvular stenosis
(hardening of the valves). Other cases of VHD include tumors of the
heart muscle, injury to the chest, lupus, and many others.
There are two main types of faulty valves that may or may not require valvular
replacement surgery. There are valves which do not close properly
and leak blood into another quadrant of the heart (regurgitation) and valves
which are hardened and don’t open properly (stenosis). Valvular regurgitation
causes the heart to work less efficiently because it has to pump some blood
twice, and usually results in an enlargement of the heart chambers because
there is more blood to pump to compensate for the leaking blood.
However, in severe cases the heart is not strong enough to compensate for
the efficiency loss and it results in congestive heart failure. Valvular
stenosis causes higher blood pressure in the heart because blood builds
up behind the closed valve and forces the cardiac muscle to work harder
to pump the higher-pressure blood through the heart. The heart usually
compensates by growing a thicker layer of muscle. In extreme VHD
cases, valvular replacement surgery is becoming an extremely feasible option.
Both mechanical and biosynthetic valves are used, and prognosis of surgical
patients is fairly good (see chart below).
(Data from Fundamentals of Anatomy and Physiology Applications Manual
by Frederic H. Martini and
Kathleen Welch, Prentice Hall 1998)
Brief
History of Prosthetic Heart Valves:
In 1952, Charles Hufnagel used the first artificial heart valve, an acrylic
ball valve, to correct aortic incompetence. This procedure was rarely
performed until the heart-lung machine was created in 1953, when surgeons
were first able to perform open-heart surgery under direct vision.
Several forms of the ball valve were created and used in valvular replacement,
but were phased out starting in 1965 when the first disk valve was created
by Kay and Donald Shiley. This valve was thought to encompass traits
that the ball valve did not possess, but it too had problems with blood
pressure fall (poor hemodynamics) inside the heart. Doctors then
turned to tissue replacement valves, using human pericardium and fascia
lata over a synthetic form, but these valves failed after a period of approximately
five years because of insufficiency and calcification of the tissue.
A Japanese surgeon invented a second form of the disk valve, this time
with a tilting disk that hindered falls in blood pressure. This new
valve tended to wear out too quickly, and in 1969 a tilting disk valve
with a floating disk made of Delrin was created that lasted much
longer than its predecessor. In 1971, the Delrin disk was
replaced with a disk of carbon pyrolite when it was discovered that the
carbon pyrolite disk would not react with the blood and become swollen
and immobile inside the valve the way that the Delrin disk had.
In 1976, the carbon pyrolite disk was given a convexoconcave shape, giving
it an aerodynamic form that allowed the valve to open and close quicker
and with less space for blood to leak through. In 1977, the bileaflet
valve, termed the "St. Jude Cardiac Valve Prosthesis," was introduced.
This valve consisted of two disks rather than one, and was more capable
of controlling blood flow and resisting blood clotting and bacterial infection
than the previous designs. This final design, with minor alterations
to its composition, has been used with a high degree of success since its
advent. In addition to the bileaflet valve, porcine and bovine tissue
valves (biosynthetic valves) are now used in valvular replacement when
the situation calls for a more delicate replacement valve.
Hemodynamics:
Physicians look for three main criteria
when assessing the hemodynamic performance (proper blood flow) of a particular
valve design. The valve in question should (1) function efficiently
and present the minimum load to the heart, (2) be durable and maintain
its efficiency for the patient's entire lifespan, and (3) not cause
damage to molecular or cellular blood components or stimulate thrombus
formation (blood clotting). In addition to these criteria, good hemodynamics
ensures that the valve will hold the blood in the heart quadrant between
heartbeats, and release the blood upon heartbeat without leaking in either
case. The valve must respond to the appropriate pressure gradients
in order to open and release blood at the right moment. If there
is a drop in the body's blood pressure, the valves are responsible for
holding blood in the ventricle until the pressure has reached a level great
enough to restore appropriate pressure to the vessels. As you can
see, a great deal of skill is involved in prosthetic valve design.
What
They are Made of:
-Mechanical
Valves
Mechanical valves are synthetic valves that come in a variety of materials
and forms. Two of the most popular varieties are the Ball Valve and
the Disk Valve.
Ball
Valves*
When the first ball valves were designed, doctors were primarily concerned
with securing the structure in place and preventing thrombosis from
occurring. They knew that all the materials selected would have to
be biocompatible--that is, they would not react negatively with the antibodies
present in humans. The materials they selected ranged from Teflon
cloth for the sewing ring and silicone rubber for the occluder ball, to
stainless steel, solid Teflon, and Lucite for the cage components.
The first ball valve implanted in a human had a cage constructed entirely
of Lucite, with a ball made of a solid Silastic sphere rather than a stainless
steel ball coated with rubber, as was previously done in animal testing.
This model had a problem with thrombosis, and the patients died of related
complications. Other models had a stainless steel cage covered with
a Teflon cloth and a Silastic sphere for a ball, but thrombosis occured
with this model as well.
One of the final versions of the ball valve was the Smeloff-Cutter valve
(shown), which was contructed of a commercially pure titanium cage in a
bare, uncoated nature. This cage had a nonoverlapping, full-orifice
with a ball constructed of silicone rubber. The design of this valve
permitted slight regurgitation of blood that would, in effect, wash the
ball and cage, preventing thrombosis. The Smeloff-Cutter valve enjoyed
over a decade of success in valvular replacement with an established record
of durability.
-Disk Valves
The first disk valve used in human valvular replacement occurred in 1965,
but it was not until the advent of the tilting disk valve with a floating
disk that any major success occurred, putting the disk valve ahead of the
ball valve in terms of the longevity of the patients and lack of complications
with the valves.
-Single Leaflet Disk Valves*
The large size of the ball valve was thought to be associated with certain
deaths--deaths that were the result of irritation of the ventricular cavity
at the hands of the ball valve's large cage. This lead scientists
to develop a valve with a smaller cage, which would thusly require a smaller
ball, or rather a disk. The first disk valves resembled a shallow
ball valve with a disk in place of the ball (shown), where the disk simply
moved up and down with the heartbeat to open or occlude the valve.
Like the ball valves, these original disk valves lacked optimal hemodynamics,
the ability to properly control blood flow. Other designs followed,
having disks oriented on an angle to optimize hemodynamics, and having
a floating disk that prevented wear along the axis of attachment.
The many versions of the tilting disk valve have been popular for decades
because of their ability to prevent periprosthetic leak, endocarditis,
and thrombosis, among other complications.
-Bileaflet
Disk Valves*
The bileaflet design first introduced in 1977 has been heralded for its
success. The design (using two disks, a hinge mechanism, and a low
profile) was found to be very durable when constructed of an apporpriate
material (usually carbon pyrolite) and has enjoyed low thrombogenicity
and superior hemodynamics. Of the half-dozen or so varieties of the
bileaflet valve, the St. Jude prosthesis (shown) has been used most often
in mitral and aortic valve replacements. Of the three varieties of
the St. Jude prostheses, all are constructed of carbon pyrolite, and have
recently been fitted with a circular metallic ring below the polyester
sewing ring for aid in x-ray visibility.
-Tissue
Valves (Biosynthetic Valves)
Tissue valves are classified in two varieties based on what type of tissue
is used. They can either consist of human tissue or animal tissue
-Human Tissue Valves (Homographs, Autographs)
Cognizant of the problems with the ball valves, doctors in the 1960s turned
to the idea of homographs (or allographs) in which the patient receives
a replacement heart valve from a deceased donor. The donated valve
is frozen in liquid nitrogen until time for surgery, when the valve must
be thawed for 24 hours before transplantation. Because the delicate
nature of the valve, surgeons must be careful to ensure the valve is the
proper size and to take the utmost care during surgery, since it is harder
to install than all other forms of tissue valves.
In an autograph tissue valve, the tissue is from the body of the patient
receiving the valve replacement. The surgeon can take tissue from
a variety of regions, including, but not limited to, the dura mater, pericardium,
fascia lata, peritoneum, and vena cava. The tissue is then attached
to a synthetic frame, usually of stainless steel, which gives the structure
a stronger form and is therefore easier to transplant than a homograph.
-Animal Tissue Valves (Xenographs, Heterographs)
Unlike homographs and autographs, the terms xenograph and heterograph are
used interchangeably. Both refer to animal tissue implants by coining
them either "foreign" or "different." The animal tissue chosen for
human valvular prosthesis is porcine or bovine. In certainporcine
implants*,
the pig valve is attached to a steel frame (called a stent), giving the
tissue shape, and the stent is then covered with a Dacron cloth.
Other porcine valves are transplanted without a stent, with the theory
that the stent and the sewing cloth decrease the hemodynamics of the valve.
Another xenographic tissue implant comes from bovine pericardium, where
the tissue is attached to a Dacron covered titanium stent.
Bovine
pericardium valves*
exhibit non-thrombogenic properties and excellent hemodynamic traits, and
have begun to replace mechanical valves and porcine valves used for the
same purpose.
*link
to Cedars Sinai Medical Center
Science has come very close to designing artificial valves that function
like healthy cardiac valves, however the ideal heart valve still does not
exist.
Links to Other Sites on Valvular Prosthesis:
Medical Carbon Research Institute, LLC
St. Jude Medical
Sulzer Carbomedics, Inc.
Vi Vitro Systems
Some Interesting
Links (used as references):
http://www.heartpoint.com/valvularheartdxmore.html
http://www.allina.com/Allina_Journal/Fall1996/rose.html
www.prenhall.com/martini/fap
