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Hypoplastic Left Heart Syndrome (HLHS) This page is dedicated to those affected by HLHS and my friend's son Thomas David Moore
The heart consists of four chambers: the two upper chambers, called
atria, where blood enters the heart; and the two lower chambers, called
ventricles, where blood is pumped out of the heart. The flow between
the chambers is controlled by a set of valves  that act as one-way doors.
...in
a healthy heart, oxygen-poor (blue) blood returns to the right atrium
from the body, travels to the right ventricle, then is pumped through
the pulmonary artery into the lungs where it receives oxygen.
Oxygen-rich (red) blood returns to the left atrium from the lungs,
passes into the left ventricle, and then is pumped out to the body
through the aorta.
With Hypoplastic Left Heart Syndrome, the left
side of the heart (the part that pumps oxygenated blood to the rest of
the body) is underdeveloped. The degree of underdevelopment differs
from child to child.
The structures affected usually include the following:
Mitral valve - The valve that controls blood flow between the left atrium and left ventricle in the heart.
Left
ventricle - The lower left-hand chamber of the heart. It receives
oxygen-rich (red) blood from the left atrium and pumps it into the
aorta, which takes the blood to the body. The left ventricle must be
strong and muscular in order to pump enough blood to the body to meet
its requirements. When the chamber is small and poorly developed, it
will not function effectively and cannot provide enough blood flow to
meet the body's needs.
Aortic valve - The valve that regulates blood flow from the heart into the aorta.
Aorta - The largest artery in the body and the primary blood vessel leading from the heart to the body.
Hypoplastic
left heart syndrome occurs in up to four out of every 10,000 live
births. The syndrome comprises 8 percent of all cases of congenital
heart disease. It is one of the top three heart abnormalities to cause
problems in the newborn. HLHS occurs slightly more often in boys (55%
-70%) than in girls. In many children, HLHS occurs by chance, with no
clear reason evident for the underdevelopment. However, the rate of
occurance is increased in patients with Turner, Noonan,
Smith-Lemli-Opitz or Holt-Oram Syndromes. Certain chromosomal
duplications, translocations and deletions have been associated with
HLHS, but not in most cases.
Babies with this condition may
appear normal at birth. Fetuses are nourished by oxygen-rich blood from
their mothers so they don't breathe and don't use their lungs. Babies
with hypoplastic left heart syndrome may seem normal at birth because
the patent ductus arteriosus (a blood vessel that connects the
pulmonary artery to the aorta, thereby bypassing the lungs and the
defective left side of the heart.) is still open, allowing blood to
continue circulating directly into the aorta and out to the rest of the
body. Once the ductus closes a few days after birth, blood flows to the
lungs and then to the left side of the heart where it is blocked and
can't circulate through the rest of the body. It is at this time that
these babies show symptoms.
The following are the most common symptoms of hypoplastic left heart syndrome:
- cyanosis (blue color of the skin, lips and nailbeds)
- pale skin
- sweaty or clammy skin
- cool skin
- heavy and/or rapid breathing
- fast heart rate
- difficulty feeding
(As
these symptoms may resemble other medical conditions and heart
problems. Always consult your child's physician for a diagnosis.)
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ How is hypoplastic left heart syndrome diagnosed?
Your
child's physician may have heard a heart murmur during a physical
examination and referred your child to a pediatric cardiologist for a
diagnosis. A heart murmur is simply a noise caused by the turbulence of
blood flowing through a narrow region. Symptoms your child experiences
also will help with the diagnosis.
A pediatric cardiologist
specializes in the diagnosis and medical management of congenital heart
defects, as well as heart problems that may develop later in childhood.
The cardiologist will perform a physical examination, listening to the
heart and lungs, and make other observations that help in the
diagnosis. Other tests are needed to help with the diagnosis.
Chest
X-ray — A diagnostic test which uses invisible electromagnetic energy
beams to produce images of internal tissues, bones and organs onto film.
Electrocardiogram
(ECG or EKG) — A test that records the electrical activity of the
heart, shows abnormal rhythms (arrhythmias or dysrhythmias) and detects
heart muscle damage.
Echocardiogram (echo) — A procedure that
evaluates the structure and function of the heart by using sound waves,
recorded on an electronic sensor, that produce a moving picture of the
heart and heart valves.
Cardiac Catheterization — A procedure
that gives function and information about the structure inside the
heart. Under sedation, a small, thin, flexible tube (catheter) is
inserted into a blood vessel in the groin and guided to the inside of
the heart. Blood pressure and oxygen measurements are taken in the four
chambers of the heart, as well as in the pulmonary artery and aorta.
Contrast dye also is injected to more clearly visualize the structures
inside the heart.
Cardiac Magnetic Resonance Imaging (MRI) — A
non-invasive test that uses magnets and radio waves to make pictures of
structures and blood flow inside the body.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
What are the treatments for hypoplastic left heart syndrome?
HLHS is fatal unless treated. While there are treatments, HLHS is NOT CORRECTABLE!
Specific treatment for hypoplastic left heart syndrome will be determined by your child's physician based on the following:
- your child's age, overall health and medical history
- extent of the disease
- your child's tolerance for specific medications, procedures or therapies
- how your child's doctor expects the disease will progress
- your opinion or preference
Your
child most likely will be admitted to the intensive care unit (ICU) or
special care nursery once symptoms are noted. Initially, your child may
be placed on oxygen, or a ventilator to assist his/her breathing.
Intravenous (IV) medications (including prostaglandins which prevent
the ductus from closing) may be given to help the heart beat stronger
and lungs function more efficiently.
Three options may be presented to you:
Comfort
Care - includes the process of relieving pain and suffering, and
controlling debilitating symptoms, while not preventing the patient
from dying
Surgical Repair - consists of 3 open heart surgeries
that will result in the body using one good right ventricle to do the
work normally done by 2 ventricles. The goal is to separate blue and
red blood circulation. Because blood vessels of the lungs change over
the first year of life, the surgery must be performed in stages. A
successful Fontan (final stage) requires sufficient and easy blood flow
through the lungs so as not to require the force of the missing
ventricle to pump the blood. This is not possible in the first months
of life and therefore 2 procedures (stages) must be performed until the
lungs are matured and ready.
STAGE 1 - Norwood
This surgery
is preferrably performed in the first week of life. A repair is made to
allow the right ventricle to pump blood to both the lungs and the body.
Because blood flow must be forceful for the immature lungs, the surgeon
creates a tube from a branch of the aorta to the pulmonary artery known
as the modified Blalock-Taussing shunt. The baby will still appear blue
(cyanotic) after this surgery.
STAGE 2 - bi-directional Glenn or Hemi-Fontan
This
surgery is preferrable performed at about 6 months of life when the
blood starts to flow more easily and the vewntricular force is not
needed. The surgeon creates a direct connection between the superior
vena cava and the pulmonary artery thus diverting half of the blood
flow without the assistance of ventricular force. This reduces the work
on the right ventricle by allowing it to only pump blood to the body
and allowing all blood from the upper body to the lungs.
STAGE 3 - Fontan
This
surgery is preferrably performed between 18 - 48 months. The surgeon
connects the inferior vena cava to the pulmonary artery. This will
allow the remaining blood coming back from the body to go directly to
the lungs. The final result will be no mixing of blood in the heart
with more oxygen rich blood going to the body. This will significantly
improve the child's health and growth.
Heart Transplant - First
an infant must be placed on a transplant list. Then, the infant will
remain on prostaglandins to keep the ductus open until a donor heart
becomes available. After the successful transplant, the recipient will
be required to remain on anti-rejection medications for life.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
HLHS
requires a life time of follow up care. Most HLHS pateients will
require heart medications for life. They are at a high risk of heart
valve infection (endocarditis) and require antibiotics before dental
work and most surgeries. At this time, life expectancy is relatively
unknown. 70% of infants who survive heart transplant or the Fontan will
survive to the age of 5.
**Recent studies report
neurodevelopmental disabilities in a significant number of HLHS
patients (both those with surgical repair and heart transplants)
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
~NOTES OF INTEREST~
*In 1979, the first surgical palliation was performed on a newborn.
**HLHS
can be easily detected on fetal echocardiography. However, many cases
are not diagnosed because the pregnancy is typically uncomplicated and
the fetus grows and develops normally because fetal circulation is
provided by the mother. As well, little concentration is spent on
cardiac anatomy during routine exams.
During cardiac
development, adequate blood flow through a structure is responsible for
growth of that structure. Because of aortic and mitral valve artresia
(narrowing), little or no blood flow goes to the left ventricale and
therefore, it does not grow.
Recent research suggests that if
the narrowing is discovered early enough, a balloon can be inserted
in-utero to allow proper blood flow which will allow the left ventricle
to develop. Actually, this procedure has been performed and the baby
was indeed born with a functioning left heart! As well, this form of
surgical repair leaves little to no scarring. Over 100 of these
procedures have been performed. The oldest survivor is 4 years old!
To view an in-utero surgery for HLHS, go to:
www.youtube.com/watch?v=vBQnRtsLVVA
***Another
theory suggests that HLHS is caused by a premature closure or absence
of the foramen ovale. This would eliminate fetal blood flow from the
inferior vena cava to the left atrium thus resulting in
underdevelopment.
Thanks to Vanessa at CHD Heart Foundation for writing this article.Disclaimer: The
facts and opinions shown on this blog are as accurate and up to date as
possible, but are provided as general "information resources", which
may not be relevant to individual persons. This blog is not a
substitute for individual assessment and always take advice from a
doctor who is familiar with the particular person..
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