Doctors Hear Recommendations for Heart Care
in MD
Some 50 physicians and scientists gathered in Tucson, Ariz., in late
September for an MDA-sponsored meeting to pool their knowledge on
how to detect and treat the often devastating damage to the heart
that takes place in some forms of muscular dystrophy (MD).
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MDA
grantees Elizabeth McNally of the University of Chicago School
of Medicine and Jeffrey Towbin of Baylor College of Medicine
in Houston were co-chairs of MDAs Cardiomyopathy in Muscular
Dystrophy workshop. |
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The main cardiac problems in MD are cardiomyopathy (heart
muscle deterioration) the dilated (floppy) and hypertrophic (thickened) forms and conduction defects, abnormal signals
that lead to abnormal heart rates or rhythms.
Much of the discussion centered around molecular research and ideas
for gene transfer and use of cardiac repair cells, which have exciting
implications for the future (see full report).
But the audience was clearly impressed with the possibilities of the
cardiac care guidelines presented by Kate Bushby of the Institute
of Human Genetics in Newcastle upon Tyne, United Kingdom.
Bushby presented the decisions of 16 neuromuscular disease experts
who met in the Netherlands in June 2002 under the auspices of the
European Neuromuscular Centre. The meeting report is published in
full in the February issue of Neuromuscular Disorders. The experts
recommended the following steps for close monitoring and treatment
of heart defects in various MDs:
Duchenne MD (DMD)
echocardiogram (echo) and electrocardiogram (EKG) at diagnosis
cardiac investigations before any surgery and every two years
up to age 10; every year after age 10
assessment and treatment of respiratory dysfunction in parallel
with cardiac investigations
treatment with angiotensin-converting enzyme (ACE) inhibitors
with consideration of adding beta-blocker medications when abnormalities
progress
Becker MD (BMD)
echo and EKG at diagnosis
screening for cardiomyopathy at least every five years
treatment with ACE inhibitors and possibly beta blockers if
progressive abnormalities found
consideration of cardiac transplantation
Female Carriers of DMD & BMD
echo and EKG at diagnosis or after age 16 and every five years
thereafter; more frequent evaluations with test abnormalities or symptoms
treatment with ACE inhibitors if significant abnormalities detected,
with consideration of additional medications
consideration of cardiac transplantation
Type 1 Myotonic Dystrophy (MMD1)
annual EKG starting at diagnosis
monitoring with portable EKG recorder (Holter monitor) for
24 to 48 hours at diagnosis in adult patients
echo at diagnosis in congenital MMD
Holter monitoring if EKG shows increased risk of abnormally
slow heart rate; consideration of invasive measurement of cardiac
conduction
consideration of drugs to treat overly fast heart rate in atria
(upper cardiac chambers) but with caveat that these may worsen rate
irregularities in ventricles (lower chambers)
pacemaker insertion when progressive rhythm abnormalities detected
Congenital MD (CMD)
echo and EKG at diagnosis
echo prior to surgery or as symptoms suggest, except in merosin
gene form, in which cardiomyopathy generally isnt progressive
X-Linked Emery-Dreifuss MD (EDMD)
EKG at diagnosis and yearly thereafter, with follow-up by cardiologist
24- to 48-hour EKG (Holter monitoring) yearly, with particular
attention to detecting overly fast or overly slow heart rates; less
frequent echo
permanent pacemaker implantation when EKG shows abnormalities
of sinoatrial node (natural cardiac pacemaker) or atrioventricular
node (relay station from upper to lower chambers of heart)
consideration of invasive electrophysiology testing to help
determine pacemaker insertion site and mode of operation
with frequent atrial fibrillation (uncoordinated contractions
in upper chambers) or atrial standstill, consideration of anticoagulant
drug warfarin to prevent clots or strokes
Female Carriers of X-Linked EDMD
periodic EKGs to detect atrial or atrioventricular conduction
disease
Chromosome 1 EDMD
consideration of implantable defibrillator
with frequent atrial fibrillation or atrial standstill, consideration
of warfarin to prevent clots or strokes
Limb-Girdle MD 2C, 2D, 2E and 2F (Sarcoglycan-Deficient
LGMD)
same surveillance as for DMD or BMD for cardiomyopathy
periodic surveillance for abnormal heart rhythms with Holter
EKG or similar recording
treatment with ACE inhibitors with consideration of adding beta
blockers for cardiomyopathy
consideration of calcium antagonist medications to improve coronary
artery flow
consideration of cardiac transplantation
LGMD2I (Fukutin-Related-Protein-Deficient)
surveillance for cardiomyopathy as in DMD or BMD
treatment with ACE inhibitors with consideration of adding beta
blockers
consideration of cardiac transplantation
LGMD1B (Lamin A/C-Related)
consideration of implantable defibrillator
with frequent atrial fibrillation or atrial standstill, consideration
of warfarin to prevent clots or strokes
Facioscapulohumeral MD (FSHD)
EKG and echo at diagnosis, with follow-up dictated by clinical
picture
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The heartbeat
is normally set by the sinoatrial node, which sends impulses
to the atrio- ventricular node. From there, theyre conducted
to the ventricles. This process is frequently abnormal in type
1 myotonic dystrophy, both forms of Emery-Dreifuss dystrophy,
and the chromosome 1 form of limb-girdle dystrophy. |
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New Clues May Lead to New Tests in FSH Dystrophy
Much progress has been made in identifying the unusual genetic flaw
that causes facioscapulohumeral muscular dystrophy (FSHD),
but each discovery seems to lead to new mysteries.
Last year, MDA-supported researchers found that a small deleted section
of chromosome 4 prevents a cellular "braking mechanism"
from operating properly (see "Research
Updates," August 2002). The absence of this section causes
one or more nearby genes to be inappropriately activated when they
should be silent, researchers believe.
Although most people with FSHD have this deletion, a minority of
people with the disease test negative for the deletion.
Recently, a group including MDA grantee Silvere van der Maarel, a
molecular biologist at the Center for Human and Clinical Genetics
at Leiden University Medical Center in the Netherlands, found clues
that may explain the negative tests, publishing its results in the
July 22 issue of Neurology. The researchers found that the deleted
section of chromosome 4 in FSHD-affected members of three unrelated
families was too large to be identified by the current test. They
described a method of testing that can detect the larger deletions
as well as the smaller ones. Van der Maarel says he believes this
type of testing should be available in major diagnostic centers within
the next year or so.
Surprisingly, they also found that a gene previously thought to be
inappropriately activated in FSHD was part of the deleted section
in two of the families. The absence of that gene told the investigators
that it couldnt have been wrongly switched on, so its been eliminated
as a possible culprit in FSHD causation.
The investigators suggest that the identification of other large
deletions on chromosome 4 may allow them to eliminate other genes
in the region, narrowing the search for the cause of FSHD muscle degeneration.
New MG Drug Now in Biotech Pipeline
Ester Neurosciences, a biotechnology company in Herzliya, Israel,
announced in June that its new compound, EN101, aimed at myasthenia
gravis (MG) had done well in preliminary testing in 16 people
and would undergo further studies in Israel.
The drug is designed to have effects similar to those of the commonly
used pyridostigmine (Mestinon), which indirectly increases levels
of acetylcholine, the chemical transmitter of nerve-to-muscle signals.
Having more acetylcholine at the nerve-to-muscle junction generally
improves strength in people with MG and other forms of myasthenia.
Pyridostigmine accomplishes an acetylcholine increase by interfering
with an enzyme that normally breaks down the chemical. EN101 targets
the same system but at a different point, says Irene Zeitoun, director
of Research and Development at Ester Neurosciences.
EN101 takes aim against the genetic instructions for the breakdown
enzyme instead of the enzyme itself, allowing for a more specific
action, she says. The new compound also keeps the body from thwarting
the increase in acetylcholine, something that can happen with current
medications.
EN101, like pyridostigmine, can be taken by mouth. The company says
its exploring other potential applications for the compound, such
as treating Lambert-Eaton syndrome, a myasthenic disorder in
which acetylcholine isnt released properly from nerve fibers.
For more information go to www.esterneuro.com.
Blocking Waste Disposal Restores Dystrophin
in Mice
MDA grantee Michael Lisanti of the Department of Molecular Pharmacology
at Albert Einstein College of Medicine in New York was part of a U.S.
and Italian research team that recently found that blocking a cellular
waste disposal mechanism could be a way to save muscle cells in Duchenne
muscular dystrophy (DMD). In this form of MD, the muscle protein
dystrophin is missing from the muscle cell membrane, causing the membrane
to become fragile and muscle cells to degenerate.
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Saving
partially functional dystrophin is the goal of Lisantis research
group. Left to right are Federica Sotgia, Michael Lisanti and
Gloria Bonuccelli. |
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In experiments with mice that make a very small dystrophin fragment
(as do many people with DMD), Lisanti and colleagues found that blocking
the function of cellular garbage disposal units called proteasomes apparently allowed the cells to save and use the small dystrophin
fragments. They published their findings in the October issue of the
American Journal of Pathology.
Instead of sending these fragments to the waste disposal units (probably
the usual procedure in DMD-affected cells), the cells of the treated
mice apparently routed them to the membrane. Once the dystrophin pieces
were in the cell membrane, other proteins lined up properly there
as well, restoring the membranes strength.
The authors say the findings suggest a new route of therapy for DMD.
"Using an inhibitor of the proteasomal pathway, we could effectively
block the degradation of dystrophin and of dystrophin-associated proteins,
and we could ameliorate myopathic changes normally seen in the skeletal
muscle fibers of mdx [dystrophin-deficient] mice," they wrote.
The researchers used a compound thats only available for laboratory
research, but Lisanti says theres a drug used in cancer treatment
that could be considered for a future clinical trial. An important
consideration is the potential toxicity of disabling the cells main
disposal and recycling system.
Normal
Muscle Cell |
DMD-Affected
Muscle Cell |
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Muscle
Cell Treated With Proteasome Blocker |
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Blocking
cellular garbage disposal units allowed small dystrophin fragments
to take their place near the cell membrane. |
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Swedish Researchers Target T-Cells in Inclusion-Body
Myositis
Investigators in Sweden say a specific type of immunoglobulin therapy
may be beneficial in people with inclusion-body myositis (IBM),
based on results of a small pilot study they conducted.
Christopher Lindberg and colleagues at Sahlgrenska University Hospital
in Gothenburg found small increases in muscle strength in people with
IBM who received a week of intravenous treatment with an immunoglobulin
directed against certain cells in their immune systems and then a
years treatment with oral methotrexate, a medication that suppresses
the immune system.
The comparison group, which received methotrexate alone, showed a
decrease in strength over the same period.
Laboratory evaluations also suggested some benefit from the specific
immunoglobulin treatment compared with methotrexate alone.
This immunoglobulin was directed against the CD3 type of T-cell,
which is thought to be involved in a misguided attack on muscle tissue
in IBM. The anti-T-cell treatment is a refinement of the mixed immunoglobulin
infusions that have been used in IBM and other disorders.
So far, no treatment has been found to have more than very small
or inconsistent benefits in IBM, including mixed immunoglobulin therapy.
The study was small, and the investigators advise further studies
using this therapy.
Oxidative Damage Found in Duchenne, Becker
MDs, Not in Myotonic Dystrophy
MDA-supported researchers at McMaster University Medical Center in
Hamilton, Ontario, have found that people with Duchenne and Becker
muscular dystrophies (DMD and BMD) show signs of oxidative
stress, a type of cellular damage, in their muscles.
This type of damage results from an excess of oxygen-containing chemicals
carrying an electrical charge that can harm cell membranes, DNA and
other cellular structures. These chemicals, called free radicals,
are natural byproducts of certain cell activities, but checks and
balances normally keep their levels low.
In contrast, the researchers found that people with type 1 myotonic
dystrophy (MMD1) didnt show signs of this type of damage, though
lab experiments in cells had indicated they might.
Oxidative stress was assessed by measuring the ratio of a compound
called 8-OhdG to the chemical creatinine in the participants
urine. In subjects with DMD and BMD, this ratio was 48 percent above
normal; in people with MMD, it wasnt elevated.
In the paper, published May 1 in Free Radical Biology & Medicine,
the authors say the presence of free radicals and oxidative damage
in skeletal muscle may increase the destruction caused by the primary
muscle defect in diseases like DMD and BMD. (The primary problem in
these diseases is a lack of the muscle protein dystrophin.)
The study supports the idea that nutritional supplements with antioxidant
properties could be beneficial in preserving muscle in these disorders.
MDA grantee Mark Tarnopolsky at McMaster, an author of this report,
is studying the use of nutritional supplements in the treatment of
DMD, BMD and MMD.
New Prenatal Test Resembles Pap Smear
Scientists at the Australian Genome Research Facility in Brisbane
say theyve developed a simpler, less expensive and less risky form
of prenatal testing for genetic disorders that could make such procedures
available to more prospective parents.
Investigators Ian Findlay and Darryl Irwin, who announced their findings
in July at the International Congress of Genetics in Melbourne, say
the new test takes fetal cells from a pregnant woman in much the same
way that cells are obtained in the widely performed Pap test, which
screens women for signs of cancer. (Pap tests are performed by swabbing
or brushing the entrance to the uterus, or cervix, and placing the
cells on a slide or in a special solution.)
Findlay and Irwin say they can isolate fetal cells from the Pap smear
of a pregnant woman and then screen them for a range of genetic disorders.
Current prenatal tests involve taking samples from one of the uterine
membranes (chorionic villus testing) or from the fluid surrounding
the fetus (amniocentesis). Both tests have to be performed by specialists,
pose a small risk to mother and child, and are expensive.
The new Pap-type prenatal test has been performed on samples from
600 women who were between five and 35 weeks pregnant. The researchers
say the test can be performed when the pregnancy is five weeks along
and results can be obtained the same day.
Theyre continuing to evaluate the test in clinical trials and hope
it will be on the market in two to three years.
Boys With Duchenne MD Wish for Fun Stuff,
Pets
"If you could make three wishes, any three wishes in the whole
world, what would they be?"
Thats what neuropsychologist Veronica Hinton, an MDA grantee at
Columbia University in New York, and her colleague Nancy Nereo, a
clinical psychologist at the University of California in San Diego,
asked 74 boys with Duchenne muscular dystrophy (DMD), 32 of
their siblings and a comparison group of 43 boys without any illness
in the family. The children were between 6 and 12 years old.
The investigators, who published their results in the April issue
of the Journal of Developmental and Behavioral Pediatrics, found to
their surprise that the boys with DMD were no more likely to make
health-related wishes than were boys in the comparison group. (Interestingly,
their siblings were more likely to make this type of wish, sometimes
specifically in relation to the affected brothers illness.)
Among the most common wishes of the children in all three groups
were desires for material things, such as toys, candy or a swimming
pool, and the wish for a pet. The boys with DMD often wished for a
realistic fun activity, such as going to a restaurant.
Boys with no family illness commonly stated a long-term goal, such
as a certain type of profession or education. This wish, however,
wasnt common for boys with DMD or their siblings, suggesting to the
researchers that avoidance of the future might reflect a difference
in the DMD-affected families.
"While boys with DMD do not appear to be more concerned with
health issues than their siblings or comparison boys," Nereo
says, "there were differences in their wishes that might reflect
a subtle shift in their perspective. For example, boys with DMD made
fewer future or goal-oriented wishes, suggesting an adaptive way of
responding to their illness; that is, by focusing on the here and
now."
Their siblings appear to have also experienced this shift in perspective.
Childrens Behavior Top Cause of Mothers
Stress
Stress in mothers of children with Duchenne muscular dystrophy
(DMD) is more closely related to problem behavior in their children
than to the familys socioeconomic status, single parenthood or even
the childs level of physical disability, says a study in the October-November
issue of the Journal of Pediatric Psychology.
Neuropsychologist and MDA grantee Veronica Hinton at Columbia University
in New York was the principal investigator. Hinton and her colleagues
studied 127 mothers of boys with DMD and compared their stress with
that of mothers of children with cerebral palsy and mothers of children
without any illness.
They found maternal stress was more likely to be caused by child
behavior related to poor social skills in the DMD-affected families,
while it was more likely to be from other causes in the other two
groups.
Based on their previous research, the authors of the study suggest
that boys with DMD may experience delayed maturation and late development
of certain social skills because of some differences in their cognitive
development compared with that of other children. (See "When
Neuromuscular Disease Affects the Brain," December 2002.)
When 28 families were surveyed again after two and then four years
had passed, the researchers found that maternal stress had diminished,
even though the childrens DMD had progressed. The investigators say
this could be because the mothers learned to cope better with their
situations, or that the boys may have matured and developed better
social skills. (They also admit that the families who consented to
the long-term follow-up may have been those who were coping the best.)
The researchers note that, based on these preliminary findings, social
services that target problem behavior and deficient social skills
in children might be more helpful to DMD-affected families than more
general types of support programs. They say the issue warrants further
investigation.
Genzyme Expands Myozyme Program in Pompes
Genzyme, a biotechnology firm based in Cambridge, Mass., announced
in September that it plans to launch a program that would allow access
to Myozyme, its experimental treatment for Pompes disease (acid
maltase deficiency), for severely ill patients who arent eligible
to participate in the companys clinical trials of Myozyme. (See "Research
Updates," September-October 2003.)
Myozyme is Genzymes trademarked name for a laboratory-engineered
enzyme that acts like acid maltase (also known as acid alpha-glucosidase)
and seems to compensate for the lack of acid maltase in Pompes disease
patients. Acid maltase normally breaks down stored sugar in cells.
In addition, Genzyme says it will launch a disease registry to study
the natural history, outcomes and management of Pompes disease. Those
with the disease can participate in the registry through their physicians.
The company will also study the natural course of late-onset Pompes
disease in approximately 60 people with mild to intermediate symptoms
and will then use these data to begin a trial of Myozyme in some adult
study participants in 2004.
For more information, contact Genzymes Medical Information Department
at medinfo@genzyme.com or
(800) 745-4447. MDAs Web site at www.mda.org will post information about these trials, the disease registry and
the access program as they become available. Check "Clinical
Trials" (under "Research") and "News."
Study to Probe Service Dog Use
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Occupational therapist Diane Collins with Greg Traynor
and his dog, Nala, in Pittsburgh
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The Veterans Affairs Research & Development Center of Excellence
for Wheelchairs and Related Technology and the University of Pittsburgh
are conducting a study to examine how service dogs affect wheelchair
users lives. You dont have to have a service dog to participate.
The researchers are looking for people who are at least 18 years
old; use a wheelchair or scooter for at least 75 percent of their
mobility; and either own a service dog, are on a waiting list to receive
a service dog, or arent interested in a service dog.
The study, which follows a similar one (see "Research
Updates," May-June 2003), requires completion of mailed or
telephoned questionnaires. These ask about the participants disability,
socioeconomic status, health care, life satisfaction, social life,
daily activities and pets. Participants are paid $20 for each questionnaire
they complete.
Contact Shirley Fitzgerald at (412) 365-4840 (Pittsburgh) or Diane
Collins at (412) 365-4844; or send e-mail to dmcst84@pitt.edu.
