Offer Prednisone for DMD, Neurology Group Says
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Side effects of prednisone can include weight gain and a Cushingoid face. |
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On Jan. 10, the American Academy of Neurology (AAN) released its
long-awaited report on the use of corticosteroids (prednisone or deflazacort)
in Duchenne muscular dystrophy (DMD). The report
is also published in the Jan. 11 issue of Neurology.
It finds that corticosteroids are beneficial in DMD, but that some
drawbacks to their use must be considered. To see the report for physicians
and a version for families, go to “Practice Guidelines”
on the AAN Web site at www.aan.com.
Known as a practice parameter, the report results from a
review of relevant articles published from 1966 to 2004, of which
25 were chosen for detailed analysis. The AAN subcommittee preparing
the report was composed mostly of MDA clinic directors and research
grantees. Several of the 25 selected studies received MDA funding.
The report concluded that:
- Prednisone and deflazacort (the latter isn't available in the United
States) are beneficial in the treatment of DMD. Seven high-quality
studies showed a significant increase in strength, timed muscle function
and pulmonary function with these medications.
- Effective initial treatments are 0.75 milligrams per kilogram of
body weight per day for prednisone, or 0.9 milligrams per kilogram
per day for deflazacort.
- The most frequent side effects are weight gain and the development
of a Cushingoid facial appearance (rounded, puffy face).
- There are insufficient data comparing prednisone and deflazacort
to determine whether deflazacort has fewer side effects.
The subcommittee’s recommendations included:
- Maintaining a daily dosage of 0.75 milligrams of prednisone per kilogram
is best, but if side effects require a decrease in dosage, a gradual
tapering to as low as 0.3 milligrams will still provide some improvement.
- Benefits and side effects of corticosteroid therapy need to be monitored.
Timed function tests, pulmonary function tests, and age at loss of
independent walking are useful to assess benefits. An offer of treatment
with corticosteroids should include a discussion of risks.
- Possible side effects, such as weight gain, Cushingoid appearance,
cataracts, short stature from slowed growth rate, acne, excessive
hair growth, gastrointestinal symptoms and behavioral changes, need
to be assessed. If a boy gains more than 20 percent over the estimated
normal weight for his height in a year, the dosage of prednisone should
be decreased to 0.5 milligrams per kilogram per day, with a further
decrease to 0.3 milligrams after three to four months if excessive
weight gain continues.
- Deflazacort at 0.9 milligrams per kilogram per day can also be used
for the treatment of DMD in countries where it’s available.
Patients taking deflazacort should be monitored for cataracts and
weight gain.
Valerie Cwik, MDA’s medical director, said that while the guidelines
are useful, they also identify many questions about corticosteroid
therapy and DMD that remain unanswered.
Researchers Refining Naked DNA Delivery
MDA grantee Basil Petrof at the Meakins-Christie Laboratories and
the Respiratory Division of McGill University in Montreal will continue
to improve the efficiency of delivering “naked” (without
viruses) DNA through the bloodstream to muscle cells, using funding
from MDA that runs through 2007.
A group headed by Petrof that included MDA grantee George Karpati
at McGill’s Montreal Neurological Institute recently found that
reducing pressure from fluid buildup inside muscles may make delivery
of naked DNA to muscles via arteries more effective.
The team, which published its findings online in Molecular Therapy
on Oct. 28, found that by reducing the fluid pressure inside the leg
muscles during the injection procedure, they could significantly increase
the amount of DNA delivered to the muscles and minimize damage to
muscle cells.
In experiments in pigs, the scientists reached some 60 percent of
fibers in a muscle at the back of the leg after injecting DNA into
a major artery in the thigh. Tests also indicated that lowering intramuscular
fluid pressure buildup may have reduced damage to muscle fibers caused
by such injections.
“Several groups are attempting to improve methods for delivering
genes to muscle by injection into the bloodstream,” Petrof said.
“We believe that intramuscular pressure monitoring is a simple
and valuable tool for optimizing these efforts.”
Karpati added, “This method could be used for optimization
of dystrophin gene delivery in appropriate clinical trials in Duchenne
dystrophy patients.”
Better Tests Available for Duchenne, Beckers MDs
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New tests will help families determine which mutation has led to Duchenne or Becker MD.
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The Medical Genetics Laboratories at Baylor College of Medicine in
Houston are now offering full screening for mutations (flaws) in the
dystrophin gene, which underlie Duchenne muscular dystrophy
(DMD) and Becker MD (BMD).
Standard tests only detect about 60 percent of DMD-causing mutations
in the dystrophin gene and an uncertain percentage of BMD-causing
mutations. However, it’s important for families to know exactly
what mutation an affected member has, because such results may determine
eligibility for a clinical trial, and may allow definitive prenatal
and carrier testing.
The Baylor test, which was developed with MDA support of Madhuri
Hegde in the Department of Molecular and Human Genetics, scans the
dystrophin gene using denaturing high-pressure liquid chromatography
(DHPLC), a process designed to detect almost all dystrophin mutations.
For more information, see the laboratory’s Web site at www.bcmgeneticlabs.org,
or call (800) 411-GENE (4363).
Tests that examine the entire dystrophin gene are also offered at
the Utah Genome Depot in Salt Lake City (www.genome.utah.edu/DMD/clinical_test.shtml;
[801] 581-6956); and City of Hope National Medical Center’s
Clinical Molecular Diagnostic Laboratory in Duarte, Calif. (www.cityofhope.org/cmdl/DMD.asp;
[888] 826-4362).
SMA PROGRESS
Spinal muscular atrophy (SMA) is caused by a deficiency
of the survival of motor neuron (SMN) protein, which is made
by the SMN1 gene and to a far lesser extent by the SMN2 gene. Research
is focused on improving SMN protein levels through insertion of SMN
genes or increasing production from SMN2 genes.
Lentivirus Vector Delivers Genes to SMA Mice
Researchers at Ohio State University in Columbus and Oxford (England)
BioMedica have developed a way of delivering therapeutic genes to
mice with a disease resembling human SMA.
Mice that received SMN genes developed SMA symptoms later and lived
a few days longer than did mice that received injections with no genes
or no treatment at all.
The investigators first inserted the genes into transport vehicles
(vectors) made from an altered version of the equine infectious
anemia virus (EIAV), a member of the lentivirus family.
They then injected the virus-coated genes into the muscles of the
back legs, diaphragms, rib areas, faces and tongues of the SMN-deficient
mice. They say the genes moved from muscle fibers up nerve fibers.
The authors, who published their results in the December issue of
the Journal of Clinical Investigation, write that the findings “are
indicative that gene transfer using lentivector expressing SMN at
onset of disease induces not only an extension in life span, but also
results in a delay in the motor phenotype [movement functions] in
a severe model of SMA.”
They also note, however, that the effects on the mouse disease were
surprisingly minimal, given that SMN was found in a large percentage
of examined nerve cells.
The study authors included Arthur Burghes, a molecular biologist
at Ohio State who, with MDA funding, contributed significantly to
the understanding of SMA genetics in the late 1990s.
Drug Screen Under Way
A project funded by the National Institute of Neurological Disorders
and Stroke (NINDS) of the National Institutes of Health is searching
for chemical compounds that can be developed into medications to treat
SMA.
Known as the SMA Project (see www.smaproject.org), the drug screen is aimed at finding substances
that increase SMN2’s output of the SMN protein.
“We have good candidate drugs from studies in other systems,”
grantee Michael Terns, associate professor of biochemistry and molecular
biology at the University of Georgia in Athens, said. “In addition,
there are libraries of compounds available for testing to see if protein
concentrations go up without having to know the mechanism behind it.”
The Georgia researchers will use NIH-approved human embryonic stem
cells to test the ability of compounds to increase SMN production.
Additional grants were given to Johns Hopkins University in Baltimore
and Ohio State University in Columbus.
Indoprofen Increases SMN
A team of investigators has found that indoprofen, a nonsteroidal
anti-inflammatory agent, slightly increases production of the needed
SMN protein in cells taken from people with severe SMA.
Drug responses from cells in a lab dish don’t always match
responses in animals or people, but cell-based screens are often a
first step toward drug discovery
The researchers, in the November issue of Chemistry & Biology,
say the drug also led to more gems, structures that are reduced
in SMA-affected cells. And SMA-affected developing embryos showed
a trend toward greater survival when their mothers were given indoprofen.
Among the study team members were Glenn Morris of the Robert Jones
and Agnes Hunt Orthopaedic Hospital in Oswestry, United Kingdom; Arthur
Burghes of Ohio State University in Columbus; and Elliot Androphy
of the University of Massachusetts in Worcester, all of whom have
received MDA funding to study SMN.
The authors note that no other tested compounds from this class of
anti-inflammatory medications increased SMN production.
The indoprofen finding wasn’t a result of the NINDS SMA Project
(above).
CLINICAL TRIALS AND STUDIES
DMD Gene Therapy Trial Passes First Safety Test
The Recombinant DNA Advisory Committee (RAC), part of the National
Institutes of Health (NIH) in Bethesda, Md., voted on Dec. 16 that
an MDA-supported gene therapy safety trial — the first such
trial in boys with Duchenne muscular dystrophy (DMD) in the United States — can move forward. Next steps include
further animal safety testing and approval by the U.S. Food and Drug
Administration (FDA).
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R. Jude Samulski |
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The study, once approved, will be conducted by neurologist Jerry
Mendell of Columbus Children’s Research Institute, part of Ohio
State University; R. Jude Samulski, a virus specialist at the University
of North Carolina in Chapel Hill; and Xiao Xiao, a molecular biologist
at the University of Pittsburgh. Samulski and Xiao are part of Asklepios
Biopharmaceutical, a biotechnology company in Chapel Hill.
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Xiao Xiao |
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The investigators plan to test the safety of a laboratory-engineered
gene for the muscle protein dystrophin, tucked inside a modified adeno-associated
virus (AAV). (See “Bridge Over Troubled Waters,” January-February.)
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Jerry Mendell |
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If all goes according to plan, six boys with DMD who are at least
10 years old will receive injections of the AAV-encapsulated genes
into one biceps muscle, while the opposite biceps receives placebo
(sham) injections.
After about six weeks, samples of the muscles will be examined for
evidence of dystrophin production and signs of damaging reactions,
such as an unwanted immune response. The participants will undergo
many other types of safety testing during and after the injections.
The trial isn’t seeking participants at this time.
Sudden Cardiac Death a Risk in Type 2 MMD
In a study of type 2 myotonic dystrophy (MMD2),
sudden death from cardiac causes occurred in four people, three of
whom had no prior symptoms, report researchers at the University of
Minnesota in Minneapolis and several centers in Germany.
The investigational team included MDA research grantees Laura Ranum
and John Day at the University of Minnesota-Twin Cities. Day also
directs the MDA clinic at Fairview-University Medical Center in Minneapolis.
The researchers studied medical records and other data from 297 people
with genetically confirmed MMD2.
The four who died had the “dilated” type of cardiomyopathy,
and two of them also had scarring of heart cells that conduct signals
through the tissue.
In their report in the Dec. 28 issue of Neurology, the authors write,
“Our observations reveal that DM2 [type 2 MMD] patients are
at risk for severe cardiac complications that need close cardiac surveillance.”
While the cardiac problems associated with type 1 MMD have been the
subject of much study in recent years (see "Heart Problems,"
below), the extent to which MMD2 is associated with these problems
has only recently become clear.
“These findings substantiate the need for patients with both
types of MMD to have frequent clinical evaluations to assess heart
function,” Day said.
Last year, researchers at the University of Wurzburg in Germany found
that people with MMD2 can have subtle heart problems long before they
develop symptoms and that older MMD2 patients can develop cardiomyopathy,
a degeneration of cardiac muscle cells (see “Research Updates,”
January-February).
Heart Problems in MMD1 Often Require Pacemaker
A ongoing study of heart problems in type 1 myotonic dystrophy
(MMD1) that began in 1997 has released two sets of interim
results.
The study is being conducted under the direction of cardiologist
William Groh at the Krannert Institute of Cardiology of Indiana University
in Indianapolis and has had support from medical electronics manufacturer
Medtronic and from MDA.
As of June, 440 patients were enrolled in the study. In a subsection,
six people had a device implanted underneath the skin of the chest
to constantly record heart rate and rhythm. Serious problems were
detected in three people, and two received an electronic device to
correct problems.
As of January, 57 participants (13 percent of the 440) were noted
to have entered the study with a diagnosed heart problem. At study
entry, nine of them (2 percent) had a pacemaker. By January, 37 (9
percent) had had a pacemaker inserted.
Residents of the Indianapolis area who believe they have MMD1 are
still being enrolled. Contact clinical research coordinator Miriam
Lowe at (317) 962-0080, (800) 843-2786 or milowe@iupui.edu.
Etanercept for MG Shows Promise, Risks
Doctors at the University of Illinois and Rush University Medical
Center in Chicago and the University of Texas at Galveston have found
that the drug etanercept (Enbrel) may offer hope to some
people with myasthenia gravis (MG) who need relatively
high doses of corticosteroids, such as prednisone.
In the autoimmune disease MG, the immune system mistakenly attacks
the part of the muscle cell that receives signals from a nerve cell,
leading to fluctuating weakness.
Etanercept, which has FDA approval for the treatment of arthritis
and psoriasis, blocks the action of tumor necrosis factor (TNF),
a substance secreted by cells of the immune system that has been implicated
as a contributor to MG.
The doctors originally enrolled 11 people with MG, all of whom had
needed at least 25 milligrams of prednisone every other day for more
than six months to control symptoms. This is a potentially toxic corticosteroid
level.
Six of the 11 patients improved with etanercept, administered by
injection twice a week, based on measures of muscle strength and the
ability to successfully taper their prednisone doses. Two others withdrew
when their disease worsened.
The study team, which included MDA grantees Erdem Tuzun and Premkumar
Christadoss at the University of Texas at Galveston, published its
findings in the Dec. 28 issue of Neurology. (Amgen, which markets
Enbrel, contributed to funding for the trial.)
