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NFP37
SOMATIC
GENE THERAPY
Texts for Laypersons
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Prof. Patrick Aebischer;
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Division Autonome de Recherche Chirurgicale; C H U V;
Pavillon 3; 1011 Lausanne; CH;
Tel 021 314 24 60; Fax 021 314 24 68;
e-mail:
paebisch@chuv.hospvd.ch
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Title:
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Development of a gene therapy approach for patients
suffering from amyotrophic lateral sclerosis.
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Co-applicants:
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Prof. A. Kato CMU (Genève)
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Collaborators:
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ABSTRACT | PUBLICATION | DIVULGATION
TEXT | BACK TO OUTLINE
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ABSTRACT FOR LAYPERSONS 1997:
Neuronal growth factors hold promise for
providing therapeutic benefits in various neurological disorders. As
a means of ensuring adequate central nervous system delivery of
growth factors and minimizing significant adverse side effects
associated with systemic delivery methods, we have developed an ex
vivo gene therapy approach for protein delivery using encapsulated
genetically modified xenogeneic cells. One neurotrophic factor in
particular, ciliary neurotrophic factor (CNTF), has been shown in
various rodent models to reduce the motor neuron cell death similar
to that seen in amyotrophic lateral sclerosis (ALS). The initial
clinical trial focusing on the systemic administration of CNTF
resulted in severe side-effects mandating the interruption of the
trials, therefore preventing determination of the efficacy of the
molecule. In order to deliver CNTF directly to the nervous system, we
conducted a phase I study in which 10 patients with ALS were
implanted with polymer capsules containing geneticallyengineered baby
hamster kidney (BHK) cells releasing approximately 1.0 µg of
CNTF per day in vitro. The CNTF-releasing implants were surgically
placed within the lumbar intrathecal space. Serial cerebrospinal
fluid (CSF) sampling showed the presence of hundred of picograms of
CNTF up to 15 months post-implantation whereas no CNTF was detected
prior to implantation. On explant, devices showed viable BHK cells
and CNTF output when measured in vitro. The patients showed no weight
loss, severe coughing or induction of acute phase reactants over the
course of implantation which were the limiting side effects observed
with systemic CNTF administration. All patients were evaluated using
various ALS clinical rating scales for ALS progression. Examination
of the slopes of the various tests before and after implantation
indicate that the disease continues to progress. In vitro and
experiments conducted on rodent models of motoneuron degeneration
indicate that the delivery of more than one trophic factor has
beneficial effect over the delivery of a single factor. We have
identified a second neurotrophic factor named NT4/5 which synergises
in vitro the effect of CNTF. We have also been able to construct cell
lines able to release 2 trophic factors. These cell lines are
currently being tested in various animal models of motoneuron
degeneration. It is hoped that these combinations can be tested in
patients in the not so far future.
ABSTRACT FOR LAYPERSONS
1998:
Neurotrophic factors are proteins that hold
promise for the treatment of neurodegenerative diseases.
Demonstration of the neuroprotective effects of trophic factors in
the central nervous system (CNS) and in various animal models of
neurodegeneration has led to the development of strategies for the
treatment of diseases such as Parkinson's disease, Alzheimer's
disease and Amyotrophic Lateral Sclerosis (ALS). The presence of the
blood brain barrier, a system that prevent the access of molecules
including proteins to the nervous system remains, however, a major
concern for the delivery of neurotrophic factors to the CNS. A
technique involving the placement of cells genetically engineered to
release neurotrophic factors in natural fluid surrounding the spinal
cord provides a means to continuously deliver trophic factors
directly within the CNS, beyond the blood brain barrier. The cells
are protected from the host immune system by a thin porous synthetic
film that we call capsules.
Amyotrophic lateral sclerosis is a neurodegenerative disease leading
to paralysis and death within 2-3 years following the loss of
motoneurons, the nerve cells localized essentially in the spinal cord
controlling muscle activity. Administration of neurotrophic factors
in vitro and in animal models of this disease lead to an increased
survival of motoneurons. Numerous side effects have been observed
following systemic administration in ALS patients of human ciliary
neurotrophic factor (hCNTF), a trophic factor. Deliver of hCNTF
should directly expose motoneurons to the neurotrophic factor, while
avoiding side effects related to its peripheral administration. This
can be achieved by the transplantation of immunoprotected xenogenic
cell lines genetically engineered to release hCNTF.
The efficacy and safety of transplanting baby hamster kidney (BHK)
cells genetically engineered to release human CNTF was first
demonstrated in rodents and sheep. Twelve patients were then
implanted in the fluid surrounding hte spinal cord with a device
containing BHK cells releasing CNTF. According to the protocol, the
implants have been retrieved after 3 months and replaced by a second
capsule. Viable cells and hCNTF secretion were observed in all
retrieved implants. No limiting adverse effects were observed in any
of the implanted patients. Detectable levels of CNTF were observed up
to 60 weeks post transplantation whereas hCNTF was undetectable
before implantation. The biological results demonstrate that
neurotrophic factors can be delivered to the CNS through encapsulated
genetically modified cel1 transplantation. The small number of
patients, however, does not allow the assessment of a potential
slowing of the degeneration process.
ABSTRACT FOR LAYPERSONS
1999:
ABSTRACT FOR LAYPERSONS
2000:
ABSTRACT FOR LAYPERSONS
2001:
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