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Recent
Patents on CNS Drug Discovery
ISSN: 1574-8898
Recent Patents on CNS Drug
Discovery
Volume 3, Number 3, November 2008
Contents
Neurodegeneration and Neuroprotective Agents in Multiple Sclerosis
Pp. 153-165
Joanna S. Fong, Alexander Rae-Grant and
DeRen Huang
[Abstract]
Targeting the NMDA Receptor for Fear-Related
Disorders Pp. 166-178
Olavo B. Amaral and Rafael Roesler
[Abstract]
Small Molecular Inhibitors of p-STAT3:
Novel Agents for Treatment of Primary and Metastatic CNS Cancers
Pp. 179-188
Amy B. Heimberger and Waldemar
Priebe
[Abstract]
Inflammation: Beneficial or Detrimental
After Spinal Cord Injury? Pp. 189-199
Carmen C.M. Chan
[Abstract]
Small Molecules that Promote Neurogenesis
in vitro Pp. 200-208
Gilbert M. Rishton
[Abstract]
Gap Junctions as Therapeutic Targets
in Brain Injury Following Hypoxia-Ischemia Pp.
209-215
Macarena Sahores and Ariadna Mendoza-Naranjo
[Abstract]
Brain Permeable Nanoparticles Pp.
216-225
Dimple Chopra, Monica Gulati, Vikrant Saluja,
Purnima Pathak and Parikshit Bansal
[Abstract]
Neurolological Disorders and Neuroprotection
After Heart Surgery Pp. 226-229
Georgios I. Tagarakis
[Abstract]
Patent Selections Pp. 230-233
Abstracts
[Back to top]
Neurodegeneration and Neuroprotective Agents in Multiple Sclerosis
Joanna S. Fong, Alexander Rae-Grant and
DeRen Huang
Multiple sclerosis (MS) is an autoimmune/ inflammatory
disease of the central nervous system (CNS). MS affects more
than two million people worldwide and has been recognized
as the leading cause of neurological disability in young adults.
MS has long been considered as a CNS disease of demyelination
and inflammation. Axonal degeneration has however been increasingly
accepted as a key pathogenetic element. Certain noninvasive
tests such as optic coherence tomography (OCT), magnetization
transfer imaging (MTI), and proton magnetic resonance spectroscopy
(MRS) might be superior in early detection of axonal loss
and neurodegeneration as compared to conventional neuroimaging
studies. New therapeutic strategies targeting the neurodegenerative
process in MS provide hope to the MS community. A number of
phase II or III clinical trials that are designed to target
such specific pathogenetic mechanisms include sodium channel
blockers, matrix metalloproteinases (MMP) inhibitors, c-AMP
selective phosphodiesterase inhibitors, NMDA receptor antagonists,
amongst others. In the current review, we will discuss the
current understanding of the mechanisms of neurodegeneration
in MS, agents with neuroprotective properties, patents currently
available and, their possible application in the treatment
of MS.
[Back to top]
Targeting the NMDA Receptor for Fear-Related
Disorders
Olavo B. Amaral and Rafael
Roesler
The gap between basic neuroscience and clinical
psychiatry in the treatment of anxiety disorders has been
steadily diminishing over recent years. Among the leading
advances in this field of translation research is the application
of knowledge on the neurobiology of fear memory to the treatment
of anxiety disorders in humans. Animal studies have identified
N-methyl-D-aspartate (NMDA) receptors as crucial
in fear memory acquisition and consolidation, as well as in
its extinction and reconsolidation. Based on this, the NMDA
receptor partial agonist D-cycloserine, which facilitates
fear extinction in rodents, has been shown to increase the
effect of exposure therapy in psychiatric patients for conditions
such as phobias, social anxiety and obsessive-compulsive disorder.
In this article, we review current strategies for targeting
the NMDA receptor in the treatment of fear-related disorders,
analyzing experimental results, clinical data, and recent
patents in the field, while also addressing potential new
approaches to explore this field of drug discovery.
[Back to top]
Small Molecular Inhibitors of p-STAT3:
Novel Agents for Treatment of Primary and Metastatic CNS Cancers
Amy B. Heimberger and
Waldemar Priebe
High-grade primary and metastatic central nervous
system (CNS) tumors are common, deadly, and refractory to
conventional therapy and have a median survival duration of
less than one year. A key transcriptional factor, signal transducer
and activator of transcription (STAT) 3, drives the fundamental
components of tumor malignancy and metastases in the CNS.
STAT3 promotes this tumorigenesis by enhancing proliferation,
angiogenesis, invasion, metastasis, and immunosuppression.
The clinical implementation of drugs that specifically target
malignancy within the CNS is clearly a major unmet need. A
group of potent, small molecule inhibitors of STAT3 display
marked efficacy with minimal toxicity against malignancy in
murine models, including established intracerebral tumors.
The mechanism of this in vivo efficacy of the STAT3
blockade agents is a combination of direct tumor cytotoxicity
and immune cytotoxic clearance. Given their ability to achieve
good CNS penetration, these drugs will be taken forward into
clinical trials for patients with CNS malignancies and as
immunotherapeutic enhancers.
[Back to top]
Inflammation: Beneficial or Detrimental
After Spinal Cord Injury?
Carmen C.M. Chan
Spinal cord injury leads to a devastating cascade
of secondary complications that eventually results in the
formation of scar tissue many times the size of the original
insult. Inflammation plays a very important role towards the
development of such scar, but paradoxically, at the same time
it has neuroprotective properties. Only recently have we understood
enough about the relevant events to make the repair of injured
spinal cords a reachable goal. Over the past decade, researchers
have designed and tested numerous innovative therapeutic strategies,
and many of such involve manipulation of the immune response.
Interestingly, both immuno-stimulatory and immuno-suppressive
interventions have shown positive results, which include the
prevention of further tissue damage, prevention of secondary
cell death and axonal degeneration, promotion of remyelination,
stimulation of axonal regeneration, and facilitation of sensorimotor
function recovery.
[Back to top]
Small Molecules that Promote Neurogenesis
in vitro
Gilbert M. Rishton
Small molecule modulators of neural stem cell (NSC)
differentiation might potentially be developed into orally
administered neurogenic drugs to treat neurodegenerative diseases
including Alzheimer’s disease. New technologies developed
for the study of NSC culture, proliferation and differentiation
have enabled the establishment of screening platforms to identify
small molecules with neurogenic activity. Recent patents claim
novel small molecules identified from screening collections
that stimulate or otherwise regulate stem cell differentiation
and neurogenesis. Several patents claim newly discovered NSC
differentiation modulating activity of previously marketed
drugs suggesting perhaps a previously unknown mechanism of
action of these drugs and/or implicating the target enzyme
and receptor pathways as key players in neurogenesis. This
relatively new area of research into small molecule modulators
of neurogenesis is reviewed and recent patents claiming small
molecule neurogenic compounds, potentially orally administered
CNS regenerative therapies are summarized.
[Back to top]
Gap Junctions as Therapeutic Targets
in Brain Injury Following Hypoxia-Ischemia
Macarena Sahores and Ariadna
Mendoza-Naranjo
Gap junctions (GJs) are highly specialized membrane
structures which allow the passage of small molecules and
ions between neighboring cells. Intercellular communication
via GJs is a crucial mechanism that plays a central role in
several pathologies. This review focuses on: i) the role of
connexins (Cxs, transmembrane proteins that form GJ channels)
in the pathophysiology of neuronal injury after brain hypoxia-ischemia,
ii) the opposing theories regarding whether Cxs are protective
agents or contribute to the spread of damage, and iii) recent
patent applications and registrations showing Cxs as key targets
in regulating GJ-mediated intercellular communication.
[Back to top]
Brain Permeable Nanoparticles
Dimple Chopra, Monica Gulati, Vikrant Saluja,
Purnima Pathak and Parikshit Bansal
The brain is one of the least accessible organs
of the body, thus making the delivery of neurotherapeutics
almost a challenge. Despite its relatively high nutrient support
and exchange requirements, the uptake of any compound is strictly
regulated by the blood brain barrier (BBB). As a consequence,
BBB prevents effective treatment of many severe and life threatening
diseases like brain cancer, epilepsy, Alzheimer’s disease,
schizophrenia etc. Numerous drug delivery strategies have
been developed to circumvent this barrier. One such approach
is the use of nanoparticles. Nanoparticles form solid, colloidal
drug delivery system that consists of macromolecular materials
in which the active principle is dissolved, entrapped or encapsulated
or onto which the active principle is adsorbed or attached.
Brain targeted polymeric nanoparticles have been found to
increase the therapeutic efficacy and reduce the toxicity
for a large number of drugs. By coating the nanoparticles
with surfactants, higher concentrations of drugs can be delivered
to the brain. The article presents various approaches used
in design and delivery of nanoparticles to brain. It also
reviews various patents that describe the use of nanoparticles
to deliver various neurotherapeutics and neurodiagnostics
to brain.
[Back to top]
Neurolological Disorders and Neuroprotection
After Heart Surgery
Georgios I. Tagarakis
Neurological/neuropsychiatric complications are
commonly observed after heart surgery. They include the cerebral
ischemic episode, transient ischemic attack, postoperative
cognitive decline and postoperative delirium. In this review
article, we are dealing with the etiology of these complications,
mainly focusing on the role of genetic components. We are
also commenting on the putative role of certain pharmacologic
agents in the treatment of the aforementioned nosological
entities.
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