| Recent
Patents on Endocrine, Metabolic & Immune Drug Discovery
ISSN: 1872-2148
Recent Patents on Endocrine,
Metabolic & Immune Drug
Volume 1, Number 1, February
2007
Contents
Molecular Targets for Promoting Wound Healing
in Diabetes Pp. 1-13
Leena Pradhan, Nicholas D. Andersen, Frank W. LoGerfo
and Aristidis Veves
[Abstract] [Full
Text Article]
Dipeptidyl Peptidase-IV Inhibitors: An Evolving Treatment
for Type 2 Diabetes from the Incretin Concept Pp.
15-24
Yau-Jan Chyan and Lee-Ming Chuang
[Abstract] [Full
Text Article]
Insulin Delivery Systems for Controlling Diabetes
Pp. 25-40
Jaleh Varshosaz
[Abstract] [Full
Text Article]
Development of Prolactin Receptor Antagonists: Same
Goal, Different Ways Pp. 41-52
Vincent Goffin, Estelle Tallet, Jean-Baptiste Jomain and
Paul A. Kelly
[Abstract] [Full
Text Article]
C75, a Fatty Acid Synthase (FAS) Inhibitor
Pp. 53-62
Miguel López and Carlos Diéguez
[Abstract] [Full
Text Article]
Melatonin as Antioxidant Under Pathological Processes
Pp. 63-82
Cristina Tomás-Zapico and Ana Coto-Montes
[Abstract] [Full
Text Article]
Stimuli-induced Pulsatile or Triggered Release Delivery
Systems for Bioactive Compounds Pp. 83-90
Anil K. Anal
[Abstract] [Full
Text Article]
Patent Annotations Pp. 91-93
Patent Selections Pp. 95-102
Abstracts
[Back to top]
Molecular Targets for Promoting Wound Healing
in Diabetes
Leena Pradhan, Nicholas D. Andersen, Frank W. LoGerfo
and Aristidis Veves
[Full Text Article]
Diabetic foot ulceration stands as one of the most costly
and debilitating complications of diabetes and remains the
leading cause of nontraumatic lower extremity amputation in
the United States. Traditionally, ischemia, neuropathy, trauma,
and infection were considered the culprits of the recurring
chronic wound and treatment revolved largely around wound
debridement and revascularization. However, recent investigations
have uncovered an impaired cutaneous wound healing process
in diabetes caused by cellular and molecular alterations in
the diabetic microenvironment and have subsequently identified
an array of potential molecular targets for intervention.
Here, we review recent patents describing upcoming molecular
technologies at various stages of development for treating
foot ulceration in the diabetic patient. Target classes reviewed
include immunomodulators, neuropeptides, and growth factors,
and targets reviewed include lactoferrin, thymosin beta 4,
T cell immune response cDNA 7, substance P, neuropeptide Y,
vascular endothelial growth factor, fibroblast growth factor,
nerve growth factor, connective tissue growth factor, hepatocyte
growth factor, homeobox genes, and treprostinil. In the course
of this presentation, the biology of wound healing and the
pathobiology of impaired wound healing in diabetes are emphasized
to illustrate how these future molecular therapeutics are
intended to counteract disease pathology and promote normal
wound repair.
[Back to top]
Dipeptidyl Peptidase-IV Inhibitors: An Evolving Treatment
for Type 2 Diabetes from the Incretin Concept
Yau-Jan Chyan and Lee-Ming Chuang
[Full Text Article]
Glucose-dependent insulinotropic polypeptide (GIP) and glucagon-like
peptide (GLP-1) are the 2 major incretin hormones released
after meals to enhance glucose-stimulated insulin secretion.
In patients with type 2 diabetes, a loss of activity of GIP
for insulinotropic function and a reduced secretion of GLP-1
exist in response to oral glucose while GLP-1 action is preserved.
GLP-1 is therefore an attractive avenue for treating type
2 diabetes. Due to the short circulating half-life of GLP-1,
which is degraded by dipeptidyl peptidase IV (DPP-IV), 2 approaches
have been undertaken. One is to develop long-acting GLP-1
analogs, such as exendin-4 that is resistant to degradation.
Here we review another approach for developing DPP-IV inhibitors.
This group of potential drugs covers several major chemical
classes and their derivatives, such as amino acid amide, carbocyclic,
alkylamine, and heterocyclic compounds. More than 100 patents
have been issued for DPP-IV inhibitors to be used either as
a monotherapy or in combination with other antidiabetic agents
for the treatment of type 2 diabetes, as well as metabolic
syndrome, osteoporosis, and arthritis. Structure-based drug
design is currently under intensive investigation for future
development of more selective therapeutic agents.
[Back to top]
Insulin Delivery Systems for Controlling Diabetes
Jaleh Varshosaz
[Full Text Article]
The goal of all drug delivery systems is to deploy medications
intact to specifically targeted parts of the body through
a medium that can control the therapy's administration by
means of either a physiological or chemical trigger. The polypeptide
insulin is the primary hormone responsible for controlling
the transport, utilization and storage of glucose in the body.
Due to the inconvenience of insulin injections, various approaches
have been attempted to formulate insulin for administration
by non-injectable routes. Different approaches to deliver
insulin including transdermal, transmucosal, pulmonary route
using dry aerosols and inhalers, smart hydrogels, nasal delivery,
oral delivery, and treatment of diabetes with synthetic beta
cells, has resulted in recent developments in treatment of
diabetes. Among the latest patent approaches are delivering
into the subject a genetic construct comprising a coding sequence
for a human proinsulin operably connected a promoter functional
in the host cells. Polypeptides having activity of human neurogenin3
(hNgn3), and nucleic acid encoding such polypeptide are among
the other inventions that use of islet transcription factors
such as hNgn3 to facilitate production of pancreatic islet
cells from progenitor cells, and to facilitate insulin delivery
by production of islet cells so produced.
[Back to top]
Development of Prolactin Receptor Antagonists: Same
Goal, Different Ways
Vincent Goffin, Estelle Tallet, Jean-Baptiste Jomain and
Paul A. Kelly
[Full Text Article]
Hyperprolactinemia is an endocrine pathology resulting from
over-production of prolactin (PRL) by pituitary adenomas,
and leading to various reproductive disorders. In addition,
there is increasing evidence that PRL acts as a growth-promoter
of breast and prostate tumors. Classical drugs blocking pituitary
PRL production are not necessarily efficient in these pathological
situations, which has encouraged the search for alternative
ways of inhibiting the undesirable actions of PRL. Prolactin
receptor (PRLR) antagonists, acting at the level of receptor
activation rather than PRL production, are the most promising
strategy. Based on the protein core of human (h)PRL or growth
hormone (hGH), the other natural hPRLR ligand, a series of
new variants have been engineered within the past couple of
years, leading to various patent applications. Modifications
of amino acid sequences involve single/multiple substitutions,
truncations, or generation of fusion proteins. Three mechanisms
of action have been reported for these PRLR antagonists: 1)
inhibition of PRLR signaling by competition with endogenous
PRL for receptor binding, 2) activation of specific PRLR signalling
pathways resulting in actions opposite to those of wild-type
hPRL, and 3) engineering of chimeric ligands targeting more
than one receptor/cell type, in order to improve tumor-growth
inhibition. Since none of these patented molecules is yet
in clinical trials, their efficacy to treat PRL-dependent
pathologies remains to be demonstrated in humans.
[Back to top]
C75, a Fatty Acid Synthase (FAS) Inhibitor
Miguel López and Carlos Diéguez
[Full Text Article]
Recent data has demonstrated that fatty acid metabolism plays
a critical role in the hypothalamic regulation of food intake
and the evidence is as follows. Circulating long chain fatty
acids act as nutrient surplus signals in the hypothalamus.
On addition, fatty acid synthesis pathway enzymes, such as
fatty acid synthase (FAS) and acetyl-CoA carboxylase (ACC)
and its upstream regulator, AMP-activated protein kinase (AMPK)
are regulated by nutritional and hormonal stimuli. Very importantly,
current evidence also indicates that fatty acid metabolism
pathway may be a potential target for obesity treatment. In
this sense, it has been demonstrated that pharmacological
inhibition of FAS results in profound decrease in food intake
and body weight in rodents. These anorectic actions are mediated
by the modulation of hypothalamic neuropeptide systems, through
a malonyl-CoA dependent mechanism.
In this review, we recapitulate what is known about hypothalamic
fatty acid metabolism and the regulation of feeding, with
particular interest in a specific FAS inhibitor, C75, which
has been recently patented as a potential drug for adipose
mass reduction.
[Back to top]
Melatonin as Antioxidant Under Pathological Processes
Cristina Tomás-Zapico and Ana Coto-Montes
[Full Text Article]
Many are the diseases which course with free radical formation.
These disorders cover a great range of fields such as neurodegenerative,
immune, inflammatory and mitochondrial-related diseases. Melatonin
is the main pineal gland product and it functions as “time-giver”
in the regulation of circadian rhythms, among others. But
the actions of melatonin are not only restricted to the neuroendocrine
physiology. In fact, it has been known as a radical scavenger,
a role that has been deeply studied in all those conditions
where free radicals are generated. Furthermore, melatonin
has been shown to act as an indirect antioxidant, since it
is able to increase the activity and expression of the main
antioxidant enzymes, the machinery for the glutathione synthesis,
and many others direct or indirectly implicated in the free
radical removal. Melatonin can also diminish the activity
or expression of enzymes or factors that are considered as
prooxidants. Thus, researchers have paid attention to the
possible actions of melatonin in the attenuation of those
processes where free radical overproduction is implicated.
This review summarizes some of the proposed melatonin mechanisms
for different free radical-dependent pathological situations,
as well as some patents on melatonin significance recently
reported for the treatment of attention deficit, hyperactivity
disorders, stress-related diseases, Chronic fatigue syndrome,
diabetes, Parkinson’s disease. Alzheimer’s disease,
age associated cognitive dysfunction and cancer.
[Back to top]
Stimuli-induced Pulsatile or Triggered Release Delivery
Systems for Bioactive Compounds
Anil K. Anal
[Full Text Article]
As is frequently found in the living body, many vital functions
are regulated by pulsed or triggered release of bioactive
substances at a specific site and time. Thus it is important
to develop new drug delivery devices to achieve pulsed delivery
of a certain amount of drugs in order to mimic the function
of the living systems to minimize the undesired side effects.
The pulsed or triggered delivery systems are designed to alter
their rate of drug delivery in response to stimuli such as
changes in a specific molecule, a magnetic or electric field,
temperature, light or mechanical forces. Such systems are
suitable for the release of therapeutics that benefit from
non-constant plasma concentrations. In this article, several
types of drug delivery systems which cause the pulsed or triggered
release of bioactive compounds due to certain external stimuli,
mostly focuses on thermally-, electrically- and magnetically-
induced release are described in detail. The recent patents
on various delivery systems which release the active compounds
only with the external stimuli are described in detail.
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