Obesity Clinical Trial
Official title:
Pharmacogenetic Study of Neurofunctional Brain Areas Related to Food Craving in Obese Patients With Binge Eating Disorder Treated With Topiramate
Adoption, twin and family studies have reported that obesity has a strong heritable
component and in particular, it has been suggested that BMI in adults is due to genetic
influence rather than shared family environment. Binge eating in obese patients was
described. Therefore, it has been proposed that binge eating disorder (BED) may contribute
to obesity in some individuals.
Pharmacological studies reported that topiramate plays an important role in the treatment of
binge eating disorder. It has been observed improvement of co-occurring binge eating
disorder in patients receiving topiramate for treatment of mood disorders. In addition,
topiramate was associated with anorexia and weight loss in clinical trials with epilepsy
patients. Also, topiramate has been demonstrated efficacy in pilot and controlled studies
for binge eating disorder (BED) associated with obesity. Genetic studies will be important
to elucidate the mechanism by which putative susceptibility variation in candidate genes
influences in pharmacological improvement of binge eating disorder in obese patients treated
with topiramate.
Connecting drug response with relevant functional DNA variants and differences in brain
regions represents the ultimate goal for pharmacogenetic research playing an important role
in advancing this understanding. The use of brain imaging combined with genetics can aid in
understanding the pathophysiological mechanism of the disease. Additionally, brain imaging
has the ability to bridge between preclinical research and human pharmacological studies.
This will be a naturalistic clinical study designed to analyze the effect of genetic
variants and neurofunctional brain areas associated with food craving in patients with
obesity and binge eating disorder responders to topiramate.
Hypothesis: The use of topiramate in obese subjects with binge eating disorder is associated
with a differential gene variants and different activation brain areas in subjects that
showed a reduction of food craving and weight lost.
Obesity has been declared the number one illness of the 21st Century in industrialized
countries, and is reaching epidemic proportions. Adoption, twin and family studies have
reported that obesity has a strong heritable component and in particular, it has been
suggested that BMI in adults is due to genetic influence rather than shared family
environment. Binge eating in obese patients was escribed. Therefore, it has been proposed
that binge eating disorder (BED) may contribute to obesity in some individuals. Subjects
with BED are frequently obese. Conversely, BED is often observed in obese populations,
especially the severely obese. Therefore, these findings suggest that BED is a major public
health problem and a contributor to the obesity epidemic.
Evidence from twin studies suggests a significant contribution of genetic factor in binge
eating. Interestingly, it was reported that relatives of patients with BED displayed a
higher prevalence of obesity, particularly of severe obesity than relatives of probands
without BED. Adoption and twin studies have consistently shown that, regardless of the
population studied, genetic factors play an important role in determining the risk of
developing binge eating.
Pharmacological studies reported that topiramate plays an important role in the treatment of
binge eating disorder. It has been observed improvement of co-occurring binge eating
disorder in patients receiving topiramate for treatment of mood disorder. In addition,
topiramate was associated with anorexia and weight loss in clinical trials with epilepsy
patients. Also, topiramate has been demonstrated efficacy in pilot and controlled studies
for binge eating disorder (BED) associated with obesity. A paper review showed that
topiramate weigtht loss was reported in 21 of 32 studies analyzed.
Recently, it was approved on 4/6/2012 the use of topiramate in combination with phentermine
(QNEXA) in the Meeting of the Endocrinologic and Metabolic Drugs Advisory Committee of the
Food and Drug Administration, as an adjunct to diet and exercise for weight management in
patients with a body mass index (BMI) equal to or greater than 30 kilograms (kg) per square
meter or a BMI equal to or greater than 27 kg per square meter if accompanied by
weight-related co-morbidities.
Finally, animal studies have shown that stimulation of the lateral hypothalamus by glutamate
and glutamate agonists, including kainite/AMPA agonists, causes an intense, rapid,
dose-dependent increase in food intake.
Topiramate weight loss was reported in 21 of the 32 studies analysed and reached 5%
reduction of the baseline weight prior treatment in 5 studies. Among the studies analyzed, a
frequent finding was that the grater weight loss was associated with higher BMI at baseline.
Also, diabetic patients were related with glycemic control and normalization of blood
pressure in hypertensive subjects. Topiramate was generally well tolerated and serious
adverse events were rare. Also, the use of topiramate was reported effective for weight
reduction and improvement in glycemic control in obese subject with type 2 diabetes treated
with metformin monotherapy.
Topiramate, which is approved for use in epilepsy and migraine prophylaxis, has multiple
sites of action that might contribute to its neurostabilizing effects.
The mechanism of action of topiramate in BED is unknown. It may act as an appetite
suppressant or satiety enhancer or somehow influence the reward system acting on appetite,
and thereby reduce binge eating. Topiramate has not been shown to affect serotoninergic
neurotransmission. Indeed, it has been shown to attenuate nicotine-induced increases in
mesolimbic extracellular dopamine and norepinephrine, but not serotonin, release.
In addition, topiramate antagonizes glutamate receptors. Since glutamate and glutamate
agonists rapidly elicit intense eating when injected into the lateral hypothalamus of rats,
topiramate might reduce binge eating through glutamate antagonism. However, the mechanism of
action of topiramate is unknown. Therefore, it is very important pharmacogenetic and
neurofunctional brain studies that could help to elucidate the role of topiramate such as a
new treatment for binge eating disorder associated with obesity in Mexican population.
Genetic studies will be important to elucidate the mechanism by which putative
susceptibility variation in candidate genes influences in pharmacological improvement of
binge eating disorder in obese patients treated with topiramate. DNA variants in coding and
regulatory regions of genes will be both useful for systematic genome scans, for identifying
genes associated with drug response, and for examining integrated systems of gene pathways
as an important step on the route to functional genomics. Initiatives focused on
identification of gene variants would greatly facilitate postgenomic research on the links
between genes, brain, behavior, and treatment response.
Many drug targets (e.g., receptors, transporters, enzymes) that contribute to the
pharmacodynamics of drug response are not only key players in the regulation of
neurotransmitter systems but also directly or indirectly modify the development and
plasticity of neural networks involved in drug effects. There is now considerable evidence
that variability of epigenetic profiles of genes critical to neurocircuit development and
function influences drug responses.
There are a number of different kinds of natural genetic variation that result in functional
protein differences and affect drug responsiveness. The type of variation that is most
prevalent in the genome and, arguably, the most relevant to common diseases and complex
traits is represented by single nucleotide polymorphisms (SNPs).
There are many ways in which genetic variability, the differences in the sequence of
specific genes, can lead to variability in drug responsiveness and it is likely that each of
these mechanisms is involved in determining the effects for example in anticonvulsant drugs.
Up to now, the focus of pharmacogenetic studies has been on "polymorphic drug metabolism".
This methodology examines variations in the sequence of genes that code for
drug-metabolizing enzymes. SNPs have been found to underlie variability in drug-metabolizing
capacity and such variability is often documented as differences in drug and metabolite
profiles between patients. It is likely that variation in genes coding for proteins involved
in other pharmacokinetic processes, including drug absorption, distribution, and excretion,
also help to determine individual differences in responsiveness although these mechanisms
are not as well studied regarding genetic influences.
Another way in which genetic variation plays a role in drug responses depends upon
polymorphisms in genes that code for proteins involved in drug targets or that mediate drug
action. These differences in response apply both to therapeutic effects and adverse effects
so that both efficacy and toxicity may be influenced by individual genetic variation. In the
future, pharmacogenetic discoveries related to drugs will make individualization of therapy
even more difficult in the sense that the genetic substrate that mediates efficacy may well
differ from that mediates toxicity. As such, two different sets of genes and genotypes will
need to be examined in order to match patients with the most appropriate treatment.
Differences in response apply both to therapeutic effects and adverse effects so that both
efficacy and toxicity may be influenced by individual genetic variation.
In addition, compounds exist with mechanisms of action that either differ from standard
drugs or are not yet fully characterized. These compounds and their mechanisms will lead
eventually to the investigation of specific, possibly novel, genes in relation to drug
responsiveness. Because behavioral traits are the most complex traits of all, response to
psychopharmacological drugs, which modify behaviour traits, is likely to profit from this
integration. Moreover, behavioural pharmacogenetics will make a major contribution to
functional genomics.
Connecting drug response with relevant functional DNA variants and differences in brain
regions represents the ultimate goal for pharmacogenetic research playing an important role
in advancing this understanding. Brain imaging can provide valuable links in understanding
the potential importance and clarifying the pathophysiological mechanisms that lie between
associations of genetic variability and clinical response. Analysis of additional
populations, such as Mexican population, is also necessary to achieve these goals. The use
of brain imaging combined with genetics can aid in understanding the pathophysiological
mechanism of the disease. Additionally, brain imaging has the ability to bridge between
preclinical research and human pharmacological studies.
This study proposes the collection of samples which will result from this study will form
the basis with which to identify the genes associated with neurofunctional brain areas
involved in food craving in obese patients with BED treated with topiramate in Mexican
population. The pharmacogenetic analysis in obese patients associated with BED will identify
gene variants associated with the treatment efficacy to topiramate in Mexican population.
Objective The main objective of this study is to analyze the genetic variants and
neurofunctional brain areas associated with food craving in obese patients with binge eating
disorder responders to topiramate treatment.
Study design:
This will be a naturalistic clinical study designed to analyze the effect of genetic
variants and neurofunctional brain areas associated with food craving in patients with
obesity and binge eating disorder responders to topiramate.
;
Observational Model: Case-Only, Time Perspective: Cross-Sectional
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