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Celexa has been a popular antidepressant for several decades and Celexa weight
gain has been overlooked by the healthcare industry. It is normal for 55% of
those taking Celexa to experience weight gain. Unfortunately, 40.6 percent of
the people taking Celexa will gain 7% or more weight, the health concerns are
real. (1)Further studies are listed below but The Harper Method has one
interest; helping those that have Celexa weight gain and losing the weight
safely.
Who is
this method for?
It is
for those who may or may not want to stay on Celexa
It is
also for those that are now off Celexa
It is
for those that have gained weight due to Celexa
It is
for those that have tried to diet and exercise and the Celexa weight gain will
not come off.
Some
of the reasons for Celexa weight gain found on the Internet are absurd at best.
Examples:
"Celexa has been associated with slight weight gain, but it’s thought that the
drug itself doesn’t cause this effect. Rather, the weight increase is likely due
to improved appetite from taking the drug. A better appetite can cause you to
eat more, leading to increased body weight." Source "Monitor your diet and get
exercise"
Source
The
list goes on and on. If diet and exercise worked for Celexa weight gain you
would not be doing a Google search for answers to the Celexa weight gain. Dr.
Tracey Marks, M.D. provides a YouTube video detailing how histamine receptor H1
can be the cause of antidepressant induced weight gain. Click here to view. The
Dr. would have been well served to continue her research. The Harper Method is
based upon the over activation of the JNK gene. Histamine as well as other
substances make this JNK gene become to active. Antidepressants cause the JNK
gene to become over active and is the direct source of the antidepressant weight
gain. Reduce the activation of the JNK gene and histamine H1 receptor is a mute
point. If humans did not have the JNK gene there is no possible way for a human
to become overweight. How this method works
You
need to start reducing the activation of the JNK gene as a first step. The JNK
gene is associated with weight gain and all antidepressants induce the
activation of the JNK gene. Until you do this; all of the exercise and dieting
in the world will be of no use. You likely know this already. How this is done
is simple. After 22 years of research two supplements have been formulated in
reduce the activation of the JNK1, JNK 2 and to slightly reduce the activation
of the JNK 3. Additionally, other proteins that reside upstream of the JNK's
need to be silenced and these are silenced with the supplements as well. Foods;
you should start eliminating foods with preservatives as your first diet change.
Exercise; if you do not get any exercise, it is time to start with walking. At
least 3 walks a week, with each walk for 20 minutes. The two supplements setup
your body to lose the weight gain caused by Celexa but you also need to do the
normal things that help you lose weight; diet and exercise. I am assuming you
have already tried diet and exercise to combat the Celexa weight gain, without
Celexa weight loss success. After 22 years of research there is now a simple
solution. Two supplements have been formulated to decrease the activation of the
JNK gene and provide you, for the first time, the chance to lose the Celexa
weight gain. They are called JNK 5 and Optimum Solace. The JNK 5 provides the
nutrients to reduce the activation of the JNK gene and also the proteins that
reside upstream of the JNK that continue to activate this gene. The Optimum
Solace also reduces the JNK activation and the saffron in the supplement help
bring you a relaxed calm feeling. Without making you tired. These two
supplements are also sold at a massively reduced price so the majority can
afford their benefits. It is time to take control back and be the you, you want
to be.
What you need to do next to reverse Celexa weight
gain click here
(1)
Jan-Feb 2015;37(1):46-8. doi: 10.1016/j.genhosppsych.2014.10.011. Epub 2014 Oct
31. Weight gain and associated factors in patients using newer antidepressant
drugs Objective: The aim of the present study was to examine weight gain and its
association with clinical and sociodemographic characteristics in patients using
newer antidepressants. Methods: The study had a cross-sectional design. A total
of 362 consecutive psychiatric patients taking antidepressant drugs for 6 to 36
months were included in the study. Results: The prevalence rate of weight gain
was 55.2%; 40.6% of the patients had a weight gain of 7% or more compared to the
baseline. Overall, antidepressant use was significantly related to increased
body weight. Specifically, citalopram, escitalopram, sertraline, paroxetine,
venlafaxine, duloxetine and mirtazapine, but not fluoxetine, were associated
with significant weight gain. Multivariate logistic regression analysis
indicated that lower education status, lower body mass index at the onset of
antidepressant use and family history of obesity were independent predictors of
weight gain ≥7% compared to the baseline. Conclusions: The study results suggest
that patients who take newer antidepressants might have significant problems
related to body weight. Keywords: Antidepressants; Body mass index; Weight gain.
(2)
JNK at the crossroad of obesity, insulin resistance, and cell stress response
Background: The cJun-N-terminal-kinase (JNK) plays a central role in the cell
stress response, with outcomes ranging from cell death to cell proliferation and
survival, depending on the specific context. JNK is also one of the most
investigated signal transducers in obesity and insulin resistance, and studies
have identified new molecular mechanisms linking obesity and insulin resistance.
Emerging evidence indicates that whereas JNK1 and JNK2 isoforms promote the
development of obesity and insulin resistance, JNK3 activity protects from
excessive adiposity. Furthermore, current evidence indicates that JNK activity
within specific cell types may, in specific stages of disease progression,
promote cell tolerance to the stress associated with obesity and type-2
diabetes. Scope of review: This review provides an overview of the current
literature on the role of JNK in the progression from obesity to insulin
resistance, NAFLD, type-2 diabetes, and diabetes complications. Major
conclusion: Whereas current evidence indicates that JNK1/2 inhibition may
improve insulin sensitivity in obesity, the role of JNK in the progression from
insulin resistance to diabetes, and its complications is largely unresolved. A
better understanding of the role of JNK in the stress response to obesity and
type-2 diabetes, and the development of isoform-specific inhibitors with
specific tissue distribution will be necessary to exploit JNK as possible drug
target for the treatment of type-2 diabetes. Keywords: Autophagy; Diabetes;
Endoplasmic eeticulum stress; Inflammation; MAPK; Oxidative stress.
(3)
Role of c-Jun N-terminal Kinase (JNK) in Obesity and Type 2 Diabetes Obesity has
been described as a global epidemic and is a low-grade chronic inflammatory
disease that arises as a consequence of energy imbalance. Obesity increases the
risk of type 2 diabetes (T2D), by mechanisms that are not entirely clarified.
Elevated circulating pro-inflammatory cytokines and free fatty acids (FFA)
during obesity cause insulin resistance and ß-cell dysfunction, the two main
features of T2D, which are both aggravated with the progressive development of
hyperglycemia. The inflammatory kinase c-jun N-terminal kinase (JNK) responds to
various cellular stress signals activated by cytokines, free fatty acids and
hyperglycemia, and is a key mediator in the transition between obesity and T2D.
Specifically, JNK mediates both insulin resistance and ß-cell dysfunction, and
is therefore a potential target for T2D therapy. Keywords: JNK; c-Jun N-terminal
kinase; glucotoxicity; inflammation; insulin resistance; lipotoxicity; obesity;
type 2 diabetes.
(4)
Adipocyte-Macrophage Cross-Talk in Obesity Obesity is characterized by the
chronic low-grade activation of the innate immune system. In this respect,
macrophage-elicited metabolic inflammation and adipocyte-macrophage interaction
has a primary importance in obesity. Large amounts of macrophages are
accumulated by different mechanisms in obese adipose tissue. Hypertrophic
adipocyte-derived chemotactic monocyte chemoattractant protein-1 (MCP-1)/C-C
chemokine receptor 2 (CCR2) pathway also promotes more macrophage accumulation
into the obese adipose tissue. However, increased local extracellular lipid
concentrations is a final mechanism for adipose tissue macrophage accumulation.
A paracrine loop involving free fatty acids and tumor necrosis factor-alpha
(TNF-alpha) between adipocytes and macrophages establishes a vicious cycle that
aggravates inflammatory changes in the adipose tissue. Adipocyte-specific
caspase-1 and production of interleukin-1beta (IL-1beta) by macrophages; both
adipocyte and macrophage induction by toll like receptor-4 (TLR4) through
nuclear factor-kappaB (NF-kappaB) activation; free fatty acid-induced and
TLR-mediated activation of c-Jun N-terminal kinase (JNK)-related
pro-inflammatory pathways in CD11c+ immune cells; are effective in macrophage
accumulation and in the development of adipose tissue inflammation. Old
adipocytes are removed by macrophages through trogocytosis or sending an "eat
me" signal. The obesity-induced changes in adipose tissue macrophage numbers are
mainly due to increases in the triple-positive CD11b+ F4/80+ CD11c+ adipose
tissue macrophage subpopulation. The ratio of M1-to-M2 macrophages is increased
in obesity. Furthermore, hypoxia along with higher concentrations of free fatty
acids exacerbates macrophage-mediated inflammation in obesity. The metabolic
status of adipocytes is a major determinant of macrophage inflammatory output.
Macrophage/adipocyte fatty-acid-binding proteins act at the interface of
metabolic and inflammatory pathways. Both macrophages and adipocytes are the
sites for active lipid metabolism and signaling. Keywords: C-C chemokine
receptor 2 (CCR2); Chemokine (C-C motif) ligand 2
(CCL2); Free fatty acids; Hypoxia-inducible factor-1 alpha (HIF-1alpha);
Insulin-like growth factor-1 (IGF1); Interleukin-6 (IL-6); M1 macrophages; M2
macrophages; Monocyte chemoattractant protein-1 (MCP-1); NOD-like receptor (NLR)
family protein (NLRP3); Obesity; Toll like receptor 4 (TLR4); Tumor necrosis
factor-alpha (TNF-alpha); Visceral adipose tissue.
(5)
The Role of JNk Signaling Pathway in Obesity-Driven Insulin Resistance Obesity
is not only closely related to insulin resistance but is one of the main factors
leading to the formation of Type 2 Diabetes (T2D) too. The c-Jun N-terminal
kinase (JNK) family is a member of the mitogen-activated protein kinase (MAPK)
superfamily. JNK is also one of the most investigated signal transducers in
obesity and insulin resistance. JNK-centric JNK signaling pathway can be
activated by growth factors, cytokines, stress responses, and other factors.
Many researches have identified that the activated phosphorylation JNK
negatively regulates insulin signaling pathway in insulin resistance which can
be simultaneously regulated by multiple signaling pathways related to the JNK
signaling pathway. In this review, we provide an overview of the composition of
the JNK signaling pathway, its regulation of insulin signaling pathway, and the
relationship between the JNK signaling pathway and other pathways in insulin
resistance. Keywords: JNK signaling pathway; insulin resistance; obesity; type 2
diabetes.
(6)
JNK expression by macrophages promotes obesity-induced insulin resistance and
inflammation The cJun NH(2)-terminal kinase (JNK) signaling pathway contributes
to inflammation and plays a key role in the metabolic response to obesity,
including insulin resistance. Macrophages are implicated in this process. To
test the role of JNK, we established mice with selective JNK deficiency in
macrophages. We report that feeding a high-fat diet to control and JNK-deficient
mice caused similar obesity, but only mice with JNK-deficient macrophages
remained insulin-sensitive. The protection of mice with macrophage-specific JNK
deficiency against insulin resistance was associated with reduced tissue
infiltration by macrophages. Immunophenotyping demonstrated that JNK was
required for pro-inflammatory macrophage polarization. These studies demonstrate
that JNK in macrophages is required for the establishment of obesity-induced
insulin resistance and inflammation. (7) The Pathogenesis of Obesity-Associated
Adipose Tissue Inflammation Obesity is characterized by a state of chronic,
low-grade inflammation. However, excessive fatty acid release may worsen adipose
tissue inflammation and contributes to insulin resistance. In this case, several
novel and highly active molecules are released abundantly by adipocytes like
leptin, resistin, adiponectin or visfatin, as well as some more classical
cytokines. Most likely cytokines that are released by inflammatory cells
infiltrating obese adipose tissue are such as tumor necrosis factor-alpha
(TNF-alpha), interleukin 6 (IL-6), monocyte chemoattractant protein 1 (MCP-1)
(CCL-2) and IL-1. All of those molecules may act on immune cells leading to
local and generalized inflammation. In this process, toll-like receptor 4
(TLR4)/phosphatidylinositol-3'-kinase (PI3K)/Protein kinase B (Akt) signaling
pathway, the unfolded protein response (UPR) due to endoplasmic reticulum (ER)
stress through hyperactivation of c-Jun N-terminal Kinase (JNK) -Activator
Protein 1 (AP1) and inhibitor of nuclear factor kappa-B kinase beta
(IKKbeta)-nuclear factor kappa B (NF-kappaB) pathways play an important role,
and may also affect vascular endothelial function by modulating vascular nitric
oxide and superoxide release. Additionally, systemic oxidative stress,
macrophage recruitment, increase in the expression of NOD-like receptor (NLR)
family protein (NLRP3) inflammasone and adipocyte death are predominant
determinants in the pathogenesis of obesity-associated adipose tissue
inflammation. In this chapter potential involvement of these factors that
contribute to the adverse effects of obesity are reviewed. Keywords: Adipose
tissue macrophages (ATMs); Autophagy; Ceramide; Endoplasmic reticulum stress;
Inducible nitric oxide synthase (iNOS); Lipotoxicity; M1 adipose tissue
macrophages; Macrophage migration inhibitory factor (MIF); Monocyte
chemoattractant protein 1 (MCP-1); Nuclear factor kappa B (NF-kappaB); Obesity;
Reactive oxygen species (ROS); Saturated fatty acid; Toll-like receptor 4
(TLR4); Tumor necrosis factor alpha (TNF-alpha); Vascular endothelial growth
factor (VEGF).