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Symposium for Patients & Caregivers. Hypothalamic Obesity. Constantine Stephen Djedjos MD Pediatric Endocrinologist Phoenix Children’s Hospital. Hypothalamic Obesity. Significant advances in basic science have greatly improved our understanding of the mechanisms of hypothalamic obesity
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HypothalamicObesity Constantine Stephen Djedjos MD Pediatric Endocrinologist Phoenix Children’s Hospital
Hypothalamic Obesity • Significant advances in basic science have greatly improved our understanding of the mechanisms of hypothalamic obesity • Unfortunately, these advances have not yet translated into therapeutic advances for patients, many of whom are struggling with the nightmare of disordered eating and obesity
Hypothalamic Obesity • Weight gain and obesity are common long term problems in patients with structural hypothalamic damage • Exact incidence is unknown. Each individual cause is rare and taken in aggregate HyOb is still relatively uncommon • Can be due to structural or genetic abnormalities • Significant percentage of patients gain weight after hypothalamic surgery
Hypothalamic Obesity • First case reports of hypothalamic tumors resulting in obesity published around the turn of the 20th century • Initially identified the ventromedial hypothalamus (VMH) associated with polyphagia • Later demonstrated polyphagia is sufficient but not required • Later identification of peripheral and central neurochemicals and cytokines
Hypothalamus Stanford CNS Visual Perspectives
Anatomy • Only 4ml in volume • Organized into discrete nuclei or collections of similar neurons • ‘Dual-Center’ hypothesis – experimental lesions in the medial (midline) hypothalamus result in weight gain while lesions in the lateral areas result in wasting
Hypothalamic Nuclei Michigan State University Brain Bank and NSF
Mechanism • The hypothalamus controls energy balance by integrating the neuroendocrine signals from other brain areas and the periphery • Controls energy intake by regulating appetite • Controls energy expenditure by regulating metabolism via sympathetic and parasympathetic nervous system
Appetite • Hypothalamus receives signals from periphery • Hypothalamus controls appetite by balancing orexigenic and anorexegenic signals • Appetite regulated by the arcuate nucleus (ARC) by 2 types of neurons • AGRP/NPYY neurons stimulate appetite (orexigenic) • POMC/CART neurons signal satiety (anorexegenic) via MC4R receptor
Appetite Nutr J. 2012 Apr 10;11:22. Gut-central nervous system axis is a targetfor nutritional therapies. Pimentel GD, Micheletti TO, Pace F, Rosa JC, Santos RV, Lira FS.
Metabolism • Hypothalamus controls metabolism by balancing sympathetic and parasympathetic signals • Hypothalamus via the locus ceruleus stimulates sympathetic nervous system (Fight or Flight) which increases metabolism • Stimulates via the vagus nerve the parasympathetic nervous system which lowers metabolism
Metabolism • VMH receives peripheral signals • VMH increases sympathetic tone or parasympathetic tone • Higher parasympathetic tone results in higher insulin
Peripheral Signals • Leptin produced by fat cells signals fat storage • Adiponectin is decreased in obesity • Ghrelin stimulates appetite and food intake and secreted from stomach • Many others
Mechanism • In HyOb damage to the hypothalamus results in altered appetite and metabolism • Increased appetite due to damage to POMC neurons and resulting in decreased MC4R signaling • Decreased metabolism from increased parasympathetic tone and decreased sympathetic tone resulting in decreased resting energy expenditure, elevated insulin • Leptin resistance and Ghrelin have a role as well
Treatment • For mild-moderately overweight patient without overt food seeking or hyperphagic behaviors, we should focus on diet and lifestyle modification • Requires full participation from the family and the school in order to make the home and school environments more conducive to weight loss
Treatment • More severe HyOb is often refractory to diet and lifestyle • Behavior therapy • Pharmacologic therapy • Surgical therapy
Pharmacologic Therapy • No standard intervention and no medication has been proven successful in randomized clinical trials • Due in part to small numbers of patients and also ineffectiveness of therapy • Because of decreased sympathetic activity and decreased POMC/CART signaling, treatment with amphetamine derivatives has been considered
Pharmacologic Therapy • Dextroamphetamine started 10months post surgery and lasting 24 months in CP patients showed less weight gain and stabilization of BMI • Treatment with ephedrine/caffeine has also showed some promise • Also had increased activity and wakefulness • No large trials • Polyphagia not significantly reduced likely because of damage to responsive neurons
Pharmacologic Therapy • Leptin ‘resistance’ is possible cause of obesity • Leptin therapy has been ineffective for weight loss • Once forced weight loss is achieved, leptin supplementation has resulted in better success in weight maintenance
Pharmacologic Therapy • Increased parasympathetic activity via vagus nerve activity results in insulin secretion • Insulin is anabolic and contributes to appetite and weight gain • Treatments aimed at lowering vagus nerve activity and insulin secretion have been considered • Treatment with metformin which lowers insulin levels has been ineffective in HyOb
Pharmacologic Therapy • Sandostatin is a medication that lowers insulin secretion • Initial trial with small number of patients was successful • Larger trial demonstrated no benefit • Much controversy about the discordant results • Vagus nerve blockade is being considered and is in early trials
Pharmacologic Therapy • Increased parasympathetic activity results in lower thyroid hormone levels and very small trials have demonstrated some benefit with treatment • Increased 11-beta hydroxysteroid dehydrogenase activity is also seen in HyOb patients but no selective inhibitor is yet available • Concomitant growth hormone deficiency is often seen, despite normal growth, and treatment with GH has been tried
Pharmacologic Therapy • Unlike patients with GH from other causes, treatment of HyOb patients with GH did NOT result in weight loss or changes in body fat distribution • Surgical therapy has had mixed results
Surgical Therapy • Criteria are unclear • Some have suggested BMI >40 (above 99.5%) • Failed 6-12 month organized weight loss attempt • Skeletal and anatomic maturity • Able to commit to rigorous psychologic and medical evaluation pre and post op • Willing to participate in a multidisciplinary program
Surgical Therapy • Restrictive procedures • Gastric banding • Adjustable band placed around the stomach • Poor weight loss and frequent complications • Sleeve Gastrectomy • Removal of part of the stomach • Not enough evidence yet with HyOb but appears promising
Surgical Therapy • Malabsorption procedures • Gastric bypass • Stomach is bypassed surgically • Restrictive and malabsorptive component • Excellent weight loss but higher complications • No significant experience with HyOb • Duodenal switch • Severe malabsorption and not routinely performed
Bariatric Surgery Complications • Operative mortality varies • Leaks, strictures, infection, blood clots, hernia, obstruction, nausea, vomiting have all been reported • Nutritional deficiencies from malabsorption are not uncommon especially iron, b12, fat soluable vitamins (ADEK), trace minerals • Dumping syndrome
Conclusions • HyOb is a common, frustrating complication of hypothalamic disease and treatments • Polyphagia and decreased metabolism play a role • Advances in the last 10 years in basic science have helped unravel many of the mechanisms • Treatment has lagged behind but still some promising therapies are being considered • Behavior therapy and exercise are the cornerstones for current treatment
References • A. Bereket et al Hypothalamic obesity in children Obesity reviews 2000 13,780-798 • J. Pinkney et al Hypothalamic obesity in humans: what do we know and what can be done? Obesity reviews 2002 3, 27-34 • R. Lustig Hypothalamic obesity after craniopharyngioma: mechanisms, diagnosis, and treatment • https://www.msu.edu/~brains/brains/human/hypothalamus/index.html • Babinski, J Tumeur du corps pituitaire sans acromegalie et avec arret developpment des organes de genitaux Rev Neurol 1900; 8,531-534 • Zhang Y et al Positional cloning of the mouse obese gene and its human homologue Nature 1994; 372,425-432 • Kreir et al Selective parasympathetic innervation of subcutaneous and intra-abdominal fat – functional implications J. Clin Invest 2002;110, 1243-1250 • Lustig RH et alHypothalamic obesity in children caused by cranial insult: altered glucose and insulin dynamics, and reversal by a somatostatin agonist. J Pediatr 1999;135: 162–168. • Lustig RH, Hinds PS, Ringwald-Smith K et al. Octreotide therapy of pediatric hypothalamic obesity: a double-blind, placebo-controlled trial. J Clin Endocrinol Metabol 2003; 88: 2586–2592. • Mason PW, Krawiecki N, Meacham LR. The use of dextroamphetamine to treat obesity and hyperphagia in children treated for craniopharyngioma. Arch Pediatr Adolesc Med 2002; 156:887–892. • Ismail D, O’Connell MA, Zacharin MR. Dexamphetamine use for management of obesity and hypersomnolence following hypothalamic injury. J Pediatr Endocrinol Metab 2006; 19: 129–134. • Greenway FL, Bray GA. Treatment of hypothalamic obesity with caffeine and ephedrine. Endocr Pract 2008; 14: 697–703. • Danielsson P, Janson A, Norgren S, Marcus C. Impact of sibutramine therapy in children with hypothalamic obesity or obesity with aggravating syndromes. J Clin Endocrinol Metab 2007; 92: 4101–4106. • Weiss R. [WWW document]. URL http://clinicaltrials.gov/ ct2/show/NCT00076362 (accessed January 2012).
References • Aslan IR, Ranadive SA, Ersoy BA, Rogers SJ, Lustig RH,Vaisse C. Bariatric surgery in a patient with complete MC4R deficiency. Int J Obes 2011; 35: 457–461. • Lanthaler M, Aigner F, Kinzl J, Sieb M, Cakar-Beck F, Nehoda H. Long-term results and complications following adjustable gastric banding. Obes Surg 2010; 20: 1078–1085. • Milone L, Strong V, Gagner M. Laparoscopic sleeve gastrectomy is superior to endoscopic intragastric balloon as a first stage procedure for the super-obese patient (BMI > 50). Obes Surg 2005; 15: 612–617. • Himpens J, Dapri G, Cadiere GB. A prospective randomized study between laparoscopic gastric banding and laparoscopic isolated sleeve gastrectomy: results after 1 and 3 years. Obes Surg2006; 16: 1450–1456. • Baltasar A, Serra C, Bou R, Bengochea M, Andreo L. Sleeve gastrectomy in a 10-year-old Child. Obes Surg 2008; 18:733–736. • Dan D, Harnanan D, Seetahal S, Naraynsingh V, Teelucksingh S. Bariatric surgery in the management of childhood obesity: should there be an age limit? Obes Surg 2010; 20: 114–117. • Ramos A, Neto MG, Galvao M, Evangelista LF, Campos JM, Ferraz A. Laparoscopic greater curvature plication: initial results of an alternative restrictive bariatric procedure. Obes Surg 2010; 20: 913–918. • Sugerman HJ, Sugerman EL, DeMaria EJ et al. Bariatric surgery for severely obese adolescents. J Gastrointest Surg 2003; 7: 102–107.
A Special Thanks to our Sponsors • Aesculap • Barrow Neurological Institute @ St. Joseph’s Hospital • Barrow Neurological Institute @ Phoenix Children’s Hospital • Great Council for the Improved • Hope for Hypothalamic Hamartoma Foundation • KARL STORZ Endoskope