The relative balance between the quantity of white and brown adipose tissue can profoundly affect lipid storage and whole-body energy homeostasis. However, the mechanisms regulating the formation, expansion, and interconversion of these 2 distinct types of fat remain unknown. Recently, the lysosomal degradative pathway of macroautophagy has been identified as a regulator of cellular differentiation, suggesting that autophagy may modulate this process in adipocytes. The function of autophagy in adipose differentiation was therefore examined in the current study by genetic inhibition of the critical macroautophagy gene autophagy-related 7 (Atg7). Knockdown of Atg7 in 3T3-L1 preadipocytes inhibited lipid accumulation and decreased protein levels of adipocyte differentiation factors. Knockdown of Atg5 or pharmacological inhibition of autophagy or lysosome function also had similar effects. An adipocyte-specific mouse knockout of Atg7 generated lean mice with decreased white adipose mass and enhanced insulin sensitivity. White adipose tissue in knockout mice had increased features of brown adipocytes, which, along with an increase in normal brown adipose tissue, led to an elevated rate of fatty acid, β-oxidation, and a lean body mass. Autophagy therefore functions to regulate body lipid accumulation by controlling adipocyte differentiation and determining the balance between white and brown fat. IntroductionObesity is characterized by an expansion of adipose tissue mass resulting from increased adipocyte number and/or size. Lipids in the form of triglycerides (TG) accumulate in various anatomical locations that differ in several regards including whether they are composed primarily of white or brown adipocytes. These 2 distinct types of adipocytes differ in their lipid content and metabolic functions. White adipose tissue (WAT) serves the primary function of lipid storage in the fed state and with fasting releases fatty acids from the breakdown of TG into the circulation for muscle energy production. In contrast, brown adipose tissue (BAT) has more limited TG storage and does not secrete fatty acids but instead uses them for autonomous energy expenditure and heat generation (1). Although the amount of BAT in adult humans has been previously considered to be minimal, recent findings of significant concentrations of brown adipocytes in adult humans (2-5) have raised the possibility that the balance between WAT and BAT mass may be one factor that regulates the development of obesity and its severity (6). Manipulating the process of adipocyte differentiation in order to promote more BAT in place of WAT may therefore be a novel approach to the treatment of obesity and its associated problems (7).Factors determining the differential development of WAT versus BAT remain poorly defined. In mammals, WAT and BAT generally develop before birth, although in rodents, WAT develops postnatally (8). Recent studies suggest that these fat cell populations are not static and may in fact continue to undergo significant cell turnover (9)...
Ascites that does not respond or recurs after high-dose diuresis and sodium restriction should be considered refractory ascites. As cirrhosis advances, the escaping fluid overwhelms the lymphatic return. Decrease in renal plasma flow leads to increased sodium reabsorption at the proximal tubule leading to decreased responsiveness to loop diuretics and mineralocorticoid antagonists, which work distally. These complex hemodynamic alterations lead to refractory ascites. In refractory ascites, high-dose diuresis (400 mg of spironolactone and 160 mg of furosemide) and sodium restriction (<90 mmol/d) result in inadequate weight loss and sub optimal sodium excretion (<78 mmol/d). Further use of diuretics is limited by complications such as encephalopathy, azotemia, renal insufficiency, hyponatremia, and hyperkalemia. Therapy for refractory ascites is limited. The available therapies are repeated large volume paracentesis (LVP), transjugular intrahepatic portosystemic shunts, peritoneovenous shunts, investigational medical therapies, and liver transplantation. LVP with concomitant volume expanders is the initial treatment of choice. Transjugular intrahepatic portosystemic seems to be superior to LVP in reducing the need for repeated paracentesis and improves the quality of life. Several treatments that act at different steps in the pathogenesis of ascites are investigational, and some show promising results. Splanchnic and peripheral vasoconstrictors (Octreotide, Midodrine, and Terlipressin) increase effective arterial volume and decrease activation of the renin-angiotensin system with resultant increase in renal sodium excretion. Clonidine when given with spironolactone has been shown to cause rapid mobilization of ascites by significantly decreasing the sympathetic activity and renin-aldosterone levels. Natural aquaretics and synthetic V2 receptor antagonists (satavaptan) are being evaluated for mobilization of ascites by increasing the excretion of solute-free water. Liver transplantation remains the only definitive therapy for refractory ascites. Because refractory ascites is a poor prognostic sign, liver transplantation should be considered and incorporated early in the treatment plan.
Hepatic hydrothorax is defined as a pleural effusion in patients with liver cirrhosis in the absence of cardiopulmonary disease. The estimated prevalence among patients with liver cirrhosis is approximately 5-6%. The pathophysiology involves the passage of ascitic fluid from the peritoneal cavity to the pleural space through diaphragmatic defects. The diagnosis is made from clinical presentation and confirmed by diagnostic thoracentesis with pleural fluid analysis. The initial medical management is sodium restriction and diuretics, but liver transplantation provides the only definitive therapy. For patients who are not transplant candidates and those who await organ availability, other therapeutic modalities that are to be considered include transjugular intrahepatic portosystemic shunt placement, videoassisted thoracoscopic surgery repair, pleurodesis, and vasoconstrictors (eg, octreotide and terlipressin). The primary therapeutic goals are to reduce ascitic fluid production and improve symptoms to bridge the time for liver transplantation.
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