The prognosis of ICC is dictated mainly by tumor factors. Future research could focus on the usefulness of adjuvant treatment as well as other multidisciplinary treatment modalities.
Metabolic syndrome comprises a cluster of related disorders that includes obesity, glucose intolerance, insulin resistance, dyslipidemia, and fatty liver. Recently, gut-derived chronic endotoxemia has been identified as a primary mediator for triggering the low-grade inflammation responsible for the development of metabolic syndrome. In the present study we examined the role of the small intestinal brush-border enzyme, intestinal alkaline phosphatase (IAP), in preventing a high-fat-diet-induced metabolic syndrome in mice. We found that both endogenous and orally supplemented IAP inhibits absorption of endotoxin (lipopolysaccharides) that occurs with dietary fat, and oral IAP supplementation prevents as well as reverses metabolic syndrome. Furthermore, IAP supplementation improves the lipid profile in mice fed a standard, low-fat chow diet. These results point to a potentially unique therapy against metabolic syndrome in at-risk humans.etabolic syndrome is a complex syndrome composed of a cluster of disorders that includes obesity, glucose intolerance, insulin resistance, abnormal lipid profile (dyslipidemia), fatty liver, and hypertension (1, 2). Metabolic syndrome leads to type 2 diabetes, atherosclerosis, and nonalcoholic fatty liver disease (1, 2). Approximately 35-39% of the US population suffers from the syndrome (3). This epidemic of metabolic syndrome has devastating consequences in terms of mortality, morbidity, and total healthcare expenditures (4).Recently, "metabolic endotoxemia" has been proposed to be central to the pathogenesis of metabolic syndrome. The Gramnegative bacterial cell wall component lipopolysaccharide (LPS) is known as endotoxin, and metabolic endotoxemia is defined as a two-to threefold persistent increase in circulating endotoxin concentrations above the normal levels (5). Metabolic endotoxemia leads to low-grade systemic inflammation as evidenced by increased serum levels of tumor necrosis factor-alpha (TNF-α), interleukin (IL)-1, and IL-6 (5). It is well recognized that chronic inflammation causes damage to pancreatic beta cells (6), hepatocytes (7), and vascular endothelial cells (8), and dysfunction of these cells is thought to contribute to metabolic syndrome.A high-fat diet (HFD) has been shown to cause metabolic endotoxemia in animals and humans (5, 9), but the underlying molecular mechanisms remain incompletely understood. Ghoshal et al. (10) demonstrated that intestinal epithelial cells (enterocytes) internalize LPS from the apical surface, which is then transported to the Golgi apparatus where it complexes with chylomicrons, the lipoproteins that transport the absorbed longchain fatty acids in enterocytes. The chylomicron-LPS complex is then secreted into mesenteric lymph and makes its way into the systemic circulation. Excess chylomicron formation during highfat feeding leads to prolonged chylomicronemia (complexed with LPS) that ultimately induces systemic inflammation. Also, it has been shown that an HFD causes local intestinal inflammation (11). Systemic and local inf...
SUMMARY Cachexia is a wasting syndrome associated with elevated basal energy expenditure and loss of adipose and muscle tissues. It accompanies many chronic diseases including renal failure and cancer and is an important risk factor for mortality. Our recent work demonstrated that tumor-derived PTHrP drives adipose tissue browning and cachexia. Here, we show that PTH is involved in stimulating a thermogenic gene program in 5/6 nephrectomized mice that suffer from cachexia. Fat-specific knockout of PTHR blocked adipose browning and wasting. Surprisingly, loss of PTHR in fat tissue also preserved muscle mass and improved muscle strength. Similarly, PTHR knockout mice were resistant to cachexia driven by tumors. Our results demonstrate that PTHrP and PTH mediate wasting through a common mechanism involving PTHR and there exists an unexpected crosstalk mechanism between wasting of fat tissue and skeletal muscle. Targeting the PTH/PTHrP pathway may have therapeutic uses in humans with cachexia.
Background Well-differentiated thyroid cancer (WDTC) is a prevalent disease, which is increasing in incidence faster than any other cancer. Substantial direct medical care costs are related to the diagnosis and treatment of newly diagnosed patients as well as the ongoing surveillance of patients who have a long life expectancy. Prior analyses of the aggregate healthcare costs attributable to WDTC in the U.S. have not been reported. Methods A stacked cohort cost analysis was performed on the U.S. population from 1985-2013 to estimate the number of WDTC survivors in 2013. Incidence rates, cancer-specific, and overall survival were based on Surveillance, Epidemiology, and End Results data. We then estimated current and projected direct medical care costs attributable to the care of WDTC patients. Health-care related costs and event probabilities were based on Medicare reimbursement schedules and the literature. Results Estimated overall societal cost of WDTC care in 2013 for all U.S. patients diagnosed after 1985 is $1.6 billion. Diagnosis, surgery, and adjuvant therapy for newly diagnosed patients (41%) constitutes the greatest proportion of costs, followed by surveillance of survivors (37%) and non-operative deaths costs attributable to thyroid cancer care (22%). Projected 2030 costs (in 2013 $US) based on current incidence trends exceed $3.5 billion. Conclusion Healthcare costs of WDTC are substantial. Unlike other cancers, the majority of the cost is incurred in the initial and continuing phases of care. With the projected increasing incidence, population, and survival trends, costs will continue to escalate.
The intestinal microbiota plays a pivotal role in maintaining human health and well-being. Previously, we have shown that mice deficient in the brush-border enzyme intestinal alkaline phosphatase (IAP) suffer from dysbiosis and that oral IAP supplementation normalizes the gut flora. Here we aimed to decipher the molecular mechanism by which IAP promotes bacterial growth. We used an isolated mouse intestinal loop model to directly examine the effect of exogenous IAP on the growth of specific intestinal bacterial species. We studied the effects of various IAP targets on the growth of stool aerobic and anaerobic bacteria as well as on a few specific gut organisms. We determined the effects of ATP and other nucleotides on bacterial growth. Furthermore, we examined the effects of IAP on reversing the inhibitory effects of nucleotides on bacterial growth. We have confirmed that local IAP bioactivity creates a luminal environment that promotes the growth of a wide range of commensal organisms. IAP promotes the growth of stool aerobic and anaerobic bacteria and appears to exert its growth promoting effects by inactivating (dephosphorylating) luminal ATP and other luminal nucleotide triphosphates. We observed that compared with wild-type mice, IAP-knockout mice have more ATP in their luminal contents, and exogenous IAP can reverse the ATP-mediated inhibition of bacterial growth in the isolated intestinal loop. In conclusion, IAP appears to promote the growth of intestinal commensal bacteria by inhibiting the concentration of luminal nucleotide triphosphates.
Endovascular treatment with fenestrated or/and branched stent-grafts is a new therapeutic option with encouraging results for patients considered unfit for conventional open repair. However, prolonged follow-up studies are needed in order to draw robust conclusions.
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