Introduction: the causal linkCardiovascular diseases (CVDs) are a major cause of morbidity and mortality throughout the world. In the United States, CVDs affect many racial or ethnic groups, and this fact has an extremely high cost that is estimated around $200 billion annually in healthcare services, drugs, and loss of productivity. Much of this burden is due to insufficient implementation of prevention strategies and poor control of atherosclerotic cardiovascular disease (ASCVD) risk factors in many adults (1,2). According to World Health Organization data, smoking determines 10% of all CVDs (3). Tobacco smoking usage causes approximately 6 million death per year throughout the world, in the United States almost 500,000 deaths can be attributed to smoking and about 10% of these deaths are caused from second-hand smoke exposure. Epidemiologic studies have supported the assumption that cigarette smoking increases the incidence of myocardial infarction and fatal coronary artery diseases (4). The increased risk of cardiovascular events has also been shown for low-tar cigarettes and smokeless tobacco. Even passive smoking is responsible for a 30% increased risk of ASCVD, a little less than half of the risk increase in active smokers that is around 80% (5,6). Ever since the Framingham study, the epidemiologic investigations have tried to identify people with a high likelihood for a future cardiovascular events in order to make actionable interventions to reduce the risk. The concept of "risk factors" was made popular by Kannel et Review Article on Improving Outcomes in Lung Cancer Through Early Diagnosis and Smoking Cessation
PurposeA phase III trial assessed the efficacy of palonosetron plus dexamethasone given once in preventing acute and delayed chemotherapy-induced nausea and vomiting (CINV) following a broad range of moderately emetogenic chemotherapy (MEC) regimens.MethodsThis multicentre, randomized, open-label, non-inferiority trial evaluated two different treatment groups. One group received palonosetron (0.25 mg intravenously) and dexamethasone (8 mg intravenously) before chemotherapy, while the other was administered the same regimen on day 1 followed by dexamethasone 8 mg orally on days 2 and 3. The primary endpoint was complete response (CR; defined as no emetic episodes and no rescue medication) during the overall phase (days 1–5 after chemotherapy initiation). The non-inferiority margin was predefined as a 15% difference between groups in the primary endpoint.ResultsOf 332 chemotherapy-naïve patients included in the intention-to-treat analysis, 65.1% were female, and 35.2% received anthracycline plus cyclophosphamide (AC)-based regimens. Overall CR rates were 67.5% for those administered dexamethasone only on day 1 (n = 166), and 71.1% for those also administered dexamethasone on days 2 and 3 (n = 166; difference −3.6% (95% confidence interval, −13.5 to 6.3)). CR rates were not significantly different between groups during the acute (0–24 h post-chemotherapy; 88.6% versus 84.3%; P = 0.262) and delayed phases (days 2–5; 68.7% versus 77.7%; P = 0.116).ConclusionsPalonosetron plus single-dose dexamethasone administered before common MEC regimens provide protection against acute and delayed CINV which is non-inferior to that of palonosetron plus dexamethasone for 3 days. However, the major benefit of the single-day regimen occurs in patients receiving non-AC MEC regimens.
In this review the main characteristics, i.e., structure, function and gene expression, of the different mucins are discussed. Mucin-type molecules consist of a core protein moiety (apomucin) where a number of carbohydrate chains are attached to serines and threonines by glycosidic bonds. O-linked carbohydrates form up to 80% of the molecule and the length of the glucidic side chains varies from one to more than 20 residues. At least eight mucin-like genes have been isolated so far, and the main characteristic is the presence of a central domain composed of a variable number of "tandem repeats". The sequence homology of the central domain among the different members of the mucin-type family is limited, indicating that this internal domain is unique for each mucin. Thanks to the integrated results of genetic, immunological and biochemical studies, it is now possible to identify eight apomucin genes, namely MUC1, MUC2, MUC3, MUC4, MUC5AC, MUC5B, MUC6 and MUC7. MUC1 is the best characterized mucin and it is expressed on the apical surface of most polarized epithelial cells. The MUC1 gene has been cloned and sequenced. The MUC2 gene encodes a typical secretory gel-forming mucin which represents the predominant form in human intestinal and colon tissues. Another intestinal mucin is MUC3. The MUC4, MUC5AC and MUC5B genes have been isolated from a bronchial tissue cDNA library. The MUC4 and MUC5AC genes are mainly expressed in the respiratory tract, in gastric and reproductive mucosa, while MUC5B is highly detectable only in the bronchial glands. The MUC6 gene is expressed by gastric tissue and, recently, MUC7 has been cloned and sequenced using a salivary cDNA library.
Epithelioid sarcoma (ES) is a rare disease representing <1% of soft tissue sarcomas. Current therapies are based on anthracycline alone or in combination with ifosfamide or other cytotoxic drugs. ES is still characterized by a poor prognosis with high rates of recurrence. Indeed, for years, ES survival rates have remained stagnant, suggesting that conventional treatments should be revised and improved. New therapeutic approaches are focused to target the key regulators of signaling pathways, the causative markers of tumor pathophysiology. To this end, we selected, among the drugs to which an ES cell line is highly sensitive, those that target signaling pathways known to be dysregulated in ES. In particular, we found a key role for GSK-3β, which results in up-regulation in tumor versus normal tissue samples and associated to poor prognosis in sarcoma patients. Following this evidence, we evaluated CHIR99021, a GSK-3 inhibitor, as a potential drug for use in ES therapy. Our data highlight that, in ES cells, CHIR99021 induces cell cycle arrest, mitotic catastrophe (MC) and autophagic response, resulting in reduced cell proliferation. Our results support the potential efficacy of CHIR99021 in ES treatment and encourage further preclinical and clinical studies.
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