The Interest Sensitivity of Commercial Bank Equity Returns: New Evidence

Daniel T. Walz is an Associate Professor of Business Administration at Trinity University, San Antonio. Roger W. Spencer is Professor of Economics at Trinity University. San Antonio

Patogênese da encefalopatia hepática: um papel para os receptores de benzodiazepínicos?

A encefalopatia hepática (EH) é uma síndrome multifatorial, na qual a função do sistema nervoso central está alterada devido às conseqüências metabólicas da disfunção hepática. Os dois principais componentes das doenças hepáticas que levam à EH são a diminuição no número de hepatócitos funcionantes e o rearranjo vascular, que leva à diminuição na fração de sangue, efetivamente detoxificado pelo fígado. Os sintomas da EH podem variar de déficits cognitivos leves até o coma profundo. Algum grau de morte neuronal pode ser observado em pacientes com EH, como conseqüência da cirrose hepática, ou, na EH avançada, da presença de edema cerebral. No entanto, a maior parte da síndrome neurológica é reversível com a compensação da doença hepática. A etiologia da EH não é totalmente conhecida e trata-se, provavelmente, de um processo multifatorial. Inicialmente, as teorias apontavam para o acúmulo de neurotoxinas que prejudicariam a função neuronal. Mais recentemente, anormalidades em vários sistemas de neurotransmissão foram propostos como causas potencias da EH como, por exemplo, o aumento observado na neurotransmissão GABAérgica. Existe evidência de que este aumento esteja relacionado com o aumento da potenciação GABAérgica por substâncias de ação similar aos benzodiazepínicos, as quais se encontram aumentadas na EH. Com esta evidência em mente, foi tentada a terapia desta síndrome com flumazenil, um antagonista benzodiazepínico, o qual tem mostrado eficácia clínica em uma porcentagem variável de pacientes em estudos recentes. No entanto, ainda não há evidências conclusivas para sustentar uma relação causal entre o aumento de ligantes ao receptor de benzodiazepínicos e os sintomas da EH. É possível que esta relação exista em alguns, mas não em todos os pacientes com esta síndrome.Hepatic encephalopathy (HE) is a multifactorial syndrome in which the function of the central nervous system is impaired due to the metabolic consequences of liver disease. The two main components of liver pathology which lead to HE are the decrease in the number of functioning hepatocytes and the vascular rearrangement causing blood from the portal vein to bypass the liver. The symptoms of HE range from mild cognitive impairment to deep coma. Some degree of neuronal loss may be found in HE patients as a consequence of chronic cirrhosis and, in advanced HE, of brain edema; however, most of the HE syndrome is reversible with compensation of the liver disease. The pathogenesis of HE is not fully understood and  is likely to be multifactorial. The initial theories implicated accumulation of neurotoxins leading to an impairment of neuronal function. With better understanding of the physiology of neuroreceptors, abnormalities in several neurotransmission systems have been put forward as potential causes of HE, such as a reported increase in GABAergic neurotransmission. There is evidence that this enhancement is related to an increase in the potentiation of GABAergic action by ligands to the benzodiazepine receptor (BZR), which are known to be increased in liver disease. With this evidence in mind, therapy with the benzodiazepine antagonist flumazenil has been attempted in HE, yielding clinical benefit in a variable percentage of patients in recent studies. However, there is still a lack of evidence to support a causal relationship between increased levels of benzodiazepine agonist ligands and HE symptoms. It is feasible to think that this relationship exists in some but not all HE patients

Deep Brain Stimulation for Obesity: A Review and Future Directions

The global prevalence of obesity has been steadily increasing. Although pharmacotherapy and bariatric surgeries can be useful adjuvants in the treatment of morbid obesity, they may lose long-term effectiveness. Obesity result largely from unbalanced energy homeostasis. Palatable and densely caloric foods may affect the brain overlapped circuits involved with homeostatic hypothalamus and hedonic feeding. Deep brain stimulation (DBS) consists of delivering electrical impulses to specific brain targets to modulate a disturbed neuronal network. In selected patients, DBS has been shown to be safe and effective for movement disorders. We review all the cases reports and series of patients treated with DBS for obesity using a PubMed search and will address the following obesity-related issues: (i) the hypothalamic regulation of homeostatic feeding; (ii) the reward mesolimbic circuit and hedonic feeding; (iii) basic concepts of DBS as well as the rationale for obesity treatment; (iv) perspectives and challenges in obesity DBS. The small number of cases provides preliminary evidence for the safety and the tolerability of a potential DBS approach. The ventromedial (n = 2) and lateral (n = 8) hypothalamic nuclei targets have shown mixed and disappointing outcomes. Although nucleus accumbens (n = 7) targets were more encouraging for the outcomes of body weight reduction and behavioral control for eating, there was one suicide reported after 27 months of follow-up. The authors did not attribute the suicide to DBS therapy. The identification of optimal brain targets, appropriate programming strategies and the development of novel technologies will be important as next steps to move DBS closer to a clinical application. The identification of electrical control signals may provide an opportunity for closed-loop adaptive DBS systems to address obesity. Metabolic and hormonal sensors such as glycemic levels, leptin, and ghrelin levels are candidate control signals for DBS. Focused excitation or alternatively inhibition of regions of the hypothalamus may provide better outcomes compared to non-selective DBS. Utilization of the NA delta oscillation or other physiological markers from one or multiple regions in obesity-related brain network is a promising approach. Experienced multidisciplinary team will be critical to improve the risk-benefit ratio for this approach

Enhancement of blood-tumor barrier permeability by Sar-[D-Phe8]des-Arg9BK, a metabolically resistant bradykinin B1 agonist, in a rat C6 glioma model

BACKGROUND: While it is well known that bradykinin B2 agonists increase plasma protein extravasation (PPE) in brain tumors, the bradykinin B1 agonists tested thus far are unable to produce this effect. Here we examine the effect of the selective B1 agonist bradykinin (BK) Sar-[D-Phe8]des-Arg9BK (SAR), a compound resistant to enzymatic degradation with prolonged activity on PPE in the blood circulation in the C6 rat glioma model. RESULTS: SAR administration significantly enhanced PPE in C6 rat brain glioma compared to saline or BK (p < 0.01). Pre-administration of the bradykinin B1 antagonist [Leu8]-des-Arg (100 nmol/Kg) blocked the SAR-induced PPE in the tumor area. CONCLUSIONS: Our data suggest that the B1 receptor modulates PPE in the blood tumor barrier of C6 glioma. A possible role for the use of SAR in the chemotherapy of gliomas deserves further study