Gold-Based Nanoplataform for the Treatment of Anaplastic Thyroid Carcinoma: A Step Forward.

Anaplastic thyroid carcinoma (ATC) is a very rare subtype of thyroid carcinoma and one of the most lethal malignancies. Poor prognosis is mainly associated with its undifferentiated nature, inoperability, and failing to respond to the typically used therapies for thyroid cancer. Photothermal Therapy (PTT) entails using light to increase tissues' temperature, leading to hyperthermia-mediated cell death. Tumours are more susceptible to heat as they are unable to dissipate it. By using functionalized gold nanoparticles (AuNPs) that transform light energy into heat, it is possible to target the heat to the tumour. This study aims to formulate ATC-targeted AuNPs able to convert near-infrared light into heat, for PTT of ATC. Different AuNPs were synthetized and coated. Size, morphology, and surface plasmon resonances band were determined. The optimized coated-AuNPs were then functionalized with ligands to assess ATC's specificity. Safety, efficacy, and selectivity were assessed in vitro. The formulations were deemed safe when not irradiated (>70% cell viability) and selective for ATC. However, when irradiated, holo-transferrin-AuNPs were the most cytotoxic (22% of cell viability). The biodistribution and safety of this formulation was assessed in vivo. Overall, this novel formulation appears to be a highly promising approach to evaluate in a very near future.

Anaplastic thyroid cancer: How far can we go?

Globally, thyroid cancer accounts for 2 % of all cancer diagnoses, and can be classified as well-differentiated or undifferentiated. Currently, differentiated thyroid carcinomas have good prognoses, and can be treated with a combination of therapies, including surgical thyroidectomy, radioactive iodine therapy and hormone-based therapy. On the other hand, anaplastic thyroid carcinoma, a subtype of undifferentiated thyroid carcinoma characterized by the loss of thyroid-like phenotype and function, does not respond to either radioactive iodine or hormone therapies. In most cases, anaplastic thyroid carcinomas are diagnosed in later stages of the disease, deeming them inoperable, and showing poor response rates to systemic chemotherapy. Recently, treatment courses using multiple-target agents are being explored and clinical trials have shown very promising results, such as overall survival rates, progression-free survival and tumor shrinkage. This review is focused on thyroid carcinomas, with particular focus on anaplastic thyroid carcinoma, exploring its undifferentiated nature. Special interest will be given to the treatment approaches currently available and respective obstacles or drawbacks. Our purpose is to contribute to understand why this malignancy presents low responsiveness to current treatments, while overviewing novel therapies and clinical trials.

How Can Biomolecules Improve Mucoadhesion of Oral Insulin? A Comprehensive Insight using Ex-Vivo, In Silico, and In Vivo Models.

Currently, insulin can only be administered through the subcutaneous route. Due to the flaws associated with this route, it is of interest to orally deliver this drug. However, insulin delivered orally has several barriers to overcome as it is degraded by the stomach's low pH, enzymatic content, and poor absorption in the gastrointestinal tract. Polymers with marine source like chitosan are commonly used in nanotechnology and drug delivery due to their biocompatibility and special features. This work focuses on the preparation and characterization of mucoadhesive insulin-loaded polymeric nanoparticles. Results showed a suitable mean size for oral administration (<600 nm by dynamic laser scattering), spherical shape, encapsulation efficiency (59.8%), and high recovery yield (80.6%). Circular dichroism spectroscopy demonstrated that protein retained its secondary structure after encapsulation. Moreover, the mucoadhesive potential of the nanoparticles was assessed in silico and the results, corroborated with ex-vivo experiments, showed that using chitosan strongly increases mucoadhesion. Besides, in vitro and in vivo safety assessment of the final formulation were performed, showing no toxicity. Lastly, the insulin-loaded nanoparticles were effective in reducing diabetic rats' glycemia. Overall, the coating of insulin-loaded nanoparticles with chitosan represents a potentially safe and promising approach to protect insulin and enhance peroral delivery.

Postprandial insulin action relies on meal composition and hepatic parasympathetics: dependency on glucose and amino acids: Meal, parasympathetics & insulin action.

Insulin sensitivity (IS) increases following a meal. Meal composition affects postprandial glucose disposal but still remains unclear which nutrients and mechanisms are involved. We hypothesized that gut-absorbed glucose and amino acids stimulate hepatic parasympathetic nerves, potentiating insulin action. Male Sprague-Dawley rats were 24 h fasted and anesthetized. Two series of experiments were performed. (A) IS was assessed before and after liquid test meal administration (10 ml.kg(-1), intraenteric): glucose + amino acids + lipids (GAL, n=6); glucose (n=5); amino acids (n=5); lipids (n=3); glucose + amino acids (GA, n=9); amino acids + lipids (n=3); and glucose + lipids (n=4). (B) Separately, fasted animals were submitted to hepatic parasympathetic denervation (DEN); IS was assessed before and after GAL (n=4) or GA administration (n=4). (A) Both GAL and GA induced significant insulin sensitization. GAL increased IS from 97.9±6.2 mg glucose/kg bw (fasting) to 225.4±18.3 mg glucose/kg bw (P<0.001; 143.6±26.0% potentiation of IS); GA increased IS from 109.0±6.6 to 240.4±18.0 mg glucose/kg bw (P<0.001; 123.1±13.4% potentiation). None of the other meals potentiated IS. (B) GAL and GA did not induce a significant insulin sensitization in DEN animal. To achieve maximal insulin sensitization following a meal, it is required that gut-absorbed glucose and amino acids trigger a vagal reflex that involves hepatic parasympathetic nerves.

Voluntary Oral Administration of Losartan in Rats.

Gavage is a widely performed technique for daily dosing in laboratory rodents. Although effective, gavage comprises a sequence of potentially stressful procedures for laboratory animals that may introduce bias into experimental results, especially when the drugs to be tested interfere with stress-dependent parameters. We aimed to test vehicles suitable for drug delivery by voluntary ingestion in rats. Specifically, Male Wistar rats (age, 2 to 3 mo) were used to test nut paste (NUT), peanut butter (PB), and sugar paste (SUG) as vehicles for long-term voluntary oral administration of losartan, an angiotensin II receptor blocker. Vehicles were administered for 28 d without drug to assess effects on the glucose level and serum lipid profile. Losartan was mixed with vehicles and either offered to the rats or administered by gavage (14 d) for subsequent quantification of losartan plasma levels by HPLC. After a 2-d acclimation period, all rats voluntarily ate the vehicles, either alone or mixed with losartan. NUT administration reduced blood glucose levels. The SUG group had higher concentrations of losartan than did the gavage group, without changes in lipid and glucose profiles. Our results showed that NUT, PB, and SUG all are viable for daily single-dose voluntary ingestion of losartan and that SUG was the best alternative overall. Drug bioavailability was not reduced after voluntary ingestion, suggesting that this method is highly effective for chronic oral administration of losartan to laboratory rodents.

Efficacy of carvedilol in reversing hypertension induced by chronic intermittent hypoxia in rats.

Animal models of chronic intermittent hypoxia (CIH) mimic the hypertension observed in patients with obstructive sleep apnoea. Antihypertensive drugs were applied to these animal models to address the physiological mechanism but not to revert established hypertension. We aimed to investigate the efficacy of carvedilol (CVDL), an unselective beta-blocker that exhibits intrinsic anti-α1-adrenergic and antioxidant activities in a rat model of CIH-induced hypertension. The variability of CVDL enantiomers in plasma concentrations was also evaluated. Wistar rats with indwelling blood pressure telemeters were exposed during their sleep period to 5.6 CIH cycles/h, 10.5 h/day, for 60 days. CVDL was administered by gavage beginning on Day 36 of the CIH period and was continued for 25 days. R-(+)-CVDL and S-(-)-CVDL plasma concentrations were monitored by HPLC. CIH significantly increased diastolic and systolic blood pressure by 25.7 and 21.6 mm Hg respectively, while no effect was observed on the heart rate (HR). CVDL administration at 10, 30 and 50 mg/kg/day promoted a significant reduction in HR but did not affect arterial pressure. The S/(R+S) ratio of CVDL enantiomers was lower in rats exposed to CIH. The blockade of the sympathetic nervous system together with the putative pleiotropic effects of CVDL did not alter the CIH-induced hypertension. Although CIH induced pharmacokinetic changes in the R/(R+S) ratio, these effects do not appear to be responsible for the inability of CVDL to reverse this particular type of hypertension.

Risk of postprandial insulin resistance: the liver/vagus rapport.

Ingestion of a meal is the greatest challenge faced by glucose homeostasis. The surge of nutrients has to be disposed quickly, as high concentrations in the bloodstream may have pathophysiological effects, and also properly, as misplaced reserves may induce problems in affected tissues. Thus, loss of the ability to adequately dispose of ingested nutrients can be expected to lead to glucose intolerance, and favor the development of pathologies. Achieving interplay of several organs is of upmost importance to maintain effectively postprandial glucose clearance, with the liver being responsible of orchestrating global glycemic control. This dogmatic role of the liver in postprandial insulin sensitivity is tightly associated with the vagus nerve. Herein, we uncover the behaviour of metabolic pathways determined by hepatic parasympathetic function status, in physiology and in pathophysiology. Likewise, the inquiry expands to address the impact of a modern lifestyle, especially one's feeding habits, on the hepatic parasympathetic nerve control of glucose metabolism.

Postprandial but not fasting insulin resistance is an early identifier of dysmetabolism in overweight subjects.

The dynamic response to insulin is highly potentiated after meal ingestion, and this meal-induced insulin sensitization (MIS) in healthy subjects is dependent on cholinergic mechanisms. The main objective of this study was to test the hypothesis that the reduced response to insulin observed in moderately overweight subjects, in comparison with control lean subjects, is due to MIS impairment and not to a reduction in the direct hypoglycemic action of insulin. Both lean and overweight male subjects were recruited. Insulin sensitivity (IS) was assessed by the rapid insulin sensitivity test (RIST) performed after a 24 h fast, as well as after a standardized meal. Fasting glucose disposal was similar between lean and overweight subjects. Following the meal, glucose disposal increased more extensively in lean than overweight subjects. The insulin profiles, in both fasted and fed states, were superimposable, suggesting that the absence of a factor other than insulin is responsible for the decreased postprandial insulin sensitivity observed in overweight subjects. Our data suggest that in overweight subjects, MIS contribution is decreased, which is responsible for the postprandial impaired IS observed and is suggested to be the cause, not effect, of mild adiposity.

High-fat diet results in postprandial insulin resistance that involves parasympathetic dysfunction.

Different diets have distinct impacts on glucose homoeostasis, for which insulin sensitivity (IS) after a meal (postprandial IS) is highly relevant. Postprandial IS depends upon hepatic parasympathetic activation and glutathione content elevation. We tested the hypothesis that postprandial IS is compromised in high-fat diet (HFD)-induced obesity. Sprague-Dawley rats were fed a standard diet (STD, n 10), 1-week HFD (n 9) or 4-week HFD (n 8). IS was tested in postprandial state using the rapid IS test (RIST) before and after the blockade of the parasympathetic nerves (atropine, 1 mg/kg); parasympathetic-dependent IS was obtained from the difference between control and post-atropine RIST. Fasting IS was also assessed in the STD-fed rats (n 4) and 4-week HFD-fed rats (n 3) using the RIST. Whole-body fat and regional fat pads were heavier in the 1-week HFD-fed rats (79.8 (SE 7.9) and 23.7 (SE 1.0) g, respectively) or 4-week HFD-fed rats (106.5 (SE 6.1) and 30.1 (SE 1.4) g, respectively) than in the STD-fed rats (32.5 (SE 3.7) and 13.7 (SE 1.0) g, respectively; P < 0.001). Fasted-state IS was similar between the groups studied. Postprandial IS was higher in the STD-fed rats (185.8 (SE 5.6) mg glucose/kg body weight (bw)) than in both the 1-week HFD-fed rats (108.8 (SE 2.9) mg glucose/kg bw; P < 0.001) and 4-week HFD-fed rats (69.3 (SE 2.6) mg glucose/kg bw; P < 0.001). Parasympathetic-dependent IS was impaired in both HFD-fed groups (STD, 108.9 (SE 3.9) mg glucose/kg bw; 1-week HFD, 38.6 (SE 4.2) mg glucose/kg bw; 4-week HFD, 5.4 (SE 1.7) mg glucose/kg bw; P < 0.001). Total (postprandial) and parasympathetic-dependent IS correlated negatively with whole-body fat (R² 0.81 and 0.87) and regional adiposity (R² 0.85 and 0.79). In conclusion, fat accumulation induced by HFD is associated with postprandial insulin resistance, but not with fasting insulin resistance. HFD-associated postprandial insulin resistance is largely mediated by impairment of parasympathetic-dependent insulin action, which correlates with adiposity.

Meal-induced insulin sensitization and its parasympathetic regulation in humans.

In animal studies, the whole-body glucose disposal effect of insulin is low in the fasted state or after atropine infusion, but doubles after a meal, consistent with the hepatic insulin-sensitizing substance (HISS) hypothesis. We tested how a standardized test meal and atropine affected the dynamic response to insulin in humans. Insulin sensitivity was assessed in healthy male subjects (aged 28.9 +/- 1.9 years, body mass index 23.3 +/- 0.8 kg.m-2) by using the rapid insulin sensitivity test (RIST), which is a transient euglycemic clamp. After a 24-hour fasting period, dynamic insulin sensitivity was assessed and then repeated 100 min after the test meal. In a second protocol, the volunteers were fed the standardized test meal and intravenous atropine (0.5 mg) or saline (control group) was administered 50 min before insulin sensitivity assessment. Insulin sensitivity increased in the fed state (232.1% +/- 46.3%, n = 7) in comparison with the 24-hour fasted state. In the atropine protocol, the drug partially blocked (56.5% +/- 11.6%, n = 6) insulin sensitivity. In humans, feeding resulted in increased insulin sensitivity. The low dose of atropine in humans lead to a partial HISS-dependent decrease in insulin sensitivity. Meal-induced insulin sensitization occured in humans by a similar mechanism as that reported in other species. The sensitization process was regulated by a cholinergic 'feeding signal.'

Hepatic-dependent and -independent insulin actions are impaired in the obese Zucker rat model.

OBJECTIVE: Whole-body insulin sensitivity (IS) depends on a hepatic pathway, involving parasympathetic activation and hepatic nitric oxide (NO) production. Both atropine and N-monomethyl-L-arginine (L-NMMA, NO synthase inhibitor) induce insulin resistance (IR). IR is associated with obesity. Because NO action was shown to be impaired in animal models of obesity, such as the obese Zucker rat (OZR), we tested the hypothesis that the hepatic-dependent pathway is diminished in OZR, resulting in IR. RESEARCH METHODS AND PROCEDURES: Lean Zucker rats (LZRs) were used as OZR controls. IS was evaluated in terms of glucose disposal [milligrams of glucose per kilogram of body weight (bw)]. Two groups were submitted to two protocols. First, a control clamp was followed by a post-atropine (3 mg/kg intravenously) clamp. Second, after the control clamp, L-NMMA (0.73 mg/kg intraportally) was given, and a second clamp was performed. Hepatic-dependent IS was assessed by subtracting the response after atropine or L-NMMA from the basal response. RESULTS: In the first protocol, basal IS was lower in OZR than in LZR (OZR, 73.7 +/- 14.2; LZR, 289.2 +/- 24.7 mg glucose/kg bw; p < 0.001), and atropine decreased IS in the same proportion for both groups (OZR, 41.3 +/- 8.0%; LZR, 40.1 +/- 6.5%). Equally, in the second protocol, OZR presented lower IS (OZR, 79.3 +/- 1.6; LZR, 287.4 +/- 22.7 mg glucose/kg bw; p < 0.001). L-NMMA induced IS inhibition in both groups (OZR, 48.3 +/- 6.6%; LZR, 46.4 +/- 4.1%), similar to that after atropine. DISCUSSION: We show that the IR in OZR is due to similar impairment of both hepatic-dependent and -independent components of insulin action, suggesting the existence of a defect common to both pathways.

A new technique to assess insulin sensitivity in humans: the rapid insulin sensitivity test (RIST).

The objective of this study was to develop a Rapid Insulin Sensitivity Test (RIST) in humans, a test already used in animal studies. Insulin sensitivity was assessed using a rapid modified euglycemic clamp, the RIST. In this test, glucose disposition was determined after an intravenous (i.v.) bolus (50mU/kg bw administered over 30 seconds) of insulin, before and after feeding a standardized test meal, in healthy male subjects (aged 27.8 +/- 2.4 years, BMI 23.5 +/- 1.2 kg/m2). The RIST uses as the index of insulin sensitivity, the total amount of glucose required to be infused to maintain euglycemia during insulin action following an i.v. bolus of insulin. During the RIST, glucose levels are determined at 2-min intervals in order to clamp the glycemia at baseline values. Following a 24 hr fasting period, the RIST index was 225.6 +/- 25.1 mg glucose/kg bw. The volunteers were then fed a standardized test meal, a new stable glucose level was obtained 100 min after the meal, and a second RIST was performed. The glucose requirement (RIST index) increased to 647.9 +/- 73.5 mg glucose/kg bw following the standardized test meal (n = 5, p < 0.001). This report describes a new technique to evaluate insulin sensitivity in healthy humans. The RIST is a powerful research tool to assess the glucose utilization action of an insulin bolus in fasted and fed states both evaluated in the same day.

Carvedilol's actions are largely mediated by endogenous nitric oxide.

Carvedilol's adrenergic antagonism does not fully explain its therapeutic actions. We therefore tested the hypothesis that its action is associated with an increase in NO synthesis. Wistar rats (male, 9 weeks, n = 10) anesthetized with sodium pentobarbital were used. Arterial NO concentration ([NO]), determined by chemiluminescence, and mean arterial pressure (MAP) were monitored throughout the experiment. In protocol 1), the effects of carvedilol (1 mg/kg, iv) were studied over a eriod of 90 min. In protocol 2), carvedilol was p administered, followed by the NO synthase (NOS) inhibitor L-NAME (5 mg/kg, iv) and by a second carvedilol administration. In protocol 1), carvedilol induced a significant fall in MAP (from 125,0 +/- 4,5 mmHg to 78.2 +/- 2.6 mmHg; p <0.001), reaching a minimum at t = 11.7 +/- 2.1 min and recovering 60 min afterwards (105.7 +/- 5.9 mmHg). Plasma [NO] varied in response to carvedilol in inverse proportion to MAP: baseline, 19.8 +/- 0.9 microM; t = 11.7 +/- 2.1 min, 32,3 +/- 2,3 microM; t = 60 min, 17.3 +/- 1.9 microM. In protocol 2), L-NAME administration blocked the effects of carvedilol (L-NAME: MAP, 129.9 +/- 5.0 mmHg; [NO], 13,1 +/- 2,3 microM. Post-L-NAME carvedilol administration resulted in MAP of 108.3 +/- 8.0 mmHg, NS, and [NO], 21.3 +/- 1.3 microM, NS. These results suggest that carvedilol increases plasma [NO], which is associated with a fall in MAP. Furthermore, carvedilol's hemodynamic action was blocked by NOS inhibition, suggesting that it depends on endogenous NO production, thus possibly explaining carvedilol's effects in hypertension and in cardiac failure.

Carvedilol action is dependent on endogenous production of nitric oxide.

BACKGROUND: Carvedilol is known to be an adrenoreceptor blocker and free radical scavenger, used in hypertension and cardiac failure. However, its therapeutic actions cannot be fully explained by these mechanisms. In these studies, we tested the hypothesis that carvedilol action is associated with the synthesis/release of nitric oxide (NO). METHODS: Male Wistar rats (n = 22), 9 weeks old, were anesthetized with an intraperitoneal injection of sodium pentobarbital. Mean arterial pressure and arterial NO levels were monitored throughout the experiments. Carvedilol (1 mg/kg, intravenously [iv]) effects were evaluated before and after NO synthase (NOS) inhibitor N(omega)-nitro-L-arginine methyl ester (L-NAME, 5 mg/kg, iv). RESULTS: Carvedilol induced a significant decrease in basal arterial pressure (from 126.6 +/- 4.3 mm Hg to 75.9 +/- 3.0 mm Hg, P < .001) and significant increase in NO levels (from 17.9 +/- 1.7 micromol/L to 32.2 +/- 2.5 micromol/L, P < .001). After administration of L-NAME the arterial pressure increased (129.9 +/- 5.0 mm Hg, P < .001) with concomitant decrease in NO levels (13.4 +/- 1.6 micromol/L, P < .01). The second carvedilol administration (post-L-NAME) did not affect either arterial pressure (108.3 +/- 8.0 mm Hg) or NO levels (22.1 +/- 1.3 micromol/L). CONCLUSIONS: Our results suggest that the carvedilol-induced decrease of blood pressure is associated with an increase of plasma NO levels. Furthermore, NOS inhibition results in impairment of carvedilol hemodynamic effects and plasma NO levels. Therefore, these results are consistent with the hypothesis that the hemodynamic effect of carvedilol is in part dependent on endogenous NO production.

Meal-induced insulin sensitization in conscious and anaesthetized rat models comparing liquid mixed meal with glucose and sucrose.

We have recently shown that meal-induced insulin sensitization (MIS) occurs after feeding and decreases progressively to insignificance after 24 h of fasting and is caused by action of a hepatic insulin sensitizing substance (HISS). In order to carry out quantitative studies of MIS, some standardized meal intake is required. Our objective was to establish animal models to be tested in both the conscious and anaesthetized state using intragastric injection of liquid meals in order to quantify MIS. Insulin sensitivity was assessed before and 90 min after the meal using the rapid insulin sensitivity test (RIST) which is a transient euglycaemic clamp. Rats tested in the conscious state were instrumented under anaesthesia 6-9 d prior to testing with catheters in the carotid artery, jugular vein and stomach. Meals, injected into the stomach, consisted of a liquid mixed meal, sucrose, glucose or water. The glucose sequestration in response to insulin increased by 90 % and 61 % following the liquid mixed meal (10 ml/kg) in conscious and anaesthetized rats, respectively. Glucose, sucrose and water did not effectively activate MIS. MIS was completely reversed in the conscious model by atropine and completely prevented from developing in the anaesthetized model that had previously undergone hepatic denervation. Gastric administration of a liquid mixed meal but not glucose or sucrose is capable of activating MIS for purposes of mechanistic studies and quantification of the MIS process. The feeding signal is mediated by the hepatic parasympathetic nerves.

In vitro nitrosation of insulin A- and B-chains.

The physiological roles of insulin and nitric oxide (NO) have been recently recognized by several studies. A diversity of chemical modifications of insulin is reported both in vivo and in vitro. S-nitrosation, the covalent linkage of NO to cysteine free thiol is recognized as an important post-translational regulation in many proteins. Here we report the in vitro synthesis of an S-nitrosothiol of bovine insulin A- and B-chains. These compounds were characterized by their HPLC chromatographic behavior, monitored by UV visible spectroscopy and electron spray ionization mass spectrometry. The experimental results indicate that each A- and B-chain were S- nitrosated with only one NO group. Stability and solubility of these synthesized derivatives is described for physiological purposes. In this work, nitroso A- and B-chains of insulin were synthesized in vitro in order to better understand the possible interactions between insulin and NO that may be involved in the etiology of insulin resistance.

Hepatic glutathione and nitric oxide are critical for hepatic insulin-sensitizing substance action.

We tested the hypothesis that hepatic nitric oxide (NO) and glutathione (GSH) are involved in the synthesis of a putative hormone referred to as hepatic insulin-sensitizing substance HISS. Insulin action was assessed in Wistar rats using the rapid insulin sensitivity test (RIST). Blockade of hepatic NO synthesis with N(G)-nitro-l-arginine methyl ester (l-NAME, 1.0 mg/kg intraportal) decreased insulin sensitivity by 45.1 +/- 2.1% compared with control (from 287.3 +/- 18.1 to 155.3 +/- 10.1 mg glucose/kg, P < 0.05). Insulin sensitivity was restored to 321.7 +/- 44.7 mg glucose/kg after administration of an NO donor, intraportal SIN-1 (5 mg/kg), which promotes GSH nitrosation, but not after intraportal sodium nitroprusside (20 nmol x kg(-1) x min(-1)), which does not nitrosate GSH. We depleted hepatic GSH using the GSH synthesis inhibitor l-buthionine-[S,R]-sulfoximine (BSO, 2 mmol/kg body wt ip for 20 days), which reduced insulin sensitivity by 39.1%. Insulin sensitivity after l-NAME was not significantly different between BSO- and sham-treated animals. SIN-1 did not reverse the insulin resistance induced by l-NAME in the BSO-treated group. These results support our hypothesis that NO and GSH are essential for insulin action.