Amelioration of diabetic dyslipidemia by macrocyclic binuclear oxovanadium complex on streptozotocin induced diabetic rats

Diabetic dyslipidemia, the main causative factor for the progression of vascular complications in diabetes, is caused due to hyperglycemia and excess mobilisation of fatty acids. Recently we have reported on a novel macrocyclic binuclear oxovanadium (MBOV) complex synthesized by us with significant hypoglycemic efficacy and without any apparent toxicity on streptozotocin induced diabetic rats. In the present study, streptozotocin induced diabetic rats were treated with the vanadium complex (5 mg/kg body weight/day) for a period of 30 days and at the end of the treatment period the status of the lipid profile in the plasma, liver and kidney was evaluated. Also the fatty acid composition of liver and kidney were analysed by gas chromatography. The increased levels of lipid contents in plasma and tissues observed in diabetic rats were reverted back to near normal levels by the administration of the vanadium complex. Also the decreased levels of HDL cholesterol and increased levels of LDL cholesterol in plasma of diabetic rats were restored to near normal levels by the treatment with the vanadium complex. The altered fatty acid composition in liver and kidney were restored by the treatment. The results enhance the claim for the macrocyclic binuclear oxovanadium complex as a potent anti-diabetogenic drug.This revised version was published online in May 2005 with a corrected article title.     

A new salicylic acid-derivatized kojic acid vanadyl complex: synthesis, characterization and anti-diabetic therapeutic potential

The molecular mechanisms of vanadium toxicity suggest that incorporation of antioxidant groups in the structure of vanadium complexes could be a preferable strategy in designing novel hypoglycemic vanadium complexes with proper efficacy and safety. By conjugating a pyrone skeleton to provide a coordination group and antioxidative motifs, we synthesized a novel complex of bis ((5-hydroxy-4-oxo-4 H-pyran-2-yl) methyl 2-hydroxy- benzoatato) oxovanadium (IV) (BSOV). Evaluation of the anti-diabetic effects of BSOV using streptozotocin (STZ)-induced diabetic rats with bis (maltolato) oxovanadium (BMOV) as a positive control showed that BSOV effectively lowered blood glucose level, ameliorated damages of hepatic and renal function in diabetic rats and improved lipid metabolism. The signs of potential alteration of renal function caused by BSOV and BMOV were observed and are discussed. Overall, the experimental results suggest BSOV as a potent hypoglycemic agent and further studies using this strategy for anti-diabetic agents.     

The influence of a new vanadium compound, bis(2,2'-bipyridine)oxovanadium(IV) sulphate on liver golgi complexes from control and streptozotocin-diabetic rats.

Among the previously studied organic vanadium derivatives showing an anti-diabetic action, we investigated a new complex, bis(2,2'-bipyridine)oxovanadium(IV) sulphate. We tested its ability to normalise parameters previously described for streptozotocin (STZ)-diabetes, such as lower yields of Golgi-rich membrane fraction isolation, decreased activity of Golgi membrane marker enzyme - galactosyltransferase (GalT) - and altered morphology of rat liver Golgi complexes. Oral application as a drinking solution of 1.8 mmol bis(2,2'-bipyridine)oxovanadium(IV) (dissolved in 0.09 M NaCl) caused a similar dispersion of GalT activities in both vanadium treated groups, control and diabetic. Very low activities of the enzyme (characteristic for untreated diabetes) we found only in approximately 35 % of the STZ-diabetic rats treated with the new vanadium compound. The morphology of liver Golgi complexes in diabetic rats treated with bis(2,2'-bipyridine)oxovanadium(IV) sulphate was improved, which manifested itself in the reappearance of vacuoles with VLDL and coated and uncoated secretory vesicles. In view of biochemical and morphological parameters of normalised diabetic rat liver Golgi apparatus, the new vanadium complex was more effective than bis(oxalato)oxovanadium(IV) or bis(kojato)oxovanadium(IV), but in our experimental model, the best anti-diabetic, orally applied drug was the bis(maltolato)oxovanadium(IV) previously investigated.     

Differences in plasma homocysteine levels between Zucker fatty and Zucker diabetic fatty rats following 3 weeks oral administration of organic vanadium compounds

PURPOSE: Recently, our laboratory group has reported that rats with Type 1 diabetes have decreased plasma homocysteine and cysteine levels compared to non-diabetic controls and that organic vanadium treatment increased plasma homocysteine concentrations to non-diabetic concentrations. However, to date, no studies have been done investigating the effects of organic vanadium compounds on plasma homocysteine and its metabolites in Type 2 diabetic animal model. These studies examined the effect of organic vanadium compounds [bis(maltolato)oxovanadium(IV) and bis(ethylmaltolato)oxovanadium(IV); BMOV and BEOV] administered orally on plasma concentrations of homocysteine and its metabolites (cysteine and cysteinylglycine) in lean, Zucker fatty (ZF) and Zucker diabetic fatty (ZDF) rats. ZF rats are a model of pre-diabetic Type 2 diabetes characterized by hyperinsulinemia and normoglycemia. The ZDF rat is a model of Type 2 diabetes characterized by relative hypoinsulinemia and hyperglycemia. METHODS: Zucker lean and ZF rats received BMOV in the drinking water at a dose of 0.19 +/- 0.02 mmol/kg/day. Lean and ZDF rats received BEOV by oral gavage daily at dose of 0.1 mmol/kg. The treatment period for both studies was 21 days. At termination, animals were fasted overnight (approximately 16 h) and blood samples were collected by cardiac puncture for determination of plasma glucose, insulin and homocysteine levels. Plasma homocysteine and its metabolites levels were determined using high-pressure liquid chromatography. Plasma glucose was determined using a Glucose Analyzer 2. Plasma insulin levels were determined by radioimmunoassay. Plasma triglycerides were determined by an enzymatic assay methodology. RESULTS: ZF (n = 4) and ZDF (n = 10) rats had significantly lower plasma homocysteine as compared to their respective lean groups (ZF 0.78 +/- 0.1 micromol/L vs. Zucker lean 2.19 +/- 0.7 micromol/L; ZDF 1.71 +/- 0.2 micromol/L vs. Zucker lean 3.02 +/- 0.3 micromol/L; p < 0.05). BMOV treatment in ZF rats restored plasma homocysteine levels to those observed in lean untreated rats (ZF treated: 2.04 +/- 0.2 micromol/L; lean 2.19 +/- 0.7 micromol/L). There was a modest effect of BMOV treatment on plasma glucose levels in ZF rats. BEOV treatment significantly decreased the elevated plasma glucose levels in the ZDF rats (lean 7.9 +/- 0.1 mmol/L; lean + vanadium 7.7 +/- 0.2 mmol/L; ZDF 29.9 +/- 0.4 mmol/L; ZDF + vanadium 17.4 +/- 0.3 mmol/L, p < 0.05). Organic vanadium treatment reduced cysteine levels in both ZF and ZDF rats. No differences in total plasma cysteinylglycine concentrations were observed. CONCLUSION: Plasma homocysteine levels are significantly reduced in a pre-diabetic model of Type 2 diabetes, which was restored to lean levels upon vanadium treatment; however, this restoration of plasma homocysteine levels was not seen in ZDF Type 2 diabetic rats following vanadium treatment. In the latter case vanadium treatment may not have totally overcome the insulin resistance seen in these animals.     

Optimization of sodium orthovanadate to treat streptozotocin-induced diabetic rats

Oral administration of sodium orthovanadate restored blood glucose to normal levels in streptozotocin-induced diabetic rats. To establish the safety dose and to evaluate the side effects of over dose, if any, different doses of vanadium were used in the present study. Low concentrations of vanadium (0.1 and 0.3 mg/ml in drinking water) restored blood glucose, urea, cholesterol and the status of liver pathophysiological enzymes to normal levels in experimental rats. High vanadate treatment proved to be toxic not only to diabetic but also to normal rats as evidenced from the observations on the blood urea, plasma and liver glutamate oxaloacetate transaminase and glutamate pyruvate transaminase. Low vanadate treatment restored body homeostasis of diabetic rats and was found to be nontoxic to normals.     

A new halogenated antidiabetic vanadyl complex, bis(5-iodopicolinato)oxovanadium(IV): in vitro and in vivo insulinomimetic evaluations and metallokinetic analysis

A new vanadyl complex, bis(5-iodopicolinato)oxovanadium(IV), VO(IPA)2, with a VO(N2O2) coordination mode, was prepared by mixing 5-iodopicolinic acid and VOSO4 at pH 5, with the structure characterized by electronic absorption, IR, and EPR spectra. Introduction of the halogen atom on to the ligand enhanced the in vitro insulinomimetic activity (IC50 = 0.45 mM) compared with that of bis(picolinato)oxovanadium(IV) (IC50 = 0.59 mM). The hyperglycemia of streptozotocin-induced insulin-dependent diabetic rats was normalized when VO(IPA)2 was given by daily intraperitoneal injection. The normoglycemic effect continued for more than 14 days after the end of treatment. To understand the insulinomimetic action of VO(IPA)2, the organ distribution of vanadium and the blood disposition of vanadyl species were investigated. In diabetic rats treated with VO(IPA)2, vanadium was distributed in almost all tissues examined, especially in bone, indicating that the action of vanadium is not peripheral. Vanadyl concentrations in the blood of normal rats given VO(IPA)2 remain significantly higher and longer than those given other complexes because of its slower clearance rate. VO(IPA)2 binds with the membrane of erythrocytes, probably owing to its high hydrophobicity in addition to its binding with serum albumin. The longer residence of vanadyl species shows the higher normoglyceric effects of VO(IPA)2 among three complexes with the VO(N2O2) coordination mode. On the basis of these results, VO(IPA)2 is indicated to be a preferred agent to treat insulin-dependent diabetes mellitus in experimental animals.     

Effect of chronic treatment with Bis(maltolato)oxovanadium (IV) in rat model of non-insulin-dependent-diabetes

Effect of chronic treatment with Bis(maltolato)oxovanadium (IV) (BMOV) was studied in streptozotocin (STZ)-induced neonatal non-insulin-dependent-diabetic (NIDDM) rats. Intraperitoneal injection of STZ (90 mg kg(-1)) in Wistar rat pups (day 2 old) produced mild hyperglycemia, impaired glucose tolerance and insulin resistance at the age of 3 months. Treatment with BMOV (0.23 mM kg(-1)) in drinking water for 6 weeks produced a significant decrease in elevated serum glucose levels without any significant change in serum insulin levels in diabetic rats. BMOV treatment significantly decreased integrated area under the glucose curve without any significant change in integrated area under the insulin curve indicating improved glucose tolerance. Treatment also significantly increased K(ITT) value of diabetic rats indicating increased insulin sensitivity. BMOV treatment significantly reduced hypercholesterolemia in diabetic rats. Treatment also significantly decreased serum triglyceride levels in both diabetic and non-diabetic rats. The data suggest that chronic BMOV treatment improves glucose and lipid homeostasis. These effects appear to be due to the insulin sensitizing action of vanadium.     

Effect of bis[curcumino]oxovanadium complex on non-diabetic and streptozotocin-induced diabetic rats

The effect of the vanadium complex bis[curcumino]oxovanadium (BCOV) on blood glucose level, serum lipid levels, blood pressure and vascular reactivity were studied in non-diabetic and streptozotocin-induced diabetic (STZ-diabetic) rats and compared to that of vanadyl sulfate. Blood glucose level, serum lipid levels, and blood pressure were significantly increased in STZ-diabetic rats. Vascular reactivity to various agonists such as noradrenaline and acetylcholine were significantly increased in STZ-diabetic rats. Blood glucose and serum lipid levels were restored to normal in STZ-diabetic animals treated with vanadyl sulfate at a concentration of 0.5 mmol/kg/day (p.o.). However, vanadyl sulfate at a concentration of 0.2 mmol/kg/day (p.o.) did not produce any significant change in blood glucose and lipid levels. There was no significant effect of vanadyl sulfate (0.2 or 0.5 mmol/kg/day) treatment on blood pressure and vascular reactivity in STZ-diabetic rats. Vanadyl sulfate significantly reduced the body weight of non-diabetic and STZ-diabetic rats. Moreover, it also caused severe diarrhea in both groups of animals. Treatment with BCOV (0.05, 0.1 and 0.2mmol/kg/day, p.o.) significantly decreased blood glucose level and serum lipids in STZ-diabetic rats. Furthermore, administration of BCOV to STZ-diabetic rats restored the blood pressure and vascular reactivity to agonists to normal. There was no significant change in the body weight of BCOV treated non-diabetic and STZ-diabetic rats. Diarrhea was not observed in both BCOV treated groups. In conclusion, the present study shows that the vanadium complex BCOV has antidiabetic and hypolipedimic effects. In addition, it improves the cardiovascular complications associated with diabetes.     

A physicochemical study of the tetracycline coordination to oxovanadium(IV)

The interaction of tetracycline and oxovanadium(IV) in aqueous solution was studied by potentiometric and spectrophotometric methods. Oxovanadium(IV) ions form both a positively charged 1:1 and a neutral 2:1 metal-ligand complex with tetracycline. When a 1:1 ligand-to-metal ratio mixture is used at about pH 4.5 the 1:1 species predominates, being replaced at pH 6 by the binuclear complex. The binuclear complex has been isolated and fully characterised. Infrared and EPR studies suggest the existence of two distinct vanadyl binding sites. Our results indicate that the first vanadium coordinates to the BCD-ring system and the second one to the A-ring. Biological implications of the existence of a neutral complex at physiological pH are briefly discussed.     

Anti-diabetic Effects of Cesium Aqua (N,N′-ethylene(salicylideneiminato)-5-sulfonato) Oxovanadium (IV) Dihydrate in Streptozotocin-induced Diabetic Rats

The study has been designed to investigate the anti-diabetic effects of cesium aqua (N,N′-ethylene (salicylideneiminato)-5-sulfonato) oxovanadium (IV) dihydrate (VO(salen-SO₃)), an organic vanadium compound, in streptozotocin-induced diabetic rats. VO(salen-SO₃) was orally administrated to diabetic rats at the dose of 0.3 mg/ml through drinking water for 24 days. Blood glucose level was significantly declined, and oral glucose tolerance was improved after VO(salen-SO₃) treatment. Moreover, liver and muscle glycogen concentrations were markedly increased in VO(salen-SO₃)-treated diabetic rats. On the other hand, aspartate amino transferase and blood urea nitrogen in serum were significantly decreased after treatment with VO(salen-SO₃). Take together, these results suggested that VO(salen-SO₃) may be of potential value in the therapy of diabetic symptom and hyperglycemia-induced hepatic and renal dysfunction.     

In vivo effects of vanadium on GLUT4 translocation in cardiac tissue of STZ-diabetic rats

The effect of vanadium treatment on insulin-stimulated glucose transporter type 4 (GLUT4) translocation was studied in cardiac tissue of streptozotocin (STZ)-induced diabetic rats by determining the subcellular distribution of GLUT4. Four groups of rats were examined: control and diabetic, with or without bis(maltolato)oxovanadium(IV) (BMOV, an organic form of vanadium) treatment for 8 weeks. The effect of vanadium on insulin-induced GLUT4 translocation was studied at 5 min as the early insulin response and at 15 min after insulin injection as the maximal insulin response.At 5 min after insulin injection, plasma membrane GLUT4 level in the diabetic-treated group was not different from the control groups and was significantly higher than that of the insulin-stimulated diabetic group, indicating an enhancement of insulin response on GLUT4 translocation brought about by vanadium treatment. In contrast to that at 5 min after insulin injection, no significant difference in the plasma membrane GLUT4 level was observed between the diabetic and the diabetic-treated groups at 15 min after insulin injection. GLUT4 mobilization from the intracellular pool in response to insulin was also investigated at 15 min after insulin injection. Basal intracellular GLUT4 content was significantly higher in the diabetic-treated group when compared to the diabetic group under the same condition. However, the increased basal intracellular GLUT4 in the diabetic-treated group did not result in more insulin-mediated GLUT4 translocation at 15 min after insulin injection. In conclusion, the finding that plasma membrane GLUT4 in the diabetic-treated group is significantly higher than that of the diabetic group at 5 min but not at 15 min post-insulin injection indicates that vanadium treatment enhances insulin-mediated GLUT4 translocation in cardiac tissue by enhancing its early response.     

Vanadium and diabetes

We demonstrated in 1985 that vanadium administered in the drinking water to streptozotocin (STZ) diabetic rats restored elevated blood glucose to normal. Subsequent studies have shown that vanadyl sulfate can lower elevated blood glucose, cholesterol and triglycerides in a variety of diabetic models including the STZ diabetic rat, the Zucker fatty rat and the Zucker diabetic fatty rat. Long-term studies of up to one year did not show toxicity in control or STZ rats administered vanadyl sulfate in doses that lowered elevated blood glucose. In the BB diabetic rat, a model of insulin-dependent diabetes, vanadyl sulfate lowered the insulin requirement by up to 75%. Vanadyl sulfate is effective orally when administered by either single dose or chronic doses. It is also effective by the intraperitoneal route. We have also been able to demonstrate marked long-terrn effects of vanadyl sulfate in diabetic animals following treatment and withdrawal of vanadyl sulfate. Because vanadyl sulfate is not well absorbed we have synthesized and tested a number of organic vanaditun compounds. One of these, bismaltolato-oxovanadiurn IV (BMOV), has shown promise as a therapeutic agent. BMOV is 2-3x more potent than vanadyl sulfate and has shown less toxicity. Recent studies from our laboratory have shown that the effects of vanadium are not due to a decrease in food intake and that while vanadium is deposited in bone it does not appear to affect bone strength or architecture. The mechanism of action of vanadium is currently under investigation. Several studies indicate that vanadiun is a phosphatase inhibitor and that vanadium can activate serine/threonine kineses distal to tbe insulin receptor presumably by preventing dephosphorylation due to inhibition of phosphatases Short-term clinical trials using inorganic vanadium compounds in diabetic patients have been promising.     

Enhanced in vivo sensitivity of vanadyl-treated diabetic rats to insulin

Vanadium has been reported to have insulin-like properties and has recently been demonstrated to be beneficial in the treatment of diabetic animals. In the present study, concentration dependence of the therapeutic effects of vanadium and the nature of interaction under in vivo conditions between vanadium and insulin were examined in streptozotocin-diabetic rats. During a 2-week period, blood glucose levels in all treated animals were decreased. At higher concentrations of vanadyl this decrease was greater and more rapid, and remained consistently lower for the entire treatment period. Daily intake of vanadyl, however, reached a similar steady state in all groups. Acute administration of submaximal doses of insulin, which had minimal effects in untreated diabetic rats, lowered blood glucose concentrations in vanadyl-treated and vanadyl-withdrawn animals to control levels. Chronic treatment of streptozotocin-diabetic rats with submaximal levels of vanadyl and insulin, ineffective alone, also produced significant decreases in blood glucose levels when used in combination. Finally, the insulin dosage required to maintain a nonglycosuric state in spontaneously diabetic (BB) rats was reduced in the presence of vanadyl. These studies indicate that chronic oral vanadyl treatment (a) produces a concentration-related lowering of blood glucose in diabetic rats, (b) potentiates the in vivo glucose lowering effects of acute and chronic administrations of insulin in streptozotocin-diabetic rats, and (c) substitutes for, or potentiates, the effects of chronic insulin therapy in spontaneously diabetic BB rats.     

The controlled release of insulin-mimetic metal ions by the multifunction of chitosan

Vanadium, which is an insulin-mimetic metal ion, was efficiently adsorbed on chitosan (CS). The adsorption of vanadium on CS was affected by the vanadium/CS ratio and the initial concentration of vanadium in preparative medium under constant pH condition. The vanadium-CS complex was able to control vanadium release. Moreover, a consistent control of vanadium release was achieved by incorporation of the vanadium-CS complex into a CS gel. After implantation of the CS gel retaining the vanadium-CS complex into diabetic mice, insulin-mimetic efficacy was confirmed by observation of a steady reduction in blood glucose levels. The sustained vanadium release also contributed to minimization of the side-effects. Thus, CS gel retaining the vanadium-CS complex appears promising as a vehicle for vanadium with long-term action and a low toxicity leading to its clinical use.     

Metallokinetic characteristics of antidiabetic bis(allixinato)oxovanadium(IV)-related complexes in the blood of rat

The antidiabetic effect of vanadium is a widely accepted phenomenon; some oxovanadium(IV) complexes have been found to normalize high blood glucose levels in both type 1 and type 2 diabetic animals. In light of the future clinical use of these complexes, the relationship among their chemical structures, physicochemical properties, metallokinetics, and antidiabetic activities must be closely investigated. Recently, we found that among bis(3-hydroxypyronato)oxovanadium(IV) [VO(3hp)₂] related complexes, bis(allixinato)oxovanadium(IV) [VO(alx)₂] exhibits a relatively strong hypoglycemic effect in diabetic animals. Next, we examined its metallokinetics in the blood of rats that received five VO(3hp)₂-related complexes by the blood circulation monitoring–electron paramagnetic resonance method. The metallokinetic parameters were obtained from the blood clearance curves based on a two-compartment model; most parameters, such as area under the concentration curve and mean residence time, correlated significantly with the in vitro insulinomimetic activity in terms of 1/IC₅₀ (IC₅₀ is the 50% inhibitory concentration of the complex required for the release of free fatty acids in adipocytes) and the lipophilicity of the complex (log P _com). The oxovanadium(IV) concentration was significantly higher and the species resided longer in the blood of rats that received VO(alx)₂ than in the blood of rats that received VO(3hp)₂ or bis(kojato)oxovanadium(IV); VO(alx)₂ also exhibited higher log P _com and 1/IC₅₀ values. On the basis of these results, we propose that the introduction of lipophilic groups at the C2 and C6 positions of the 3hp ligand is an effective method to enhance the hypoglycemic effect of the complexes, as supported by the observed in vivo exposure and residence in the blood.     

Improvement of diabetes, obesity and hypertension in type 2 diabetic KKAy mice by bis(allixinato)oxovanadium(IV) complex

Previously, we found that bis(allixinato)oxovanadium(IV) (VO(alx)(2)) exhibits a potent hypoglycemic activity in type 1-like diabetic mice. Since the enhancement of insulin sensitivity is involved in one of the mechanisms by which vanadium exerts its anti-diabetic effects, VO(alx)(2) was further tested in type 2 diabetes with low insulin sensitivity. The effect of oral administration of VO(alx)(2) was examined in obesity-linked type 2 diabetic KKA(y) mice. Treatment of VO(alx)(2) for 4 weeks normalized hyperglycemia, glucose intolerance, hyperinsulinemia, hypercholesterolemia and hypertension in KKA(y) mice; however, it had no effect on hypoadiponectinemia. VO(alx)(2) also improved hyperleptinemia, following attenuation of obesity in KKA(y) mice. This is the first example in which a vanadium compound improved leptin resistance in type 2 diabetes by oral administration. On the basis of these results, VO(alx)(2) is proposed to enhance not only insulin sensitivity but also leptin sensitivity, which in turn improves diabetes, obesity and hypertension in an obesity-linked type 2 diabetic animal.     

The Protective Effect of Vanadium Against Diabetic Cataracts in Diabetic Rat Model

The present study was designed to investigate the effect of vanadium in alloxan-induced diabetes and cataract in rats. Different doses of vanadium was administered once daily for 8 weeks to alloxan-induced diabetic rats. To know the mechanism of action of vanadium, lens malondialdehyde (MDA), protein carbonyl content, activity of superoxide dismutase (SOD), activities of aldose reductase (AR), and sorbitol levels were assayed, respectively. Supplementation of vanadium to alloxan-induced diabetic rats decreased the blood glucose levels due to hyperglycemia, inhibited the AR activity, and delayed cataract progression in a dose-dependent manner. The observed beneficial effects may be attributed to polyol pathway activation but not decreased oxidative stress. Overall, the results of this study demonstrate that vanadium could effectively reduce the alloxan-induced hyperglycemia and diabetic cataracts in rats.     

Comparison of Effects of Vanadium Absorbed by Coprinus comatus with Those of Inorganic Vanadium on Bone in Streptozotocin-Diabetic Rats

The purpose of this study was to compare the effect of vanadium absorbed by Coprinus comatus (VACC) with inorganic vanadium (vanadium nitrate, IV) in preventing diabetes-related osteopenia in streptozotocin-diabetic rats. Sixty Wistar female rats used were divided into four groups: (1) normal rats (control), (2) diabetic rats, (3) diabetic rats treated with VACC, and (4) diabetic rats treated with vanadium nitrate. A standardized type 1-like diabetes model was induced by injection of streptozotocin. After the rats were treated orally with VACC and IV respectively, plasma glucose, body weights, micro-CT, biomechanical testing, and histomorphometry were examined. In addition, bone samples were obtained to evaluate the content of mineral substances in bones. Treatments were performed over a 12-week period. Both VACC and IV have a positive effect on plasma glucose and body weights of STZ-induced diabetic rats. However, treatment with IV only caused a 39.6?% decrease in glucose levels and a 14.6?% increase in body weights, whereas VACC decreased plasma glucose and increased body weights by up to 52.2 and 24.5?%, respectively. At the same time, VACC significantly improved trabecular microstructure and mechanical strength, while IV did not exhibit desirable such effects. Also, bone Ca and bone P were not significantly increased by IV. These results indicated that both VACC and IV have hypoglycemic activity on diabetic rats, while IV did not improve bone properties. In conclusion, this study suggests that VACC improves diabetes-related bone dysfunction, primarily by improving the diabetic states.     

Insulin-enhancing activity of a dinuclear vanadium complex: 5-chloro-salicylaldhyde ethylenediamine oxovanadium(V) and its permeability and cytotoxicity

A new insulin-enhancing oxovanadium complex 5-chloro-salicylaldhyde ethylenediamine oxovanadium (V) ([V₂O₂(μ-O)₂L₂]) has been synthesized. The complex was characterized by a variety of physical methods, including X-ray crystallography. The X-ray diffraction analysis show a dinuclear complex of two six-coordinate vanadium centers doubly bridged by the oxygen atoms of the Schiff base ligand with a V₂O₂ diamond core. The complex was administered intragastrically to STZ-diabetic rats for 2 weeks. The biological activity results show that the complex at the dose of 10.0 and 20.0 mg V kg^− 1, could significantly decrease the blood glucose level and ameliorate impaired glucose tolerance in STZ-diabetic rats. That results suggested that the complex exerts an antidiabetic effect in STZ-diabetic rats. Furthermore, the complex ([V₂O₂(μ-O)₂L₂]) had permeability above 10^− 5 cm/s. The experimental results suggested that the vanadium complex permeates via a passive diffusion mechanism. It was also suggested the complex with salen-type ligands has good lipophilic properties and better oral administration. The cytotoxicity of the complex ([V₂O₂(μ-O)₂L₂]) on Caco-2 cells was measured by a decrease of cell viability using the MTT assay suggesting that the chlorine atom at C4 of complex [V₂O₂(μ-O)₂L₂] increased cytotoxicity for vanadium complexes.     

Study of the antidiabetic capacity of the VO(dmpp)2 complex

In this work we report biochemical ex vivo studies with a vanadium compound containing a pyridinone ligand, the bis(1,2-dimethyl-3-hydroxy-4-pyridinonate)oxovanadium (IV), V^IVO(dmpp)₂, which has shown to have promising antidiabetic activity. The experiments were carried out on primary adipocytes of 6-8 week old Wistar rats. Insulin-stimulated glucose uptake studies were performed using a radioactive assay by measuring the (U)-¹⁴C-glucose taken up by the isolated adipocytes for 30 min. Adipocytes were incubated with and without insulin and in the presence and absence of different concentrations of V^IVO(dmpp)₂ (100-500 μM) for 45 min. We observed that in a nontoxic concentration, as demonstrated by the Alamar Blue test, V^IVO(dmpp)₂ significantly increases glucose uptake, in the absence of insulin, by 5-folds higher than basal, and it has a significant inhibitory effect of 78% on free fatty acid release in isolated adipocytes from normal rats. We also demonstrated that it promotes the phosphorylation of Akt1, a key protein in the insulin signaling cascade. These results were compared with those obtained with another vanadium compound reported in the literature, with a similar structure, the bis(maltolato)oxovanadium (IV) (BMOV), which is now in clinical trials. Our ex vivo results clearly indicate that V^IVO(dmpp)₂ is a good candidate to be a promising drug for the treatment of diabetes and other metabolic disorders.