Release-Modulated Antioxidant Activity of a Composite Curcumin-Chitosan Polymer.

Curcumin is known to have immense therapeutic potential but is hindered by poor solubility and rapid degradation in solution. To overcome these shortcomings, curcumin has been conjugated to chitosan through a pendant glutaric anhydride linker using amide bond coupling chemistry. The hybrid polymer has been characterized by UV-visible, fluorescence, and infrared spectroscopies as well as zeta potential measurements and SEM imaging. The conjugation reactivity was confirmed through gel permeation chromatography and quantification of unconjugated curcumin. An analogous reaction of curcumin with glucosamine, a small molecule analogue for chitosan, was performed and the purified product characterized by mass spectrometry, UV-visible, fluorescence, and infrared spectroscopies. Conjugation of curcumin to chitosan has greatly improved curcumin aqueous solubility and stability, with no significant curcumin degradation detected after one month in solution. The absorbance and fluorescence properties of curcumin are minimally perturbed (λmax shifts of 2 and 5 nm, respectively) by the conjugation reaction. This conjugation strategy required use of one out of two curcumin phenols (one of the main antioxidant functional groups) for covalent linkage to chitosan, thus temporarily attenuating its antioxidant capacity. Hydrolysis-based release of curcumin from the polymer, however, is accompanied by full restoration of curcumin's antioxidant potential. Antioxidant assays show that curcumin radical scavenging potential is reduced by 40% after conjugation, but that full antioxidant potential is restored upon hydrolytic release from chitosan. Release studies show that curcumin is released over 19 days from the polymer and maintains a concentration of 0.23 ± 0.12 µM curcumin/mg polymer/mL solution based on 1% curcumin loading on the polymer. Release studies in the presence of carbonic anhydrase, an enzyme with known phenolic esterase activity, show no significant difference from nonenzymatic release studies, implying that simple ester hydrolysis is the dominant release mechanism. Conjugation of curcumin to chitosan through a phenol ester modification provides improved stability and solubility to curcumin, with ester hydrolysis restoring the full antioxidant potential of curcumin.

Curcumin encapsulation in submicrometer spray-dried chitosan/Tween 20 particles.

Optimal curcumin delivery for medicinal applications requires a drug delivery system that both solubilizes curcumin and prevents degradation. To achieve this, curcumin has been encapsulated in submicrometer chitosan/Tween 20 particles via a benchtop spray-drying process. Spray-drying parameters have been optimized using a Taguchi statistical approach to minimize particle size and to favor spheroid particles with smooth surfaces, as evaluated with scanning electron microscopy (SEM) imaging. Nearly spherical particles with 285 ± 30 nm diameter and 1.21 axial ratio were achieved. Inclusion of curcumin in the spray-drying solution results in complete encapsulation of curcumin within the chitosan/Tween 20 particles. Release studies confirm that curcumin can be released completely from the particles over a 2 h period.

Direct energy delivery improves tissue perfusion after resuscitated shock.

BACKGROUND: Conventional resuscitation (CR) from hemorrhagic shock (HS) does not restore intestinal blood flow. Indicators of anaerobic metabolism suggest that cellular energy production also is compromised. We hypothesize that the direct intravenous delivery of lipid-encapsulated high-energy phosphates to cells improves intestinal perfusion during HS and resuscitation (RES). METHODS: MAP (MAP) was monitored in male rats (200 g), terminal ileum microvessel diameters were measured by in vivo videomicroscopy, and blood flow (Doppler velocimetry) was calculated. Cellular energy delivery was accomplished by intravenous infusion during RES of fusogenic unilamellar lipid vesicles that contain adenosine triphosphate (ATP; VitaSol). Our protocol was HS to 50% baseline MAP for 60 minutes, 30 minutes of RES, and continued microscopy observation for 120 minutes. Experimental groups (n=8 each) were HS+CR (group I); HS+CR+ VitaSol (group II); HS+CR+Vehicle, Vehicle is the phospholipid vesicles without magnesium ATP, (group III); HS+ VitaSol (group IV); sham-operated control+VitaSol (group V); and a time-matched sham-operated control (group VI). The survival outcome and total tissue water from wet weight/dry weight ratio as a function of adjunct VitaSol resuscitation were evaluated in separate intact animal experiments. RESULTS: HS caused a selective vasoconstriction of the intestinal inflow arterioles (100 microm), which was not seen in the smaller intestinal premucosal arterioles (7-15 microm). CR, which restored baseline hemodynamics, resulted in an initial restoration of intestinal microvascular diameters at all arteriolar levels. However, this was followed by a progressive vasoconstriction and hypoperfusion in premucosal vessels at 120 minutes after RES (-20.48% +/- 2.95% from baseline diameters). In contrast, VitaSol with CR caused enhanced premucosal dilation (+34.27% +/- 4.62%) and augmented flow (+20.50% +/- 10.70%) above prehemorrhage baseline. Vesicles alone had no effect, and VitaSol alone caused only a modest dilation. CR of moderate HS (40% of baseline MAP for 60 minutes, n=10) caused 20% mortality, whereas adjunct VitaSol resuscitation had a 100% survival and less tissue water content. CONCLUSIONS: Our data confirms that CR causes progressive intestinal hypoperfusion. Cellular resuscitation with direct intravenous energy delivery improves intestinal perfusion after CR and results in improved survival and less tissue edema.

Establishing the inhibitory effects of bradykinin on thrombin.

Bradykinin, RPPGFSPFG, has been reported to be an inhibitor of thrombin's roles in blood clotting, platelet activation, and cellular permeability. The exact target, magnitude, and type of inhibition occurring are not well characterized. Based on the individual kinetic parameters calculated here, bradykinin is classified as a weak competitive inhibitor against hydrolysis of S-2238 and of a PAR4-like peptide. The K(m) values increased twofold in the presence of bradykinin, whereas the k(cat) values remained constant. The K(i) values ranged from 170 to 326 microM. Other biochemical studies indicated that bradykinin inhibits release of fibrinopeptide A from fibrinogen. Furthermore, bradykinin hindered the time required for fibrin clot formation. The weak inhibitions observed in vitro suggest that the direct effects of bradykinin on the thrombin active site become significant only at high concentrations, levels that may be difficult to achieve physiologically. Clearly, bradykinin can target thrombin but whether this direct interaction can be achieved in vivo and is sufficient to elicit a response without contributions from other cofactors requires further investigation.

Destabilizing effects of fructose-1,6-bisphosphate on membrane bilayers.

Fructose-1,6-bisphosphate (FBP) is a high-energy glycolytic intermediate that decreases the effects of ischemia; it has been used successfully in organ perfusion and preservation. How the cells utilize external FBP to increase energy production and the mechanism by which the molecule crosses the membrane bilayer are unclear. This study examined the effects ofFBP on membrane bilayer permeability, membrane fluidity, phospholipid packing, and membrane potential to determine how FBP crosses the membrane bilayer. Large unilamellar vesicles composed of egg phosphatidylcholine (Egg PC) were made and incubated with 50 mM FBP spiked with 14C-FBP at 30 degrees C. Uptake of FBP was significant (P < 0.05) and dependent on the lipid concentration, suggesting that FBP affects membrane bilayer permeability. With added calcium (10 mM), FBP uptake by lipid vesicles decreased significantly (P < 0.05). Addition of either 5 or 50 mM FBP led to a significant increase (P < 0.05) in Egg PC carboxyfluorescein leakage. We hypothesized that the membrane-permeabilizing effects of FBP may be due to a destabilization of the membrane bilayer. Small unilamellar vesicles composed of dipalmitoyl pC (DPPC) were made containing either diphenyl-1,3,5-hexatriene (DPH) or trimethylammmonia-DPH (TMA-DPH) and the effects of FBP on the fluorescence anisotropy (FA) of the fluorescent labels examined. FBP caused a significant decrease in the FA of DPH in the liquid crystalline state of DPPC (P < 0.05), had no effect on FA of TMA-DPH in the liquid crystalline state of DPPC, but increased the FA of TMA-DPH in the gel state of DPPC. From phase transition measurements with DPPC/DPH or TMA-DPH, we calculated the slope of the phase transition as an indicator of the cooperativity of the DPPC molecules. FBP significantly decreased the slope, suggesting a decrease in fatty acyl chain interaction (P< 0.05). The addition of 50 mM FBP caused a significant decrease (P< 0.05) in the liquid crystalline/gel state fluorescence ratio of merocyanine 540, indicating increased head-group packing. To determine what effects these changes would have on cellular membranes, we labeled human endothelial cells with the membrane potential probe 3,3'-dipropylthiacarbocyanine iodide (DiSC3) and then added FBP. FBP caused a significant, dose-dependent decrease in DiSC3 fluorescence, indicating membrane depolarization. We suggest that FBP destabilizes membrane bilayers by decreasing fatty acyl chain interaction, leading to significant increases in membrane permeability that allow FBP to diffuse into the cell where it can be used as a glycolytic intermediate.