The aim of this study was to examine the effects of ingesting a carbohydrate-electrolyte solution on endurance capacity during a prolonged intermittent, high-intensity shuttle running test (PIHSRT). Nine trained male games players performed two exercise trials, 7 days apart. On each occasion, they completed 75 min exercise, comprising of five 15-min periods of intermittent running, consisting of sprinting, interspersed with periods of jogging and walking (Part A), followed by intermittent running to fatigue (Part B). The subjects were randomly allocated either a 6.9% carbohydrate-electrolyte solution (CHO) or a non-carbohydrate placebo (CON) immediately prior to exercise (5 ml kg-1 body mass) and every 15 min thereafter (2 ml kg-1 body mass). Venous blood samples were obtained at rest, during and after each PIHSRT for the determination of glucose, lactate, plasma free fatty acid, glycerol, ammonia, and serum insulin and electrolyte concentrations. During Part B, the subjects were able to continue running longer when fed CHO (CHO = 8.9 +/- 1.5 min vs CON = 6.7 +/- 1.0 min; P < 0.05) (mean +/- S.E.M.). These results show that drinking a carbohydrate-electrolyte solution improves endurance running capacity during prolonged intermittent exercise.
DC Bead is a FDA cleared embolisation device for the treatment of hypervascular tumours and arteriovenous malformations. This product is currently evaluated in a number of centres in Europe as an embolic device for transarterial chemoembolisation (TACE). The beads consist of poly(vinyl alcohol) microspheres modified with sulfonic acid groups and are available at different size ranges varying from 100 to 900 microm in diameter. The beads were shown to actively sequester doxorubicin hydrochloride (dox) from solution in a time dependent upon the dose of the drug and size of the beads. Drug uptake was by an ion-exchange mechanism, and in the absence of other ions in solution, the beads could load a maximum of around 40 mg dox/mL hydrated beads, with >99% of drug being sequestered from the solution. A loading of 25 mg dox/mL beads was recommended as providing a practical therapeutic dose and optimum handling characteristics. There was a decrease in equilibrium water content of the beads with increasing dox loading, which resulted in a decrease in the average diameter of the beads and an increase in the compressive modulus. The deliverability properties, however, were not affected after drug loading. Using a variety of microscopic methods, the drug was shown to be distributed throughout the bead structure, but concentrated in the outer 20 microm surface layer, a feature related to the method of synthesis. This study characterises the properties of DC Bead loaded with dox with respect to important characteristics in embolisation and demonstrates the potential of this drug device combination for the treatment of hypervascular tumours such as hepatocellular carcinoma.
DC Bead is a sulfonate-modified, PVA-based microspherical embolisation agent approved for the treatment of hypervascular tumours and arterio-venous malformations. The beads have previously been shown to actively sequester oppositely charged drugs, such as doxorubicin hydrochloride (dox) by an ion-exchange mechanism. In order to characterise the release kinetics and predict the in vivo behaviour of drug eluting beads (DEB), two elution methods were utilised. The first, an application of the USP dissolution method Type II - Apparatus, enables study of the complete elution of loaded DC Bead in less than 4 h, allowing relatively rapid comparison to be made between different products and formulations. Release data obtained using this method were fitted to first order kinetics (R (2) > 0.998) and the elution constants shown to increase with the total surface area of the beads exposed to the elution medium. Diffusion coefficients were calculated adopting the Fickian diffusion model, which predicted slow elution rates under physiological conditions. The second method involved the use of a T-Apparatus where the drug experiences an element of diffusion through a static environment. This method was developed to resemble the in vivo situation in embolisation procedures more closely. Slow release of dox from DC Bead with half-lives over 1,500 h were predicted for all size ranges using a slow release model. A strong linear relationship was found between the release data from T-Apparatus and pharmacokinetic data obtained from patients treated with DC Bead loaded with dox in transarterial chemoembolisation (TACE) procedures. These data indicated a Level A in vitro-in vivo correlation (IVIVC) for the first 24 h post embolisation. Both systems developed were automated and good reproducibility was obtained for all samples, demonstrating the usefulness of these elution techniques for product development and comparative testing.
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