Nasal administration of an angiotensin antagonist in the rat model: effect of bioadhesive formulations on the distribution of drugs to the systemic and central nervous systems.

The effect of bioadhesive formulations on the direct transport of an angiotensin antagonist drug ((14)C-GR138950) from the nasal cavity to the central nervous system was evaluated in a rat model. Three different bioadhesive polymer formulations (3% pectin LM-5, 1.0% pectin LM-12 and 0.5% chitosan G210) containing the drug were administered nasally to rats by inserting a dosing cannula 7mm into the nasal cavity after which the plasma and brain tissue levels were measured. It was found that the polymer formulations provided significantly higher plasma levels and significantly lower brain tissue levels of drug than a control, in the form of a simple drug solution. Changing the depth of insertion of the cannula from 7 to 15mm, in order to reach the olfactory region in the nasal cavity significantly decreased plasma levels and significantly increased brain tissue levels of drug for the two formulations studied (1.0% pectin LM-12 and a simple drug solution). There was no significant difference between the drug availability for the bioadhesive formulation and the control in the brain when the longer cannula was used for administration. It is suggested that the conventional rat model is not suitable for evaluation of the effects of bioadhesive formulations in nose-to-brain delivery.

Distribution and clearance of bioadhesive formulations from the olfactory region in man: effect of polymer type and nasal delivery device.

There is an increasing need to identify novel approaches by which to improve the efficiency of drug transport from the nasal cavity (olfactory region) to the CNS, especially for treatment of central nervous system disorders. It is suggested, that one approach is the combination of active targeting of a bioadhesive formulation, that will retain the drug at the absorption site, potentially in combination with, an absorption enhancer. Two low methylated pectins, LM-5 and LM-12 were selected for evaluation as drug delivery systems, due to their ability to gel in the nasal cavity and their bioadhesive characteristics, together with chitosan G210, which acts both as a bioadhesive material and as an efficient absorption enhancer. It was found that all of the bioadhesive formulations were able to reach the olfactory region in the nasal cavity of human volunteers when delivered using a simple nasal drop device. Furthermore, the formulations displayed a significantly increased residence time on the epithelial surface. This was in contrast to a non-bioadhesive control delivered with the same device. In contrast, a pectin formulation administered with a nasal spray system did not show an increase in residence time in the olfactory region. It was further shown that the reproducibility of olfactory delivery of a polymer formulation was significantly better intra-subject than inter-subject.

Evaluation of bioadhesive polymers as delivery systems for nose to brain delivery: in vitro characterisation studies.

There is an increasing need for nasal drug delivery systems that could improve the efficiency of the direct nose to brain pathway especially for drugs for treatment of central nervous system disorders. Novel approaches that are able to combine active targeting of a formulation to the olfactory region with controlled release bioadhesive characteristics, for maintaining the drug on the absorption site are suggested. If necessary an absorption enhancer could be incorporated. Low methylated pectins have been shown to gel and be retained in the nasal cavity after deposition. Chitosan is known to be bioadhesive and also to work as an absorption enhancer. Consequently, two types of pectins, LM-5 and LM-12, together with chitosan G210, were selected for characterisation in terms of molecular weight, gelling ability and viscosity. Furthermore, studies on the in vitro release of model drugs from candidate formulations and the transport of drugs across MDCK1 cell monolayers in the presence of pectin and chitosan were also performed. Bioadhesive formulations providing controlled release with increased or decreased epithelial transport were developed. Due to their promising characteristics 3% LM-5, 1% LM-12 pectin and 1% chitosan G210 formulations were selected for further biological evaluation in animal models.

Development of a novel nasal nicotine formulation comprising an optimal pulsatile and sustained plasma nicotine profile for smoking cessation.

A novel nasal formulation, in the form of a nicotine-Amberlite resin complex powder has been developed that provided an optimal combined pulsatile and sustained plasma nicotine profile for smoking cessation. The adsorption isotherms of nicotine hydrogen tartrate salt on two types of Amberlite resins (IRP69 and IR120) were evaluated and the subsequent in vitro release properties of nicotine from the nicotine-Amberlite complex powders were tested using a Franz diffusion cell. Amberlite IRP69 and Amberlite IR120 are similar cationic exchange materials with the same ion-exchange capacity but due to a smaller particle size range (10-150 microm) Amberlite IRP69 had a better flow property and a better adsorptive capacity than Amberlite IR120. The material is used as an excipient in marketed pharmaceutical formulations. The highly water soluble salt, nicotine hydrogen tartrate, displayed good adsorption onto both types of Amberlite resin. The maximum adsorption of nicotine onto Amberlite IRP69 was 1.071 mg drug per mg resin. The cumulative release of drug from nicotine hydrogen tartrate-Amberlite complex powders showed that the higher the drug loading, the faster was the rate of release of the drug. Based on these results, various nicotine hydrogen tartrate-Amberlite IRP69 powder formulations containing different ratios of free to bound drug (50% to 100% bound) and a control solution were prepared and evaluated in a sheep model by nasal administration. The nicotine plasma profiles demonstrated that an initial rapid peak plasma level of nicotine followed by a sustained elevated level could be achieved by adjusting the ratio of free to bound nicotine in the Amberlite powder formulation. The curves obtained from some of the formulations were comparable to those predicted from a computer-generated pharmacokinetic model.