Performance characteristics of UV imaging instrumentation for diffusion, dissolution and release testing studies.

UV imaging is capable of providing spatially and temporally resolved absorbance measurements, which is highly beneficial in drug diffusion, dissolution and release testing studies. For optimal planning and design of experiments, knowledge about the capabilities and limitations of the imaging system is required. The aim of this study was to characterize the performance of two commercially available UV imaging systems, the D100 and SDI. Lidocaine crystals, lidocaine containing solutions, and gels were applied in the practical assessment of the UV imaging systems. Dissolution of lidocaine from single crystals into phosphate buffer and 0.5% (w/v) agarose hydrogel at pH 7.4 was investigated to shed light on the importance of density gradients under dissolution conditions in the absence of convective flow. In addition, the resolution of the UV imaging systems was assessed by the use of grids. Resolution was found to be better in the vertical direction than the horizontal direction, consistent with the illumination geometry. The collimating lens in the SDI imaging system was shown to provide more uniform light intensity across the UV imaging area and resulted in better resolution as compared to the D100 imaging system (a system without a lens). Under optimal conditions, the resolution was determined to be 12.5 and 16.7 line pairs per mm (lp/mm) corresponding to line widths of 40µm and 30µm in the horizontal and vertical direction, respectively. Overall, the performance of the UV imaging systems was shown mainly to depend on collimation of light, the light path, the positioning of the object relative to the line of 100µm fibres which forms the light source, and the distance of the object from the sensor surface.

In vitro release studies of insulin from lipid implants in solution and in a hydrogel matrix mimicking the subcutis.

Widely accepted in vitro methodologies for sustained release parenteral drug formulations remain to be established. Hydrogels have been proposed as a release matrix more closely resembling the in vivo conditions for formulations intended for subcutaneous administration. The perspective of the current work was to investigate the feasibility of developing UV imaging-based in vitro methods enabling visualization and characterization of drug release and transport of protein therapeutics intended for subcutaneous administration. Specifically, the objectives were to prepare lipid implants providing sustained release of the model protein insulin and investigate the release into 0.5% (w/v) agarose hydrogels, pH7.40, using UV imaging- and a gel sampling-based release testing method. These results were compared to insulin release into well agitated buffer solution. Irrespective of the applied in vitro release method, the insulin release from Sterotex implants with a drug load of 20% (w/w) was faster as compared to the release from implants with a load of 10% (w/w), most likely due to the higher porosity of the implants with increasing drug load. Insulin release from 10% (w/w) implants into agitated solution was faster as compared to release into agarose hydrogel. This was ascribed to the additional mass transfer resistance provided by the agarose hydrogel. Interestingly, the release profiles of insulin from implants with an initial drug load of 20% (w/w) obtained by the three in vitro methods were relatively similar. The gel-based methods, in particular UV imaging, enable monitoring local drug concentrations in the vicinity of the implant over time thereby facilitating assessment of, e.g., sink conditions. The study highlights that the selection of the in vitro release method should take into account various factors including mass transport, drug stability, data analysis and simplicity of the methodology.

Real-time UV imaging identifies the role of pH in insulin dissolution behavior in hydrogel-based subcutaneous tissue surrogate.

For parenteral biopharmaceuticals, subcutaneous diffusion and, in the case of solid implants or suspensions, dissolution may govern the clinical profile of the drug product. Insight into the dissolution and diffusion processes of biopharmaceuticals after parenteral administration is fundamental in the development of new protein drug formulations. Using insulin as a model compound, the aim of this work was to develop a UV imaging-based method to study the real-time dissolution and diffusion behavior of solid protein drugs under stagnant conditions in a hydrogel matrix mimicking the subcutaneous tissue. Dissolution of proteins and peptides is a complex phenomenon as it may be coupled to the complicated acid base properties of these substances. UV imaging allowed the real-time dissolution and diffusion processes of insulin at different pH values and of different insulins to be studied. Dissolution rates were obtained, and the quantitative performance of the developed UV imaging method was verified. It was shown that the UV imaging dissolution method was able to differentiate between the behavior of different insulins and that human insulin dissolution was highly dependent on pH. pH effects in the microenvironment of the human insulin compacts at pH 7.40 and 3.00 were observed by UV-Vis imaging, explaining the different dissolution kinetics of human insulin at pH 7.40 and 3.00 as compared to pH 5.40. In conclusion, UV-Vis imaging may be a useful tool for studying dissolution, diffusion and pH effects in the vicinity of solid protein drug in a hydrogel matrix with the aim of achieving a better understanding of in vivo dissolution processes.

Insulin diffusion and self-association characterized by real-time UV imaging and Taylor dispersion analysis.

Assessment of release kinetics of subcutaneously administered protein therapeutics remains a complex challenge. In vitro methods capable of visualizing and characterizing drug transport properties, in the formulation as well as surrounding subcutaneous tissue environment, are desirable in drug development. Diffusion is a key process in drug release and transport. Thus, our objective was to develop a UV imaging in vitro method for direct visualization and characterization of insulin diffusivity and self-association behavior. Agarose hydrogels were used for mimicking subcutaneous tissue. Diffusivity, self-association, and apparent size of insulin were further characterized by Taylor dispersion analysis, size exclusion chromatography, and dynamic light scattering. At low insulin concentrations and pH 3.0, the hydrodynamic radius of insulin was determined by Taylor dispersion analysis to 1.5±0.1nm, corresponding to the size of insulin monomer. Increasing concentration and pH to 1mM and pH 7.4, respectively, favoring insulin hexamers, increased the insulin hydrodynamic radius to 3.0±0.1nm. The UV imaging method developed was adequately sensitive to identify and characterize, in terms of diffusion coefficients, the changes in insulin transport in hydrogel due to pH and concentration changes. In conclusion, UV imaging allowed insulin diffusion in hydrogel matrixes to be studied in real-time, and showed that insulin self-association properties were reflected in the diffusion behavior. UV imaging is a useful tool for characterization of the influence of environmental conditions on protein mass transport. Hydrogels combined with UV imaging may be of utility for in vitro testing of protein therapeutics.