A Comparative Study between A Protein Based Amorphous Formulation and Other Dissolution Rate Enhancing Approaches: A Case Study with Rifaximin

Exploring the effect of protein secondary structure on the solid state and physical stability of protein-based amorphous solid dispersions

Amorphous solid dispersions (ASDs) using proteins as carriers have emerged as a promising strategy for stabilizing amorphous drug molecules. Proteins possess diverse three-dimensional structures that significantly influence their own properties and may also impact the properties of ASDs. We prepared β-lactoglobulin (BLG) with different contents of β-sheet and α-helical secondary structures by initially dissolving BLG in different mixed solvents, containing different ratios of water, methanol/ethanol, and acetic acid, followed by spray drying of the solutions. Our findings revealed that an increase in α-helical content resulted in a decrease in the glass transition temperature (Tg) of the protein. Subsequently, we utilized the corresponding mixed solvents to dissolve both BLG and the model drug celecoxib (CEL), allowing the preparation of ASDs containing either β-sheet-rich or α-helix/random coil-rich BLG. Using spray drying, we successfully developed BLG-based ASDs with drug loadings ranging from 10 wt% to 90 wt%. At drug loadings below 40 wt%, samples prepared using both methods exhibited single-phase ASDs. However, heterogeneous systems formed when the drug loading exceeded 40 wt%. At higher drug loadings, physical stability assessments demonstrated that the α-helix/random coil-rich BLG structure exerted a more pronounced stabilizing effect on the drug-rich phase compared to the β-sheet-rich BLG. Overall, our results highlight the importance of considering protein secondary structure in the design of ASDs.

Investigating the influence of protein secondary structure on the dissolution behavior of β-lactoglobulin-based amorphous solid dispersions

Proteins acting as carriers in amorphous solid dispersions (ASDs) demonstrate a notable sensitivity to the spray drying process, potentially leading to changes in their conformation. The main aim of this study was to investigate the dissolution performance of ASDs based on proteins with different content of secondary structures, specifically β-sheet and α-helix structures. We prepared β-sheet-rich and α-helix-rich β-lactoglobulin (BLG), along with corresponding ASDs containing 10 wt% and 30 wt% drug loadings, through spray drying using celecoxib as the model drug. Circular dichroism and Fourier Transform Infrared Spectroscopy results revealed that even though changes in secondary structure were obtained in the spray-dried powders, the BLGs exhibited reversibility upon re-dissolving in phosphate buffer with varying pH levels. Both β-sheet-rich BLG and α-helix-rich BLG exhibited enhanced dissolution rates and higher solubility in the media with pH values far from the isoelectric point (pI) of BLG (pH 2, 7, 8, and 9) compared to the pH closer to the pI (pH 3, 4, 5, and 6). Notably, the release rate and solubility of the drug and BLG from both types of BLG-based ASDs at 10 wt% drug loading were largely dependent on the solubility of pure SD-BLGs. α-helix-rich BLG-ASDs consistently exhibited equivalent or superior performance to β-sheet-rich BLG-ASDs in terms of drug release rate and solubility, regardless of drug loading. Moreover, both types of BLG-based ASDs at 10 wt% drug loading exhibited faster release rates and higher solubility, for both the drug and BLG, compared to the ASDs at 30 wt% drug loading in pHs 2, 7, and 9 media.

Mechanisms of Drug Solubility Enhancement Induced by β-Lactoglobulin-Based Amorphous Solid Dispersions

Protein-based amorphous solid dispersions (ASDs) have emerged as a promising approach for enhancing solubility in comparison to crystalline drugs. The dissolution behavior of protein-based amorphous solid dispersions (ASDs) was investigated in various pH media. ASDs of four poorly soluble model drugs with acidic (furosemide and indomethacin), basic (carvedilol), and neutral (celecoxib) properties were prepared by spray drying at 30 wt % drug loading with the protein β-lactoglobulin (BLG). The effect of spray-dried BLG (SD-BLG) solubility and protein binding ability with dissolved drugs in solution were investigated to retrieve the mechanisms governing the improvement of drug solubility from the BLG-based ASDs. Powder dissolution results showed that all ASDs obtained a higher maximum concentration (Cmax) compared to the respective pure crystalline drugs. It was found that the solubility increase of the drugs from the ASDs was to a large extent dependent on the solubility of the pure SD-BLG at the investigated pH values (low solubility at pH near the isoelectric point (pI) of BLG). Furthermore, drug-protein interactions in a solution were observed, in particular at pH values where the drugs were neutral. These drug-protein interactions also resulted, to some extent, in the stabilization of the drug in supersaturation.

Enhanced dissolution rate of nimodipine through β-lactoglobulin based formulation

Amorphous solid dispersions (ASD) have been considered as one of the most effective strategies to increase solubility and dissolution rate of poorly water-soluble drugs. Carriers, in which the poorly water-soluble drug is dispersed, contribute a large extent to the solid-state properties, stabilities and dissolution performance of ASDs. This study investigated the solid-state properties, physical stability, and in vitro dissolution behaviour of nimodipine ASDs formulated with a traditional polymeric carrier, i.e., polyvinylpyrrolidone (PVP) and a novel carrier, i.e., β-lactoglobulin (BLG). The ASDs with both carriers were prepared using ball milling as preparative technique at 10 %, 17.5 %, 25 %, 30 % and 40 % drug loadings (DLs). All the formulations were found to be amorphous upon milling for 60 min based on X-ray powder diffraction measurements, however, the ASDs were found to be homogeneous unequivocally only at DLs below 25 %. After open storage at accelerated conditions (40 °C/75 % relative humidity), only the ASDs formulated with BLG at 10 % and 17.5 % DLs maintained the amorphous form. The dissolution study revealed that all the freshly prepared ASDs formulated with PVP and the ASDs formulated with BLG at or above 25 % DLs, showed a low drug release (<30 µg/mL in simulated gastric fluid, < 70 µg/mL in simulated intestinal fluid). Whilst the ASD formulated with BLG at 10 % DL exhibited a high drug release with a maximum concentration (C_max) of 251 µg/mL in simulated gastric fluid and 231 µg/mL in simulated intestinal fluid. Surprisingly, the ASD formulated with BLG at 17.5 % DL demonstrated an even higher drug release (C_max, 643 µg/mL in simulated gastric fluid, 332 µg/mL in simulated intestinal fluid), compared to the ASD of 10 % DL. These findings underline the importance of rationally investigating both carrier types and DL in the design of ASDs, in order to obtain a stable ASD with the desired enhanced dissolution rate of poorly water-soluble drugs.