Demonstration of scale-down dynamic light scattering and determination of osmotic second virial coefficients for proteins

Parupudi, Arun Kumar

15 December 2007

Protein aggregation is a phenomenon that plays a major role in protein crystallization and in protein formulation. In protein crystallization, aggregation is the prerequisite step; however, in protein formulation it has to be suppressed to assure therapeutic efficiency of the product. Light scattering techniques are the most promising methods to study the hydrodynamic properties of macromolecular solutions, which directly measures protein aggregation. Unfortunately, the normal dynamic light scattering technique is regarded as expensive because of the amount of protein used for these experiments. In order to address this problem, a scale down dynamic light scattering device has been designed. The osmotic second virial coefficient, a dilute solution parameter helps in identifying solution conditions for protein crystal growth. The second part of this thesis involves comparison of osmotic second virial coefficient (B) measurements of lysozyme using laser light scattering techniques with B measurements of lysozyme performed using self-interaction chromatography (SIC).

dynamic light scattering

protein aggregation

protein formulation

A solid-state NMR study of molecular mobility and phase separation in co-spray-dried protein-sugar particles

Forbes, Robert T., Apperley, D.C., Suihko, E.J.

January 2005

No / Molecular mobility and physical form of co-spray-dried sugar:lysozyme formulations were evaluated. Co-spray-dried trehalose:lysozyme and sucrose:lysozyme formulations in 1:9, 1:1 and 9:1 ratios (w:w) were stored at 0% RH and 75% RH for 5-6 days. Molecular mobility and physical form of the co-spray-dried formulations after storage were determined by using 13C and 1H solid-state NMR as well as X-ray powder diffractometry. The results showed that increasing sugar content in co-spray-dried formulations stored at 0% RH decreased molecular mobility of the amorphous formulations indicating a close association of the protein and sugar. Exposure of sugar:lysozyme 1:1 and 9:1 formulations to 75% RH led to separation of sugar and protein phases, where the sugar phase was crystalline. The intimate sugar:lysozyme interaction of the formulations stored at 0% RH and the phase separation of the sugar-rich formulations stored at 75% RH were also confirmed by using 13C solid-state NMR spin-lattice relaxation time-filter (T1-filter) measurements. The propensity of sucrose and trehalose to crystallise was similar; however, the results suggest that part of the sugar in the phase-separated formulations remained amorphous and in close association with lysozyme.

Protein formulation

Spray-drying

Solid-state NMR

Molecular mobility

Phase separation

Spray-Dried Powders for Inhalation : Particle Formation and Formulation Concepts

Elversson, Jessica

January 2005

<p>Spray drying is a method with a high potential in the preparation of protein particles suitable for pulmonary delivery. However, surface induced denaturation of bio-molecules during atomization and subsequent drying can be substantial and it is therefore important to develop new formulation concept for concurrent encapsulation and stabilization of proteins during spray drying. Hence, with an overall objective to increase the knowledge of the formation of particulate systems for systemic administration of proteins by spray drying, the first part of this thesis, systematically investigated the particle formation by droplet size and particle size measurements. It was described how specific properties, such as the solubility and the crystallization propensity of the solute, can affect the product, e.g. the particle size, internal structures, and possibly particle density. A new method using atomic force microscopy (AFM) for the assessment of the effective particle density of individual spray-dried particles was demonstrated. In the second part, two different formulation concepts for encapsulation of protein during spray drying were developed. Both systems used non-ionic polymers for competitive adsorption and displacement of protein from the air/water interface during spray drying. The aqueous two-phase system (ATPS) of polyvinyl alcohol (PVA) and dextran, and the surface-active polymers, hydroxypropyl methylcellulose (HPMC) and triblock co-polymer (poloxamer 188) used for in situ coating, proved efficient in encapsulation of a model protein, bovine serum albumin (BSA). Inclusion of polymeric materials in a carbohydrate matrix also influenced several particle properties, such as the particle shape and the surface morphology, and was caused by changes in the chemical composition of the particle surface and possibly the surface rheology. In addition, powder performance of pharmaceutical relevance, such as dissolution and flowability, were affected.</p>

Pharmaceutics

Spray drying

Particle formation

Density

Protein formulation

Encapsulation

Coating

Competitive adsorption

Polymer

ESCA

AFM

FTIR

Galenisk farmaci

Pharmaceutics

Galenisk farmaci

Spray-Dried Powders for Inhalation : Particle Formation and Formulation Concepts

Elversson, Jessica

January 2005

Spray drying is a method with a high potential in the preparation of protein particles suitable for pulmonary delivery. However, surface induced denaturation of bio-molecules during atomization and subsequent drying can be substantial and it is therefore important to develop new formulation concept for concurrent encapsulation and stabilization of proteins during spray drying. Hence, with an overall objective to increase the knowledge of the formation of particulate systems for systemic administration of proteins by spray drying, the first part of this thesis, systematically investigated the particle formation by droplet size and particle size measurements. It was described how specific properties, such as the solubility and the crystallization propensity of the solute, can affect the product, e.g. the particle size, internal structures, and possibly particle density. A new method using atomic force microscopy (AFM) for the assessment of the effective particle density of individual spray-dried particles was demonstrated. In the second part, two different formulation concepts for encapsulation of protein during spray drying were developed. Both systems used non-ionic polymers for competitive adsorption and displacement of protein from the air/water interface during spray drying. The aqueous two-phase system (ATPS) of polyvinyl alcohol (PVA) and dextran, and the surface-active polymers, hydroxypropyl methylcellulose (HPMC) and triblock co-polymer (poloxamer 188) used for in situ coating, proved efficient in encapsulation of a model protein, bovine serum albumin (BSA). Inclusion of polymeric materials in a carbohydrate matrix also influenced several particle properties, such as the particle shape and the surface morphology, and was caused by changes in the chemical composition of the particle surface and possibly the surface rheology. In addition, powder performance of pharmaceutical relevance, such as dissolution and flowability, were affected.

Pharmaceutics

Spray drying

Particle formation

Density

Protein formulation

Encapsulation

Coating

Competitive adsorption

Polymer

ESCA

AFM

FTIR

Galenisk farmaci

Pharmaceutics

Galenisk farmaci