Abstract
Approximately two-third of the compounds in the pharmaceutical industry were developed through combinatorial chemistry and high throughput screening of particulate solids. Poor solubility and bioavailability of these pharmaceuticals are challenging attributes confronted by a formulator during product development. Hence, substantial efforts have been directed into the research on particle generation techniques. Although the conventional methods, such as crushing or milling and crystallization or precipitation, are still used; supercritical fluid technology introduced in the mid-1980s presents a new method of particle generation. Supercritical fluid processes not only produce micro- and nanoparticles with a narrow size distribution, they are also employed for the microencapsulation, cocrystallization, and surface coating with polymer. Recognized as a green technology, it has emerged as successful variants chiefly as Rapid Expansion of supercritical solutions (RESS), Supercritical anti-solvent (SAS) and Particles from Gas Saturated Solution (PGSS) depending upon type of solvent, solute, antisolvent and nebulization techniques. Being economical and eco-friendly, supercritical fluid technolgy has garnered considerable interest both in academia and industry for modification of physicochemical properties such as particle size, shape, density and ultimately solubility. The current manuscript is a comprehensive update on different supercritical fluid processes used for particle generation with the purpose of solubility enhancement of drugs and hence bioavailability.
Highlights
In the last decade, supercritical fluid (SCF) processes have been extensively utilized for pursuing chemical reactions, extraction, crystallization, precipitation, purification, and development of micro- and nanoparticles
As a well known fact the bioavailability of drugs depends on the absorption through gastrointestinal tract that is in turn governed by their solubility and dissolution
The solubility of the drug substance in supercritical CO2 had a major effect on the average diameter of the particle prepared by Rapid Expansion of Supercritical Solutions (RESS) process, and the particle diameter decreased with the solubility for all the drugs and operating conditions [15]
Summary
Supercritical fluid (SCF) processes have been extensively utilized for pursuing chemical reactions, extraction, crystallization, precipitation, purification, and development of micro- and nanoparticles. SCF methods produce micro- and nanoparticles of uniform size distribution, but are extensively applied for microencapsulation and polymeric surface coating on drug crystals, cocrystallization with excipients and development of soluble complexes with cyclodextrin. The solubility of the drug substance in supercritical CO2 has a major effect on the average diameter of the particles prepared by RESS process. The solubilities of drug substances in supercritical CO2 and the effects of various operating parameters on the characteristics of the particles prepared by RESS process were experimentally investigated. The solubility of the drug substance in supercritical CO2 had a major effect on the average diameter of the particle prepared by RESS process, and the particle diameter decreased with the solubility for all the drugs and operating conditions [15]. The amount of residual solvent in the crystallized powder must not exceed 5000 ppm
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