Melt Amorphisation of Orlistat with Mesoporous Silica Using a Supercritical Carbon Dioxide: Effects of Pressure, Temperature, and Drug Loading Ratio and Comparison with Other Conventional Amorphisation Methods.

Heejun Park,Min-Soo Kim,Seung Hyeon Hong,Jeong-Soo Kim,Kwang-Ho Cha,Sung-Joo Hwang,Sharif Md Abuzar,Eun-Sol Ha

doi:10.3390/pharmaceutics12040377

Abstract

The aim of this work was to develop an amorphous orlistat-loaded mesoporus silica formulation using the melt-amorphisation by supercritical fluid (MA-SCF) and to investigate the effects of pressure and temperature on the pharmaceutical properties of the developed formulation. In addition, the effect of orlistat mass ratio to the mesoporus silica was also evaluated. The carbon dioxide was used as a supercritical fluid, and Neusilin®UFL2 was selected as the mesoporous silica. For comparison with conventional amorphisation methods, orlistat formulations were also prepared by solvent evaporation and hot melt methods. Various pharmaceutical evaluations including differential scanning calorimetry, powder X-ray diffraction, scanning electron microscopy, specific surface area, total pore volume, and content uniformity were performed to characterise the prepared orlistat formulation. The melting point depression and the solubility of orlistat in supercritical carbon dioxide (SC-CO2) were selected for the interpretation of evaluated results in relation to temperature and pressure. The total pore volume of the prepared orlistat-loaded mesoporus silica decreased with an increasing density of SC-CO2 to about 500 g/L at a constant temperature or pressure. From these results, it was suggested that increasing the density of SC-CO2 to about 500 g/L could result in the easier penetration of CO2 into molten orlistat and lower viscosity, hence facilitating the introduction and loading of orlistat into the pores of Neusilin®UFL2. However, when the density of SC-CO2 increased to more than 500 g/L, the total pore volume increased, and this may be due to the release out of orlistat from the pores of Neusilin®UFL2 by the increased orlistat solubility in SC-CO2. Interestingly, as the total pore volume decreased by the filling of the drug, the drug crystallinity decreased; hence, the dissolution rate increased. Furthermore, it was shown that the most desirable mass ratio of Neusilin®UFL2:orlistat for the amorphisation was 1:0.8 at an optimised supercritical condition of 318 K and 10 MPa. Compared with other amorphisation methods, only the sample prepared by the MA-SCF method was in pure amorphous state with the fastest dissolution rate. Therefore, it was concluded that the amorphous orlistat-loaded mesoporus silica prepared using MA-SCF under optimised conditions was more advantageous for enhancing the dissolution rate of orlistat than other conventional amorphisation methods.

Highlights

OOrrlliissttaatt, aa ddeerriivvaattiivvee ooff lliippssttaattiinn, iiss aa ppootteenntt lliippaassee iinnhhiibbiittoorr iissoollaatteedd ffrroomm tthhee bbaacctteerriiuumm SSttrreeppttoommyycceess ttooxxyyttrriicciinnii aanndd hhaassbbeeeennuusseeddfoforrmmananyyyeyaerasrstototrteraetatoboebseitsyit.yT. hTehcehecmheicmailcnalamnaemoef oorfliosrtlaitstaist i(sS()S-1)--1[[-([2[S(2,3SS,3)-S3)--h3-ehxeyxl-y4l--o4x-oox-2o--o2x-oetxaentaynl]yml]emtheythl]y-dl]o-ddoecdyelcyelsteesrter(F(iFgiugruere11).)
The results showed that the total pore volume of orlistat-loaded mesoporous silica decreased with the increasing density of SC-CO2
It is suggested that the high density of SC-CO2, which could penetrate into molten orlistat and decrease the viscosity, facilitated the loading of orlistat into the pores of Neusilin®UFL2

Summary

Introduction

OOrrlliissttaatt,, aa ddeerriivvaattiivvee ooff lliippssttaattiinn,, iiss aa ppootteenntt lliippaassee iinnhhiibbiittoorr iissoollaatteedd ffrroomm tthhee bbaacctteerriiuumm SSttrreeppttoommyycceess ttooxxyyttrriicciinnii aanndd hhaassbbeeeennuusseeddfoforrmmananyyyeyaerasrstototrteraetatoboebseitsyit.yT. hTehcehecmheicmailcnalamnaemoef oorfliosrtlaitstaist i(sS()S-1)--1[[-([2[S(2,3SS,3)-S3)--h3-ehxeyxl-y4l--o4x-oox-2o--o2x-oetxaentaynl]yml]emtheythl]y-dl]o-ddoecdyelcyelsteesrter(F(iFgiugruere11).). Cha et al used supercritical CO2 to lower both the melting temperature of fenofibrate and the viscosity of molten fenofibrate, and thereby load the molten fenofibrate into the adsorbent as an amorphous composite [32] These studies took advantage of the fact that gases with high solubility can considerably decrease the melting points of chemical drugs [33,34,35]. SC-CO2 can diffuse well into a solute, lowering its melting point, viscosity, and surface tension; this in turn aids the penetration of the substrate into the pores of mesoporous silica, and the melted drug can be distributed into the pores of mesoporous silica [36,37,38] This melt-amorphisation by supercritical fluid (MA-SCF) has less restriction due to the limited solubility of the drug in SC-CO2, and it is possible to prepare a formulation with high drug loading. The powder dissolution test was conducted to evaluate the differences in dissolution rates between samples

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Conclusion