In vivo properties of an in situ forming gel for parenteral delivery of macromolecular drugs

Development of Biodegradable Injectable In situ Forming Implants for Sustained Release of Lornoxicam

OBJECTIVE

The focus of this study was to develop in situ injectable implants of Lornoxicam which could provide sustained drug release.

METHODS

Biodegradable in situ injectable implants were prepared by polymer precipitation method using polylactide-co-glycolide (PLGA). An optimized formulation was obtained on the basis of drug entrapment efficiency, gelling behavior and in vitro drug release. The compatibility of the formulation ingredients were tested by Fourier transform infrared (FT-IR) spectroscopy, and differential scanning colorimetry (DSC). SEM study was performed to characterize in vivo behavior of in situ implant. Pharmacokinetic study and in vivo gelling study of the optimized formulation were performed on Sprague-Dawley rats. Stability testing of optimized formulation was also performed.

RESULTS

The drug entrapment efficiency increased and burst release decreased with an increase in the polymer concentration. Sustained drug release was obtained up to five days. SEM photomicrographs indicated uniform gel formation. Chemical interaction between the components of the formulation was not observed by FT-IR and DSC study. Pharmacokinetic studies of the optimized formulation revealed that the maximum plasma concentration (Cmax), time to achieve Cmax (Tmax) and area under plasma concentration curve (AUC) were significantly higher than the marketed intramuscular injection of lornoxicam. Stability study of optimized batch showed no change in physical and chemical characteristics.

CONCLUSION

Lornoxicam can be successfully formulated as in situ injectable implant that provides long-term management of inflammatory disorders with improved patient compliance.

Delivery of ziconotide to cerebrospinal fluid via intranasal pathway for the treatment of chronic pain

The purpose of the current study was to investigate the plausibility of delivery of ziconotide to the cerebrospinal fluid (CSF) via intranasal administration. Ziconotide was administered either in the form of solution or Kolliphor P 407 gels (KP 407) intranasally in Sprague-Dawley rats. The effect of incorporation of chitosan in the formulation was also investigated. Time course of drug in the CSF was investigated by collecting CSF from cisterna magna. Pharmacokinetics of ziconotide in CSF following intrathecal and intravenous (i.v.) administration of ziconotide was investigated. Upon intrathecal administration the elimination rate constant of ziconotide in CSF was found to be 1.01±0.34h(-1). The Cmax and Tmax of ziconotide in CSF following intravenous administration were found to be 37.78±6.8ng/mL and ~2h respectively. The time required to attain maximum concentration (Tmax) in CSF was less upon intranasal administration (15min) compared to i.v. administration (120min). Presence of chitosan enhanced the overall bioavailability of ziconotide from intranasal solution and gel formulations. The elimination rate constant of ziconotide in CSF following intranasal and intravenous administration of ziconotide solution was found to be 0.54±0.08h(-1) and 0.42±0.10h(-1) respectively. Whereas, intranasal administration of ziconotide in the form of in situ forming gel lowered the elimination rate significantly. These results suggest that intranasal administration could be a potential noninvasive and patient compliant method of delivering ziconotide to CSF to treat chronic pain.

Thermosensitive chitosan/glycerophosphate-based hydrogel and its derivatives in pharmaceutical and biomedical applications

INTRODUCTION

Thermogelling chitosan (CS)/glycerophosphate (GP) solutions have been reported as a new type of parenteral in situ forming depot system. These free-flowing solutions at ambient temperature turn into semi-solid hydrogels after parenteral administration.

AREAS COVERED

Formulation parameters such as CS physico-chemical characteristics, CS/gelling agent ratio or pH of the system, were acknowledged as key parameters affecting the solution stability, the sol/gel transition behavior and/or the final hydrogel structure. We discuss also the use of the standard CS/GP thermogels for various biomedical applications, including drug delivery and tissue engineering. Furthermore, this manuscript reviews the different strategies implemented to improve the hydrogel characteristics such as combination with carrier particles, replacement of GP, addition of a second polymer and chemical modification of CS.

EXPERT OPINION

The recent advances in the formulation of CS-based thermogelling systems already overcame several challenges faced by the standard CS/GP system. Dispersion of drug-loaded carrier particles into the thermogels allowed achieving prolonged release profiles for low molecular weight drugs; incorporation of an additional polymer enabled to strengthen the network, while the use of chemically modified CS led to enhanced pH sensitivity or biodegradability of the matrix.

Thermosensitive chitosan-based hydrogel containing liposomes for the delivery of hydrophilic molecules

A novel injectable in situ gelling thermosensitive chitosan-beta-glycerophosphate (C-GP) formulation has been recently proposed for tissue repair and drug delivery. The system can sustain the release of macromolecules over a period of several hours to a few days. However, with low-molecular-weight hydrophilic compounds, the release is generally completed within 24 h. In this study, liposomes were added to the C-GP solution and their effect on the viscoelastic properties of the system and release kinetics of encapsulated carboxyfluorescein was investigated. The gelation rate and gel strength were slightly increased by the presence of the liposomes. The in vitro release profiles demonstrated controlled delivery over at least 2 weeks. The release rate strongly depended on the liposome size and composition (i.e. addition of cholesterol), and on the presence of phospholipase in the release medium. The kinetics was not substantially modified when using liposomes prepared with a negatively-charged lipid or a lipid having a high phase transition temperature. These results indicate that the liposome-C-GP system rapidly gels at body temperature, and can sustain the delivery of low-molecular-weight hydrophilic compounds. A mathematical model was proposed to characterize the release kinetics.

In situ gel formulations for gene delivery: release and myotoxicity studies

The in vitro release of plasmid DNA and salmon sperm DNA from in situ gel formulations was investigated. Two in situ gel systems were studied: (a) an interpolymeric complex (IPC) of water-soluble polymers polymethacrylic acid (PMA) and polyethylene glycol (PEG) and (b) a hydroxypropylmethylcellulose-carbopol system (H:C). Two-way analysis of variance with replication demonstrated that both gel composition and medium pH influenced significantly the release of plasmid DNA from in situ gel formulations. When the release of both types of DNA was compared, higher release was observed for plasmid DNA compared to genomic salmon sperm DNA. Conformational analysis of the released plasmid DNA showed that DNA was released without degradation, but with remarkable conversion from supercoiled (SC) to open circular (OC). In addition, the tested in situ gel systems demonstrated protection from DNAse I degradation. The myotoxicity of the injectable gelling solutions was assessed by the cumulative release of creatine kinase (CK) over 120 min from the isolated rodent extensor digitorum longus (EDL) muscle. A higher level of cumulative CK was observed for IPC when compared to H:C (2:1). These results demonstrate that the in situ gelling systems can be considered as a valuable injectable controlled-delivery system for pDNA in their role to provide protection from DNAse degradation.

Transdermal delivery of antisense oligonucleotides can induce changes in gene expression in vivo

The potential for using antisense compounds as therapeutic agents has generated great enthusiasm. Strategies for delivery of these compounds are, therefore, of great interest. Transdermal iontophoresis has been used successfully as an enhancement technique for the transdermal delivery of these compounds in vitro. The effectiveness of using percutaneous penetration as a means to deliver therapeutic levels of these compounds in vivo, however, remains to be demonstrated. The purpose of this work was to demonstrate the ability of iontophoretically delivered compounds to alter enzyme levels in the intact rat. A C5 propyne-modified phosphorothioate oligonucleotide (PS-ODN) targeted to the cytochrome p450-3A2 (CYP3A2) mRNA translational start site and the reverse sequence, used as a control, were synthesized. A patch containing either an oligonucleotide or a buffer control was placed on the animal's back, and an iontophoretic current of 0.5 mA/cm2 was applied for 3.5 hours. Twenty-four hours later, CYP3A2 levels were measured noninvasively using the midazolam-induced sleeping rat model. Liver and small intestinal microsomes were made after completion of sleep studies and assayed for CYP3A2, CYP1A1/2, CYP2B1/2, and CYP2E1. Midozolam-treated animals with antisense to CYP3A2 slept significantly longer than did the controls (p < 0.05). CYP3A2 levels were significantly lower in liver microsomes from antisense-treated animals than in either buffer control (p < 0.001) or reverse sequence animals (p < 0.05). The reverse sequence was also significantly different from the buffer control (p < 0.01), indicating a nonspecific effect of the PS background. Nontarget cytochrome levels were not altered by treatment. There were no significant differences in small intestine CYP3A2 levels between treatment groups. These data demonstrate that transdermally delivered PS-ODN can reach concentrations sufficient to induce changes in specific target enzymes in vivo. Further studies are warranted to investigate potential uses for these molecules.