Synthesis, properties, and in vivo evaluation of sustained release albumin-mitoxantrone microsphere formulations for nonsystemic treatment of breast cancer and other high mortality cancers

Methods for preparing mitoxantrone (MXN)-loaded albumin microspheres for the treatment of breast cancer were developed. The effect of processing conditions on the particle size of unloaded and MXN-loaded microspheres was evaluated using multivariate analyses. The data suggested that the particle size of unloaded microspheres increased as protein concentration increased or the steric stabilizer concentration decreased. In addition, synergy between these two variables was observed. In situ-loading of MXN achieved loading efficiencies in excess of 80%. Comparable efficiencies were achieved with postsynthesis loading when the microsphere were prepared from albumin-poly(glutamic acid) blends. In vitro release of MXN in phosphate buffered saline under infinite sink conditions showed that the total amount of drug released increased as the glutaraldehyde concentration decreased. This trend was reversed when the microspheres were incubated in plasma. Nanoparticles were also prepared using ethanol desolvation. These particles were dispersible in saline and easily modified with amino acids. In addition, particle size could be varied by use of different non-ionic surfactants in the preparation.; The effect of intratumoral (IT) versus intravenous (IV) drug administration on tumor response and systemic toxicity was investigated in vivo using the 16/C murine mammary adenocarcinoma tumor model. The data suggested that IT-treated animals had significantly smaller tumors and lower weight loss when compared to IV-treated animals. Furthermore, the addition of surgery to the chemotherapy further improved the survival of the animals. Pilot studies using MXN-albumin microspheres suggested that microspheres could be safely administered IT in doses up to 48 mg/kg. However, there was no evidence that this higher dose resulted in improved long term survival when compared to the 32 mg/kg dose. The maximum tolerated dose of MAN given IT was approximately 12 mg/kg. The animal studies suggested that IT chemotherapy could result in significant reduction in tumor burden and systemic toxicity when compared to conventional IV chemotherapy. Microsphere-bound drug could be safely administered IT at very high doses. In addition, microspheres exerted an antitumoral effect over an extended period of time; however, complete tumor regression was achieved only by complete tumor perfusion.