Lipoplatin

Lipoplatin (Liposomal cisplatin) is a nanoparticle of 110 nm average diameter composed of lipids and cisplatin.[1] This new drug has successfully finished Phase I, Phase II and Phase III human clinical trials.[2][3] It has shown superiority to cisplatin in combination with paclitaxel as a chemotherapy regimen in non-small cell lung cancer (NSCLC) adenocarcinomas.

Mechanism of action

Lipoplatin evades immune surveillance thus escaping clearance from macrophages, circulates for long periods in body fluids after intravenous administration with a half-life of ~120 h, and extravasates through the compromised endothelium of the vasculature in tumors created during the process of neoangiogenesis Extravasation Figure. Thus, Lipoplatin nanoparticles are concentrated to the primary tumor and metastases. Human studies have shown 40- to 200-fold higher platinum concentration compared to the adjacent normal tissue in specimens from human biopsies 20h post-infusion of the drug.[4] Lipoplatin nanoparticles once inside the tumor cell mass can fuse with the cell membrane because of the presence of the fusogenic lipid DPPG in their lipid bilayer; an alternative mechanism proposed is that Lipoplatin is taken by endocytosis by tumor cells as shown from Lipoplatin containing fluorescent lipids and imaging of the tumor cells in culture thus treated with fluorescent microscopy. These processes occurring at the cell membrane level are promoted by the lipid shell of the nanoparticles (disguised as nutrients). The technology allows Lipoplatin to empty its toxic payload (cisplatin) inside the cytoplasm to kill the tumor cell. The cell membrane is considered a significant barrier to transportation of the toxic molecules of cisplatin across and inside the tumor cell.

Trials

The results of a Phase III trial were published in October 2011 in Cancer Chemother Pharmacol. Vol 68, pages 945-950 (Open access at http://www.springerlink.com/content/c2624362664404t5/). This study used Lipoplatin in combination with paclitaxel as first line treatment against ns-NSCLC and compared response rates and toxicities to a similar group of patients treated with cisplatin plus paclitaxel. This study has demonstrated an increase in tumor response rate in the Lipoplatin arm (59.22% of patients) versus the cisplatin arm (42.42%, of patients) which was statistically significant (p value = 0.036). Most major toxicities of cisplatin, especially nephrotoxicity were also reduced in the group of patients treated with Lipoplatin. Median survival times were 10 months for the Lipoplatin arm and 8 months for the cisplatin arm, with a p-value of 0.155. The median duration of response was 7 months for the Lipoplatin arm and 6 months for the cisplatin arm. Although not statistically significant, these results suggest the potential for superior overall survival (OS) for Lipoplatin compared to cisplatin, a hypothesis that is being tested in a larger trial. Furthermore, among the responders to Lipoplatin a subgroup of patients demonstrated a substantially higher overall survival than a comparable subgroup of cisplatin responders. After 10 months, 30% of patients in the Lipoplatin arm, as compared with just 16% of patients in the cisplatin arm, were without disease progression. By the end of the trial, there were 32 patients alive, 21 from the Lipoplatin arm (20.39%) and 11 from the cisplatin arm (11.11%). Thus, after 18 months, the number of surviving patients was approximately double for Lipoplatin versus cisplatin. The clinical development of Lipoplatin in adenocarcinomas establishes this drug as the most active platinum drug with significantly lower side effects.

EMEA has given the orphan drug status to Lipoplatin in 2007 in an ongoing registrational Phase II/III study as a first line-treatment in pancreatic cancer.[5] Lipoplatin, under the name Nanoplatin, received in 2009 the consent of EMEA to be tested as first line against non-squamous NSCLC mainly composed of adenocarcinomas. In a randomized Phase III it has shown statistically significant reduction of the toxicity of cisplatin, mainly of nephrotoxicity, in an administration regimen that does not require hospitalization of the patients as in the case of cisplatin chemotherapy. Figure 1 shows a cartoon depicting the fusion process between a Lipoplatin liposome and the cell membrane and resulting in bypassing part of the platinum drug resistance mechanisms at the level of cisplatin import. Figure 2 shows a GG crosslink in the DNA inflicted by a molecule of cisplatin (DNA damage).

References

  1. Apps, M. G., Choi, E. H. Y., Wheate, N. J. (2015). "The state-of-play and future of platinum drugs". Endocrine-related Cancer. 22 (4): 219–233. doi:10.1530/ERC-15-0237. PMID 26113607.
  2. Stathopoulos GP, Boulikas T, Vougiouka M, Deliconstantinos G, Rigatos S, Darli E, Viliotou V, and Stathopoulos JG: Pharmacokinetics and adverse reactions of a new liposomal cisplatin (Lipoplatin): Phase I study Oncol Rep 13, 589-595 (2005).
  3. Boulikas T. Clinical overview on Lipoplatin: a successful liposomal formulation of cisplatin. Expert Opin Investig Drugs. 2009 Aug;18(8):1197-218.
  4. Boulikas T, Stathopoulos GP, Volakakis N and Vougiouka M. Systemic Lipoplatin infusion results in preferential tumor uptake in human studies. Anticancer Res, 25:3031-3040, 2005.
  5. http://www.ema.europa.eu/pdfs/human/comp/opinion/16785007en.pdf

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