Growth of Metastatic Triple-Negative Breast Cancer Is Inhibited by Deep Tumor-Penetrating and Slow Tumor-Clearing Chemotherapy: The Case of Tumor-Adhering Liposomes with Interstitial Drug Release.

The poor prognosis of triple-negative breast cancer (TNBC) is attributed largely to the lack of tumor-selective therapeutic modalities that effectively deliver lethal doses at the sites of metastatic disease. Tumor-selective drug delivery strategies that aim to improve uniformity in intratumoral drug microdistributions and to prolong exposure of these cancer cells to delivered therapeutics may improve therapeutic efficacy against established TNBC metastases. In this study, we present lipid carriers for selective (due to their nanometer size) tumor delivery, which are loaded with cisplatin and designed to exhibit the following properties when in the tumor interstitium: (1) interstitial drug release (for deeper tumor penetration of cisplatin) and/or (2) intratumoral/interstitial adhesion of the carriers to tumors' extracellular matrix (ECM)-not accompanied by cell internalization-for delayed tumor clearance of carriers prolonging cancer cell exposure to the cisplatin being released. We show that on large multicellular spheroids, used as surrogates of avascular solid tumor regions, greater growth inhibition was strongly correlated with spatially more uniform drug concentrations (due to interstitial drug release) and with longer exposure to the released drug (i.e., higher time-integrated drug concentrations enabled by slow clearing of adhesive nanoparticles). Lipid nanoparticles with both the release and adhesion properties were the most effective, followed by nanoparticles with only the releasing property and then by nanoparticles with only the adhering property. In vivo, cisplatin-loaded nanoparticles with releasing and/or adhering properties significantly inhibited the growth of spontaneous TNBC metastases compared to conventional liposomal cisplatin, and the efficacy of different property combinations followed the same trends as in spheroids. This study demonstrates the therapeutic potential of a general strategy to bypass treatment limitations of established TNBC metastases due to the lack of cell-targeting markers: aiming to optimize the temporal intratumoral drug microdistributions for more uniform and prolonged drug exposure.

Interstitial Release of Cisplatin from Triggerable Liposomes Enhances Efficacy against Triple Negative Breast Cancer Solid Tumor Analogues.

Liposomal cisplatin, a promising triple negative breast cancer treatment modality, has been shown to decrease toxicities associated with cisplatin's free agent form. However, the heterogeneous intratumoral distributions of the liposomes themselves, combined with limited release of cisplatin from them contribute to limited penetration of cisplatin within tumors reducing efficacy. This study uses pH-responsive liposomes designed to release cisplatin within the acidic tumor interstitium (7.0 > pH ≥ 6.0) with a dual aim (1) to improve the penetration of the free drug within tumors on the assumption of greater diffusivities based on the free drug's much smaller size than its carrier's size and (2) to increase the availability of the free agent near cancer cells deep into the tumor. On cell monolayers treated with pH-releasing liposomal cisplatin, acidification of the extracellular solution resulted in decreased LD50 values, which were significantly lower than the LD50 values for non-pH-releasing liposomal cisplatin. In multicellular spheroids with acidic interstitia, pH-releasing liposomal cisplatin significantly decreased spheroid volumes relative to non-pH-releasing liposomal cisplatin. Improved efficacy was correlated with increased spheroid penetration of a fluorescent cisplatin surrogate. These findings demonstrate that interstitial release of cisplatin by pH-responsive liposomes may improve the intratumoral distributions of the free drug enhancing efficacy.

Liposome-based approaches for delivery of mainstream chemotherapeutics: preparation methods, liposome designs, therapeutic efficacy.

We review liposome-based delivery approaches that aim to address toxicities and to improve the therapeutic efficacy of mainstream chemotherapeutics, namely, doxorubicin, paclitaxel, and cisplatin. A brief review of the biomolecular mechanism(s) of action of these agents is followed by a description of characteristic examples of therapeutic approaches and of liposome membrane designs. Short reports on clinical studies are also included when applicable. The technical issues of different loading/encapsulation methods of these agents into liposomes are also discussed in terms of the physicochemical properties of both the agents themselves and of the lipid-based self-assemblies.