Transport-driven engineering of liposomes for delivery of α-particle radiotherapy to solid tumors: effect on inhibition of tumor progression and onset delay of spontaneous metastases.

PURPOSE: Highly cytotoxic α-particle radiotherapy delivered by tumor-selective nanocarriers is evaluated on metastatic Triple Negative Breast Cancer (TNBC). On vascularized tumors, the limited penetration of nanocarriers (<50-80 µm) combined with the short range of α-particles (40-100 µm) may, however, result in only partial tumor irradiation, compromising efficacy. Utilizing the α-particle emitter Actinium-225 (225Ac), we studied how the therapeutic potential of a general delivery strategy using nanometer-sized engineered liposomes was affected by two key transport-driven properties: (1) the release from liposomes, when in the tumor interstitium, of the highly diffusing 225Ac-DOTA that improves the uniformity of tumor irradiation by α-particles and (2) the adhesion of liposomes on the tumors' ECM that increases liposomes' time-integrated concentrations within tumors and, therefore, the tumor-delivered radioactivities. METHODS: On an orthotopic MDA-MB-231 TNBC murine model forming spontaneous metastases, we evaluated the maximum tolerated dose (MTD), biodistributions, and control of tumor growth and/or spreading after administration of 225Ac-DOTA-encapsulating liposomes, with different combinations of the two transport-driven properties. RESULTS: At 83% of MTD, 225Ac-DOTA-encapsulating liposomes with both properties (1) eliminated formation of spontaneous metastases and (2) best inhibited the progression of orthotopic xenografts, compared to liposomes lacking one or both properties. These findings were primarily affected by the extent of uniformity of the intratumoral microdistributions of 225Ac followed by the overall tumor uptake of radioactivity. At the MTD, long-term toxicities were not detected 9.5 months post administration. CONCLUSION: Our findings demonstrate the potential of a general, transport-driven strategy enabling more uniform and prolonged solid tumor irradiation by α-particles without cell-specific targeting.

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.

Two diverse carriers are better than one: A case study in α-particle therapy for prostate specific membrane antigen-expressing prostate cancers.

Partial and/or heterogeneous irradiation of established (i.e., large, vascularized) tumors by α-particles that exhibit only a 4-5 cell-diameter range in tissue, limits the therapeutic effect, since regions not being hit by the high energy α-particles are likely not to be killed. This study aims to mechanistically understand a delivery strategy to uniformly distribute α-particles within established solid tumors by simultaneously delivering the same α-particle emitter by two diverse carriers, each killing a different region of the tumor: (1) the cancer-agnostic, but also tumor-responsive, liposomes engineered to best irradiate tumor regions far from the vasculature, and (2) a separately administered, antibody, targeting any cancer-cell's surface marker, to best irradiate the tumor perivascular regions. We demonstrate that on a prostate specific membrane antigen (PSMA)-expressing prostate cancer xenograft mouse model, for the same total injected radioactivity of the α-particle emitter Actinium-225, any radioactivity split ratio between the two carriers resulted in better tumor growth inhibition compared to the tumor inhibition when the total radioactivity was delivered by any of the two carriers alone. This finding was due to more uniform tumor irradiation for the same total injected radioactivity. The killing efficacy was improved even though the tumor-absorbed dose delivered by the combined carriers was lower than the tumor-absorbed dose delivered by the antibody alone. Studies on spheroids with different receptor-expression, used as surrogates of the tumors' avascular regions, demonstrated that our delivery strategy is valid even for as low as 1+ (ImmunoHistoChemistry score) PSMA-levels. The findings presented herein may hold clinical promise for those established tumors not being effectively eradicated by current α-particle radiotherapies.

Combination of Carriers with Complementary Intratumoral Microdistributions of Delivered α-Particles May Realize the Promise for 225Ac in Large, Solid Tumors.

α-particle radiotherapy has already been shown to be impervious to most resistance mechanisms. However, in established (i.e., large, vascularized) soft-tissue lesions, the diffusion-limited penetration depths of radiolabeled antibodies or nanocarriers (≤50-80 µm) combined with the short range of α-particles (4-5 cell diameters) may result in only partial tumor irradiation, potentially limiting treatment efficacy. To address this challenge, we combined carriers with complementary intratumoral microdistributions of the delivered α-particles. We used the α-particle generator 225Ac, and we combined a tumor-responsive liposome (which, on tumor uptake, releases into the interstitium a highly diffusing form of its radioactive payload [225Ac-DOTA], potentially penetrating the deeper parts of tumors where antibodies do not reach) with a separately administered, less-penetrating radiolabeled antibody (irradiating the tumor perivascular regions where liposome contents clear too quickly). Methods: In a murine model with orthotopic human epidermal growth factor receptor 2-positive BT474 breast cancer xenografts, the biodistributions of each carrier were evaluated, and the control of tumor growth was monitored after administration of the same total radioactivity of 225Ac delivered by the 225Ac-DOTA-encapsulating liposomes, by the 225Ac-DOTA-SCN--labeled trastuzumab, and by both carriers at equally split radioactivities. Results: Tumor growth was significantly more inhibited when the same total injected radioactivity was divided between the 2 separate carriers than when delivered by either of the carriers alone. The combined carriers enabled more uniform intratumoral microdistributions of α-particles, at a tumor dose that was lower than the dose delivered by the antibody alone. Conclusion: This strategy demonstrates that more uniform microdistributions of the delivered α-particles within established solid tumors improve efficacy even at lower tumor doses. Augmentation of antibody-targeted α-particle therapies with tumor-responsive liposomes may address partial tumor irradiation, improving therapeutic effects.

Daptomycin-Induced Lipid Phases on Model Lipid Bilayers: Effect of Lipid Type and of Lipid Leaflet Order on Membrane Permeability.

Daptomycin's bacterial membrane activity is partly due to the defects of lipid-packing at the boundaries of daptomycin-induced, separated lipid phases, which are rich in phosphatidylglycerol (PG). On model membranes, the permeability of phase boundaries is strongly dependent on the extent of saturation of the lipid acyl tails, which affect the lipids' ability to pack within these boundaries, and on the cross-leaflet registration of these boundaries. Using vesicles with asymmetric lipid leaflet compositions, we evaluated the role of headgroup type and/or extent of acyl-tail saturation on daptomycin-induced membrane permeability. We demonstrate that the release rates of vesicle-encapsulated contents scales with the total length of daptomycin-induced, PG-rich phase boundaries. On the outer leaflet, lipids with PG-headgroups (in contact with daptomycin) were a necessary condition, but they still were not adequate for release. Increased membrane permeability was observed only when inner leaflet lipids had saturated acyl tails; we postulate that the latter may have enabled the recruitment, by the outer leaflet daptomycin-induced phases, of inner leaflet lipids in cross-registered phases with boundaries of defective packing that spanned the bilayer. These findings provide insights on the potential role of lipids as a whole (headgroup and acyl tails) and of lipid leaflet order on the boundaries of daptomycin-induced separated lipid phases in model membranes.