Inhalable Lactoferrin/Chondroitin-Functionalized Monoolein Nanocomposites for Localized Lung Cancer Targeting.

Localized drug delivery to lung cancer can overcome the limitations of systemic nanocarriers including low drug amounts reaching lung tissues and severe off-target toxicity. The current work presented novel inhalable nanocomposites as noninvasive platforms for lung cancer therapy. Nanoparticulate liquid crystals (LCNPs) based on monoolein were developed for synergistic co-encapsulation of the cytotoxic chemotherapeutic drug, pemetrexed, and the phytoherbal drug, resveratrol (PEM-RES-LCNPs). For active tumor targeting, lactoferrin (LF) and chondroitin sulfate (CS), natural polymers with intrinsic tumor-targeting capabilities, were exploited to functionalize the surface of LCNPs using a layer-by-layer (LbL) self-assembly approach. To maximize their deep lung deposition, LF/CS-coated PEM-RES-LCNPs were then microencapsulated within various carriers to obtain inhalable nanocomposites via spray-drying techniques. The inhalable dry powder nanocomposites prepared using a mannitol-inulin-leucine (1:1:1 wt) mixture displayed superior in vitro aerosolization performance (2.72 µm of MMAD and 61.6% FPF), which ensured deep lung deposition. In lung cancer-bearing mice using urethane as a chemical carcinogen, the inhalable LF/CS-coated PEM-RES-LCNP nanocomposites showed superior antitumor activity as revealed by a considerable decrease of the average lung weight, reduced number and diameter of cancerous lung foci, decreased expression of VEGF-1, and increased expression of active caspase-3 as well as reduced Ki-67 expression compared to the spray-dried free PEM/RES powder mixture and positive control. Moreover, the in vivo fluorescence imaging confirmed successful lung deposition of the inhalable nanocomposites. Conclusively, the inhalable liquid crystalline nanocomposites elaborated in the current work could open new avenues for noninvasive lung cancer treatment.

Inhalable lactoferrin-chondroitin nanocomposites for combined delivery of doxorubicin and ellagic acid to lung carcinoma.

AIM: The use of inhalable nanomedicines can overcome the Enhanced permeation and retention effect (EPR)-associated drawbacks in lung cancer therapy via systemic nanomedicines. METHODS: We developed a lactoferrin-chondroitin sulfate nanocomplex for the co-delivery of doxorubicin and ellagic acid nanocrystals to lung cancer cells. Then, the nanocomplex was converted into inhalable nanocomposites via spray drying. RESULTS: The resulting 192.3 nm nanocomplex exhibited a sequential faster release of ellagic acid, followed by doxorubicin. Furthermore, the nanocomplex demonstrated superior cytotoxicity and internalization into A549 lung cancer cells mediated via Tf and CD44 receptors. The inhalable nanocomposites exhibited deep lung deposition (89.58% fine particle fraction [FPF]) with powerful antitumor efficacy in lung cancer bearing mice. CONCLUSION: Overall, inhalable lactoferrin-chondroitin sulfate nanocomposites would be a promising carrier for targeted drug delivery to lung cancer.

Targeting sialic acid residues on lung cancer cells by inhalable boronic acid-decorated albumin nanocomposites for combined chemo/herbal therapy.

Etoposide (ETP), as a potential treatment for lung cancer, has limited application due to its poor solubility, and systemic side effects. In the current study, we propose inhalable boronate-targeted HSA nanocomposites for combined delivery of ETP and the herbal drug, berberine (BER) for localized therapy of lung cancer. First, ETP was pre-formulated as phospholipid complex (EPC) to enhance drug solubility and facilitate its encapsulation within the hydrophilic albumin nanoparticles (NPs). Second, EPC and BER were then co-loaded with high efficiency into HSA NPs as a synergistic therapy for lung cancer. The NPs displayed suitable size around 200 nm and sequential drug release pattern. Moreover, conjugation of aminophenylboronic acid (APBA) to HSA NPs resulted in enhanced cytotoxicity and internalization into A549 lung cancer cells, compared to non-targeted NPs or free drugs via binding to sialic acid residues over-expressed by cancer cells. Using mannitol as a spray-drying carrier, the developed inhalable nanocomposites demonstrated deep pulmonary deposition, confirmed by small MMAD (2.112 µm) and high FPF (77.86%). In vivo investigations in lung cancer animal models revealed the superior anti-tumor efficacy of the inhalable nanocomposites. Overall, the inhalable APBA-HSA nanocomposites offered an alternative strategy for systemic delivery of ETP and BER in lung cancer therapy.

Inhalable multi-compartmental phospholipid enveloped lipid core nanocomposites for localized mTOR inhibitor/herbal combined therapy of lung carcinoma.

Pulmonary delivery of drug nanocarriers can overcome the shortcomings of systemic cancer therapy via the enhanced permeability and retention (EPR) based-nanomedicine. Herein, inhalable multi-compartmental nanocomposites with the capability for both localized and modulated release of the hydrophobic mTOR inhibitor, rapamycin (RAP) and the hydrophilic herbal drug, berberine (BER) have been developed for lung cancer therapy. Two types of multi-compartmental nanocarriers were fabricated by enveloping BER hydrophobic ion pair-lipid nanocore within a shell of RAP-phospholipid complex bilayer to reduce the delivery gap between the two drugs. To further enhance their tumor targeting, the nanocarriers were layer-by-layer coated by cationic lactoferrin and anionic hyaluronate resulting in enhanced internalization and cytotoxicity against lung cancer cells. The inhalable nanocomposites fabricated by spray-drying of multi-compartmental nanocarriers exhibited favorable aerosolization efficiency (MMAD of 3.28 µm and FPF of 55.5%). The powerful anti-cancer efficacy of inhalable nanocomposites in lung cancer bearing mice compared to the inhaled free drugs was revealed by remarkable decrease in lung weight, and reduction in both number and diameters of lung adenomatous foci and angiogenic markers compared to positive control. Overall, localized delivery of RAP and BER to tumor cells via inhalable multi-compartmental nanocomposites holds great promise in management of lung cancer.