Abstract
Liposome-based drug delivery systems have allowed for better drug tolerability and longer circulation times but are often optimized for a single agent due to the inherent difficulty of co-encapsulating two drugs with differing chemical profiles. Here, we design and test a prodrug based on a ribosylated nucleoside form of 5-fluorouracil, 5-fluorouridine (5FUR), with the final purpose of co-encapsulation with doxorubicin (DOX) in liposomes. To improve the loading of 5FUR, we developed two 5FUR prodrugs that involved the conjugation of either one or three moieties of tryptophan (W) known respectively as, 5FUR−W and 5FUR−W3. 5FUR−W demonstrated greater chemical stability than 5FUR−W3 and allowed for improved loading with fewer possible byproducts from tryptophan hydrolysis. Varied drug ratios of 5FUR−W: DOX were encapsulated for in vivo testing in the highly aggressive 4T1 murine breast cancer model. A liposomal molar ratio of 2.5 5FUR−W: DOX achieved a 62.6% reduction in tumor size compared to the untreated control group and a 33% reduction compared to clinical doxorubicin liposomes in a proof-of-concept study to demonstrate the viability of the co-encapsulated liposomes. We believe that the new prodrug 5FUR−W demonstrates a prodrug design with clinical translatability by reducing the number of byproducts produced by the hydrolysis of tryptophan, while also allowing for loading flexibility.
Highlights
Innovation in nanomedicine has resulted in the successful development of many novel oncology therapies in the clinic [1,2]
Chemotherapeutics remain the front-line treatment for many cancers [6,7,8], and while cancer treatment has evolved with the introduction of several experimental and improved immunotherapies, chemotherapy continues to remain one of the main pillars of cancer therapy
We have previously reported a polyethylene glycol-containing (PEGylated) liposomal formulation comprised of 5-fluorouridine (5FUR) and doxorubicin (DOX) for breast cancer therapy, a formulation referred to as DAFODIL
Summary
Innovation in nanomedicine has resulted in the successful development of many novel oncology therapies in the clinic [1,2]. Advancements in the formulation of new nanomedicines have coincided with the identification of new therapeutic targets [3], a new understanding of the immunogenic effects of nanocarriers [4], and advancements in the delivery of biologics [5]. Chemotherapeutics remain the front-line treatment for many cancers [6,7,8], and while cancer treatment has evolved with the introduction of several experimental and improved immunotherapies, chemotherapy continues to remain one of the main pillars of cancer therapy. To mitigate the toxic effects of large doses, nanoparticlebased delivery systems for chemotherapeutics were developed to protect the drug cargo
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