Nanoparticles with In Vivo Anticancer Activity from Polymer Prodrug Amphiphiles Prepared by Living Radical Polymerization

Novel carbon quantum dots can serve as an excellent adjuvant for the gp85 protein vaccine against avian leukosis virus subgroup J in chickens

To evaluate whether carbon quantum dots (CQDs) can serve as an excellent adjuvant for the gp85 protein vaccine, this study produced recombinant gp85 protein against the avian leukosis virus subgroup J (ALV-J) in chickens. Functionalized CQDs were prepared and then linked to the recombinant gp85 protein. A total of 36 chickens were divided into 3 groups, namely, 2 experimental groups and 1 control group. Chickens from the experimental groups were inoculated twice intramuscularly with purified recombinant gp85 protein with CQDs as adjuvant or Freund's adjuvant emulsion at 14 and 21 D, whereas those from the control group were inoculated with an equivalent volume of PBS. At 35 D, the chickens were challenged with a 102.4 50% tissue culture infective dose of ALV-J. Blood samples were collected from each chicken at weekly intervals for serum antibody and viremia analyses. Results indicated that immunization with gp85-CQDs or gp85-Freund's adjuvant induced the inoculated chickens to produce positive serum antibodies (sample-to-positive ratio >0.6) at the 3rd week and persisted over 9 wk. Antibody levels in the gp85-CQDs group were higher than those in the gp85-Freund's adjuvant group. Differences were significant at 21 D (P < 0.05) and extremely significant from 28 D to 70 D (P < 0.01). Additionally, results of viremia showed higher protection in the gp85-CQDs group than in the Freund's adjuvant group. These findings highlighted the potential of CQDs as excellent candidate nanovehicles for vaccine delivery.

Structure-based rational design of prodrugs to enable their combination with polymeric nanoparticle delivery platforms for enhanced antitumor efficacy

Drug-loaded nanoparticles (NPs) are of particular interest for efficient cancer therapy due to their improved drug delivery and therapeutic index in various types of cancer. However, the encapsulation of many chemotherapeutics into delivery NPs is often hampered by their unfavorable physicochemical properties. Here, we employed a drug reform strategy to construct a small library of SN-38 (7-ethyl-10-hydroxycamptothecin)-derived prodrugs, in which the phenolate group was modified with a variety of hydrophobic moieties. This esterification fine-tuned the polarity of the SN-38 molecule and enhanced the lipophilicity of the formed prodrugs, thereby inducing their self-assembly into biodegradable poly(ethylene glycol)-block-poly(d,l-lactic acid) (PEG-PLA) nanoparticulate structures. Our strategy combining the rational engineering of prodrugs with the pre-eminent features of conventionally used polymeric materials should open new avenues for designing more potent drug delivery systems as a therapeutic modality.