Orally administrable anticancer nanomedicines are highly desirable due to their easy and repeatable administration, but are not yet feasible because the current nanomedicine cannot simultaneously overcome the strong mucus and villi barriers and thus have very low bioavailability (BA). Herein, this work presents the first polymeric micelle capable of fast mucus permeation and villi absorption and delivering paclitaxel (PTX) efficiently to tumors with therapeutic efficacy even better than intravenously administered polyethylene glycol based counterpart or free PTX. Poly[2‐(N‐oxide‐N,N‐diethylamino)ethyl methacrylate] (OPDEA), a water‐soluble polyzwitterion, is highly nonfouling to proteins and other biomacromolecules such as mucin but can weakly bind to phospholipids. Therefore, the micelle of its block copolymer with poly(ε‐caprolactone) (OPDEA‐PCL) can efficiently permeate through the viscous mucus and bind to villi, which triggers transcytosis‐mediated transepithelial transport into blood circulation for tumor accumulation. The orally administered micelles deliver PTX to tumors, efficiently inhibiting the growth of HepG2 and patient‐derived hepatocellular carcinoma xenografts and triple‐negative breast tumors. These results demonstrate that OPDEA‐based micelles may serve as an efficient oral nanomedicine for delivering other small molecules or even large molecules.
Janus nanoparticles with an anisotropic feature concentrated
multiple
properties on a single carrier, providing synergistic effects. In
this study, dual-functionalized Janus nanoparticles (HA-JMSN/DOX-DMMA)
were constructed with a tumor-targeting ligand (hyaluronic acid, HA)
modified on the one side and a charge reversal group (2,3-dimethylmaleic
anhydride, DMMA) on the other side. The drug release of HA-JMSN/DOX-DMMA
was positively correlated with the acidity of the environment. The
cytotoxicity and cell uptake of HA-JMSN/DOX-DMMA were superior to
the isotropous nanoparticles. The endocytosis pathway of HA-JMSN/DOX-DMMA
involved the clathrin-mediated endocytosis (HA) and the micropinocytosis
(DMMA) at the same time, which indicated that they both participated
in the interaction between nanoparticles and tumor cells. After being
injected intravenously in mice, the distribution of HA-JMSN/DOX-DMMA
in tumor was enhanced significantly. The antitumor therapy study in
vivo showed that HA-JMSN/DOX-DMMA inhibited tumor growth and improved
the survival rate of tumor-bearing mice effectively. In general, HA-JMSN/DOX-DMMA
could take the synergistic effect of active targeting and charge reversal
to deliver drug in tumor cells and kill them efficiently, which was
a promising antitumor nanodrug.
Cancer cell membranes (CCMs) are widely used as sources of tumor-associated antigens (TAAs) for the development of cancer vaccines. To improve the CCM-associated cancer vaccine efficiency, personalized cancer vaccines and effective delivery systems are required. In this study, we employed surgically harvested cancer tissues to prepare personalized CCMs for use as TAAs. Thioglycolic-acid-grafted poly(2-methyl-2-oxazoline)-block-poly(2-butyl-2-oxazoline-co-2-butenyl-2-oxazoline) (PMBEOx-COOH) was synthesized to load imiquimod (R837) efficiently. The personalized CCMs were then coated onto R837loaded PMBEOx-COOH nanoparticles (POxTA NPs/R837) to obtain surgically derived CCM-coated POxTA NPs (SCNPs/ R837). SCNPs/R837 efficiently travelled to the draining lymph nodes and were taken up and presented by plasmacytoid dendritic cells to elicit enhanced antitumor immune responses. When combined with programmed cell death-1 antibodies, SCNPs/R837 exhibited high efficiency corresponding to antitumor progression. Therefore, SCNP/R837 might represent a promising personalized cancer vaccine with significant potential for cancer immunotherapy.
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