In contrast to traditional strategies based on external driving forces, an internal path for intratumoral delivery is explored by degrading the tumor microenvironment component hyaluronan. Natural hyaluronidase PH20 and constructed long-acting PH20-Fc have been used to achieve this objective. It has been then evaluated how these agents facilitate the diffusion of the following typical therapeutic agents varying in nanoscales: doxorubicin (≈1.5 × 1.0 × 0.7 nm) chemotherapy, trastuzumab (10-15 nm) biotherapy, and gold nanorod (≈100 × 35 nm) thermotherapy. In traditional 2D cultures, PH20 and PH20-Fc have little influence on cytotoxicity due to lack of a tumor microenvironment. However, the cytotoxicities of the three therapeutic agents in 3D tumor spheroids are all enhanced by PH20 or PH20-Fc because hyaluronan degradation facilitates therapeutic penetration and accumulation. Furthermore, in vivo evaluations reveal that the significantly prolonged circulation time of PH20-Fc leads to accumulation in the tumor and subsequent hyaluronan degradation. Consequently, PH20-Fc coadministration further inhibits tumor growth. The performance of PH20-Fc varies for the three therapeutic agents due to their different nanoscales. Trastuzumab benefits most from combination with PH20-Fc. The results provide here novel insights that can aid in the development of more effective hyaluronidase-based therapeutic systems.
Keywords: doxorubicin; gold nanorods; novel drug delivery systems; trastuzumab; tumor microenvironment and modification.
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