Abstract
Preclinical studies demonstrating high cure rates with PD1/PD-L1 combinations have led to numerous clinical trials, but emerging results are disappointing. These combined immunotherapies are commonly employed for patients with refractory tumors following prior treatment with cytotoxic agents. Here, we uncovered that the post-chemotherapy tumor presents a unique mechanical microenvironment characterized by an altered extracellular matrix (ECM) elasticity and increased stiffness, which facilitate the development of aggressive tumor phenotypes and confer resistance to checkpoint blocking therapy. As thus, we rationally designed an in situ nanocomposite hydrogel system, LOS&FeOX@Gel, which enabled effective and specific delivery of the therapeutic payloads (losartan [LOS] and oxaliplatin [OX]) into tumor. We demonstrate that sustained release of LOS effectively remodels the tumor mechanical microenvironment (TMM) by reducing ECM deposition and its associated "solid stress", thereby augmenting the efficacy of OX and its immunological effects. Importantly, this hydrogel system greatly sensitized post-chemotherapy tumor to checkpoint blocking therapy, showing synergistic therapeutic effects against cancer metastasis. Our study provides mechanistic insights and preclinical rationale for modulating TMM as a potential neoadjuvant regimen for tumor to optimize the benefits of chemo-immunotherapy, which lays the groundwork for leveraging "mechanical-immunoengineering" strategies to combat refractory tumors.