Decellularized extracellular matrix-based disease models for drug screening.

In vitro drug screening endeavors to replicate cellular states closely resembling those encountered in vivo, thereby maximizing the fidelity of drug effects and responses within the body. Decellularized extracellular matrix (dECM)-based materials offer a more authentic milieu for crafting disease models, faithfully emulating the extracellular components and structural complexities encountered by cells in vivo. This review discusses recent advancements in leveraging dECM-based materials as biomaterials for crafting cell models tailored for drug screening. Initially, we delineate the biological functionalities of diverse ECM components, shedding light on their potential influences on disease model construction. Further, we elucidate the decellularization techniques and methodologies for fabricating cell models utilizing dECM substrates. Then, the article delves into the research strides made in employing dECM-based models for drug screening across a spectrum of ailments, including tumors, as well as heart, liver, lung, and bone diseases. Finally, the review summarizes the bottlenecks, hurdles, and promising research trajectories associated with the dECM materials for drug screening, alongside their prospective applications in personalized medicine. Together, by encapsulating the contemporary research landscape surrounding dECM materials in cell model construction and drug screening, this review underscores the vast potential of dECM materials in drug assessment and personalized therapy.

Enhanced Tumor Site Accumulation and Therapeutic Efficacy of Extracellular Matrix-Drug Conjugates Targeting Tumor Cells.

The extracellular matrix (ECM) engages in regulatory interactions with cell surface receptors through its constituent proteins and polysaccharides. Therefore, nano-sized extracellular matrix conjugated with doxorubicin (DOX) is utilized to produce extracellular matrix-drug conjugates (ECM-DOX) tailored for targeted delivery to cancer cells. The ECM-DOX nanoparticles exhibit rod-like morphology, boasting a commendable drug loading capacity of 4.58%, coupled with acid-sensitive drug release characteristics. Notably, ECM-DOX nanoparticles enhance the uptake by tumor cells and possess the ability to penetrate endothelial cells and infiltrate tumor multicellular spheroids. Mechanistic insights reveal that the internalization of ECM-DOX nanoparticle is facilitated through clathrin-mediated endocytosis and macropinocytosis, intricately involving hyaluronic acid receptors and integrins. Pharmacokinetic assessments unveil a prolonged blood half-life of ECM-DOX nanoparticles at 3.65 h, a substantial improvement over the 1.09 h observed for free DOX. A sustained accumulation effect of ECM-DOX nanoparticles at tumor sites, with drug levels in tumor tissues surpassing those of free DOX by several-fold. The profound therapeutic impact of ECM-DOX nanoparticles is evident in their notable inhibition of tumor growth, extension of median survival time in animals, and significant reduction in DOX-induced cardiotoxicity. The ECM platform emerges as a promising carrier for avant-garde nanomedicines in the realm of cancer treatment.

Constructing Tumor Organoid-like Tissue for Reliable Drug Screening Using Liver-Decellularized Extracellular Matrix Scaffolds.

The interplay between cells and their microenvironments plays a pivotal role in in vitro drug screening. Creating an environment that faithfully mimics the conditions of tumor cells within organ tissues is essential for enhancing the relevance of drug screening to real-world clinical scenarios. In our research, we utilized chemical decellularization techniques to engineer liver-decellularized extracellular matrix (L-dECM) scaffolds. These scaffolds were subsequently recellularized with HepG2 cells to establish a tumor organoid-like tissue model. Compared to the conventional tissue culture plate (TCP) culture, the tumor organoid-like tissue model demonstrated a remarkable enhancement in HepG2 cell growth, leading to increased levels of albumin secretion and urea synthesis. Additionally, our results revealed that, within a 3-day time frame, the cytotoxicity of doxorubicin (DOX) against cells cultured in the tumor organoid-like tissue model was notably reduced when compared to cells grown on TCPs. In contrast, there was no significant difference in the cytotoxicity of two compounds, triptolide and honokiol, both derived from traditional Chinese medicine, between TCP culture and the tumor organoid-like tissue culture, indicating a lack of substantial drug resistance. Western blotting assays further confirmed our findings by revealing elevated expressions of E-cadherin and vimentin proteins, which are closely associated with the epithelial-mesenchymal transition (EMT). These results underscored that the tumor organoid-like tissue model effectively promoted the EMT process in HepG2 cells. Moreover, we identified that triptolide and honokiol possess the capacity to reverse the EMT process in HepG2 cells, whereas DOX did not exhibit a significant effect. In light of these findings, the tumor organoid-like tissue model stands as a valuable predictive platform for screening antitumor agents and investigating the dynamics of the EMT process in tumor cells.