From Passive Targeting to Personalized Nanomedicine: Multidimensional Insights on Nanoparticles' Interaction with the Tumor Microenvironment

Nanomedicine is revolutionizing the treatment of cancer and has achieved unprecedented outcomes over the past decades. The accumulation of Nanoparticles (NPs) in different tumors relies mainly on the Enhanced Permeability and Retention (EPR) effect benefiting from the wide fenestrae of the tumor vasculature and the lack of lymphatic drainage. However, the EPR effect is recognized as a heterogeneous phenomenon resulting in heterogeneous outcomes of clinical trials. Extensive efforts are exerted to enhance the outcomes of nanomedicine in a larger cohort of patients by employing active targeting strategies. However, actively targeted NPs accumulate in tumors by the EPR effect and hence fail to achieve convincing therapeutic outcomes. These obstacles are gradually being removed by improving the understanding of the Tumor Microenvironment (TME) and the mechanistic interaction of the NPs with its different components. In this review, we provide detailed insights into the past concerns of drug targeting, the current trends of TME reengineering, and the future implications for overcoming past hurdles. Strategies explored in this regard included the use of companion diagnostics and the modulation of the protein corona associated with the systemic administration of NPs and their interaction with biological macromolecules.

Collagenase loaded chitosan nanoparticles for digestion of the collagenous scar in liver fibrosis: The effect of chitosan intrinsic collagen binding on the success of targeting

A variety of hepatic insults result in the accumulation of collagen-rich new extracellular matrix in the liver, ultimately culminating in liver fibrosis and cirrhosis. For such reasons, approaches looking into digestion of the collagen-rich extracellular matrix present an interesting therapeutic approach for cases of chronic liver disease, where the fibrotic scar is well established. Portal collagenase administration has recently led to the successful reversion of cirrhosis in an experimental rabbit model. Notwithstanding, the question of how such a sensitive therapeutic macromolecule could be administered in a less invasive manner, and in a way that preserves its functionality and avoids digestion of other non-hepatic vital collagen presents itself. Chitosan is a biodegradable polymer that has been reported to interact and bind to collagen. Chitosan nanoparticles (CS NPs) have also been reported to encapsulate therapeutic proteins, maintaining their functional form and protecting them from in-vivo degradation. For such reasons, CS NPs were loaded with collagenase and evaluated in-vitro and in-vivo for their ability to target and digest collagen. CS NPs were able to encapsulate collagenase (≈ 60% encapsulation efficiency) and release its content in active form. To determine whether chitosan's collagen interaction would enable NP collagen binding or whether the modification with collagen binding peptides (CBPs) is necessary, CS NPs were modified with the CBP; CCQDSETRTFY. Since the density of targeting ligand and the length of tether play a significant role in the success of active targeting, the surface of NPs was modified with different densities of the CBP either directly or using a polyethylene glycol (PEG) spacer. PEGylated NPs showed higher levels of CBP tagging; high, intermediate and low density of CBPs corresponded to 585.8 ± 33, 252.9 ± 25.3 and 56.5 ± 8.8 µg/mL for PEGylated NPs and 425.56 ± 12.67, 107.91 ± 10.3 and 49.86 ± 3.2 µg/mL for unPEGylated NPs, respectively. In-vitro collagen binding experiments showed that unmodified CS NPs were able to bind collagen and that modification with CBPs either directly or via PEG did not enhance collagen binding. In-vivo experiments demonstrated that unmodified CS NPs were able to reverse fibrosis with a survival rate of 100% at the end of the study, indicating the ability of CS NPs to deliver functional collagenase to the fibrotic liver and making the use of CBPs unnecessary.