Trimetallic-based nanocarriers method shows promise for visualized idiopathic pulmonary fibrosis therapy

A research group from Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences (CAS) developed a novel method for idiopathic pulmonary fibrosis (IPF) therapy by transplanting mesenchymal stem cells (MSCs), which improved the therapeutic efficacy and realized real-time treatment visualization. The study was published in Science Advances .

IPF is an interstitial lung disease with rapid progression and high mortality, and poses serious threats to human health. In addition to traditional treatment options like long-term oxygen therapy and lung transplantation, MSCs have emerged as a potential lung regeneration therapy for IPF due to their excellent safety and paracrine effects.

However, low survival rates and poor therapeutic efficacy of transplanted MSCs have limited the clinical application and advancement of MSC-based therapy for IPF.

Researchers at NIMTE, led by Prof. Wu Aiguo and Prof. Li Juan at the Laboratory of Advanced Theranostic Materials and Technology, developed AuPtCoPS trimetallic-based nanocarriers (TBNCs) with protamine sulfate (PS) as the raw material. The TBNCs exhibit remarkable enzyme-like activity, therapeutic gene loading capacity, and computed tomography (CT) imaging performance.

Based on these properties, the TBNCs can facilitate the delivery of therapeutic genes, effectively eliminate the reactive oxygen species (ROS) from fibrotic lungs, and secrete hepatocyte growth factor (HGF) at lesion sites.

This enhances the antioxidative stress and antifibrosis capabilities of MSCs and extends the in vivo survival of transplanted MSCs from seven to 14 days. The therapeutic effect of the engineered MSCs on IPF shows significant improvement.

Researchers also found that TBNCs can function as CT contrast agents for tracking MSCs during therapy, which enables the real-time monitoring of their in vivo biological behavior and the visualization of therapeutic efficacy in IPF treatment.

The study presents a promising perspective on engineered MSC-based therapy for IPF, and sheds light on the future large-scale production and application of high-performance MSCs in regenerative medicine.