Pancreatic cancer, recognized as one of the deadliest cancers, poses a persistent challenge for medical professionals globally due to its aggressive behavior and resistance to conventional therapies. The dense fibrotic tissue surrounding pancreatic tumors acts as a significant barrier, hindering the delivery of macromolecular drugs such as antibodies and nanomedicines. Therefore, addressing fibrosis is crucial in enhancing therapeutic outcomes for patients with pancreatic cancer, whose prognosis remains bleak.
Understanding the underlying mechanisms driving fibrosis is essential in advancing treatment strategies for this devastating illness. The conventional models used for studying pancreatic ductal adenocarcinoma (PDAC) fibrotic environment often fail to accurately mimic the complexity of the disease. Seeking a more clinically relevant approach, a team of researchers led by Professor Mitsunobu R. Kano from Okayama University, Japan in collaboration with The University of Tokyo and Tohoku University developed a realistic human pancreatic cancer fibrotic barrier model using patient-derived pancreatic stellate cells (PSCs). Their research, co-authored by Prof. Hiroyoshi Y. Tanaka from Okayama University, Prof. Horacio Cabral from The University of Tokyo, and Prof. Atsushi Masamune from Tohoku University, was made available online on 29 March 2024 and was formally published in the May 2024 issue of the Journal of Controlled Release.
This innovative model offers a convenient, rapid, and highly reproducible experimental platform to assess pathogenetic mechanisms driving fibrosis as well as to test the efficacy of potential therapeutic interventions. Understanding the molecular mechanisms driving extracellular matrix (ECM) remodeling in PDAC fibrosis is crucial for overcoming treatment barriers. By dissecting these signaling pathways, researchers aimed to determine points of intervention that could be manipulated to enhance tissue permeability and develop more effective treatments for pancreatic cancer.
"We used advanced cell culture techniques along with molecular and pharmacological interventions to examine the signaling pathways involved in PDAC fibrosis," explained Professor Kano. "Initially, we assessed the impact of blocking the transforming growth factor-β (TGFβ) and Rho-associated kinase (ROCK) pathways on ECM remodeling and tissue permeability within our 3D fibrotic tissue model. Additionally, we also investigated the involvement of YAP (Yes-associated protein), a key regulator of cell differentiation, in mediating the effects of ROCK inhibition on ECM remodeling and tissue permeability."
The results shed light on promising avenues for enhancing drug delivery in PDAC by targeting specific signaling pathways involved in fibrosis. "Inhibition of the TGFβ pathway led to a reduction in ECM remodeling and improved tissue permeability of drugs in 3D-PDAC fibrotic model. Similarly, blocking the ROCK pathway, particularly through ROCK2 inhibition, resulted in decreased ECM remodeling and enhanced drug permeability. Knockdown experiments revealed the predominant role of ROCK2 in regulating these processes," shares Prof. Kano. "Additionally, targeting the YAP protein, a downstream effector of ROCK signaling, produced similar improvements in ECM remodeling and drug permeability." These findings highlight the potential of targeting the TGFβ/ROCK2/YAP signaling axis to mitigate fibrotic barriers and enhance drug delivery in pancreatic cancer, offering promising prospects for improving treatment outcomes in this challenging disease.
Looking ahead, the implications of the study extend beyond pancreatic cancer alone. "Fibrosis is prevalent not only in pancreatic cancer but also in other cancers that are difficult to treat, such as those affecting the stomach, breast, and lung, as well as in some non-cancerous diseases. With effective medical treatments lacking for fibrotic conditions, our findings offer a glimmer of hope for enhancing treatment strategies and outcomes in a broader spectrum of fibrotic cancers as well as non-cancerous fibrotic conditions," concludes Prof. Kano.
About Okayama University, Japan
As one of the leading universities in Japan, Okayama University aims to create and establish a new paradigm for the sustainable development of the world. Okayama University offers a wide range of academic fields, which become the basis of the integrated graduate schools. This not only allows us to conduct the most advanced and up-to-date research, but also provides an enriching educational experience.
Website: https://www.okayama-u.ac.jp/index_e.html
About Professor Mitsunobu R. Kano from Okayama University, Japan
Mitsunobu R. Kano, MD, PhD, is a distinguished Professor of the Department of Pharmaceutical Biomedicine at Okayama University. Graduating from the University of Tokyo medical school, he brings over 20 years of experience and an impressive record of 70+ published articles cited 8500+ times to his esteemed position. His research primarily focuses on the integration of medicine and nanotechnology to combat drug-resistant cancers. Additionally, he has authored books on scientific thinking for the general public. Prof. Kano is also recognized for his pivotal role as the founder of the Young Academy of Japan and as various governmental roles including the first Science and Technology Co-Advisor to the Minister of Foreign Affairs of Japan.
