Okayama University Research: 3D Tissue Model Offers Insights Into Treating Pancreatic Cancer

OKAYAMA, Japan, January 31, 2019 /PRNewswire/ --

Researchers at Okayama University show how specific cells of the pancreas can facilitate cancer progression   

Pancreatic cancer can be fatal. It is extremely difficult to treat partly because its precise growth mechanism is not clear. One of the characteristics of pancreatic cancer is the presence of fibrous structures or 'desmoplasia' that are found in conjunction with the tumour. Scientists at Okayama University have recently clarified the structure and the mechanisms underlying the emergence of desmoplasia in pancreatic cancer.

     (Photo: https://mma.prnewswire.com/media/816116/PSC_Tissue_Samples.jpg )

To understand desmoplasia better it must be replicated in the laboratory. Here, the researchers first analysed desmoplasia from human samples of pancreatic cancer. Microscopy revealed that cancer cells were separated from surrounding blood vessels by fibrous desmoplasia cells. The desmoplasia layer was about 10 to 30 micrometers thick, suggesting that if a therapeutic agent were to reach cancer cells from the blood it would have to traverse this distance-a key factor determining the efficiency of drug delivery.

Next, the researchers extracted pancreatic stellate cells (PSCs) from patients to create a 3D model of desmoplasia because desmoplasia is formed of these cells. Arranging PSCs in increasing numbers quickly resulted in layers at least 10 micrometers thick, accurately mimicking the desmoplasia in pancreatic cancer. The normal function of PSCs is to secrete the extracellular matrix (ECM), which is a support system that holds cells together. The composition and organization of ECM is severely altered in the desmoplasia. This led the researchers to use their 3D model to understand how ECM changes occur and the role of PSCs with respect to these changes.

The model showed the abundance of two ECM components, Fibronectin and Collagen, just as seen in patient desmoplasia. Notably, these components also act as barriers preventing drugs from reaching cancer cells. The trigger that drives the switch between normal ECM and the aberrant ECM in desmoplasia was a major pathway mediated by a pair of proteins TGF-β/ROCK. Activation of this pathway could not only switch healthy fibrous cells into the toxic PSCs, but also result in increases of Collagen and Fibronectin. Lastly, another cancer protein, SPARC, was also found to be involved with these ECM abnormalities, further establishing its relevance to pancreatic cancer.

This was the first study to replicate a 3D model of desmoplasia in the laboratory, with relevance to clinical samples. This model successfully revealed toxic pathways that are activated in pancreatic cancer. Such a model has wide ranging implications such as deeper insights into structural and molecular aberrations that drive the disease with the possibility of discovering how to overcome the desmoplastic barrier to facilitate drug delivery to tumour cells.

This work has been carried out by a collaborative research with scientists in Tohoku University, Keio University, Osaka University, Hirosaki University, Japan Women's University, and Toyo University.

Background 

Extracellular matrix (ECM): The ECM is a scaffold made up of different biochemical components. This scaffolding network that is secreted by specific kinds of cells, functions to hold and bind cells in place and facilitate communication between them. It thus acts as an external system keeping cells healthy, strong and functioning correctly. Alterations in the ECM can lead to cellular dysfunction, such as in cancer.

Reference 

Hiroyoshi Y. Tanaka, Kentaro Kitahara, Naoki Sasaki, Natsumi Nakao, Kae Sato, Hirokazu Narita, Hiroshi Shimoda, Michiya Matsusaki, Hiroshi Nishihara, Atsushi Masamune, Mitsunobu R. Kano. Pancreatic stellate cells derived from human pancreatic cancer demonstrate aberrant SPARC-dependent ECM remodeling in 3D engineered fibrotic tissue of clinically relevant thickness. Biomaterials, 2019 Feb;192:355-367.

DOI: 10.1016/j.biomaterials.2018.11.023.

https://www.sciencedirect.com/science/article/pii/S0142961218308007?via%3Dihub

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About Okayama University 

Okayama University is one of the largest comprehensive universities in Japan with

roots going back to the Medical Training Place sponsored by the Lord of Okayama and

established in 1870. Now with 1,300 faculty and 13,000 students, the University offers

courses in specialties ranging from medicine and pharmacy to humanities and physical

sciences. Okayama University is located in the heart of Japan approximately 3 hours west of

Tokyo by Shinkansen.

Website: http://www.okayama-u.ac.jp/index_e.html

Correspondence to
Professor Mitsunobu Kano, M.D., Ph.D.
Department of Pharmaceutical Biomedicine,
Okayama University Graduate School of Interdisciplinary Science and
Engineering in Health Systems, 1-1-1 Tsushima-naka, Kita-Ku,
Okayama, 700-8530, Japan.
E-mail: mitkano@okayama-u.ac.jp

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