Microtissues® Inc. and Sigma-Aldrich® Sign Worldwide Supply and Distribution Agreement for the 3D Petri Dish®

Microtissues® Inc. announced today the signing of a Supply and Distribution Agreement with Sigma-Aldrich® Corporation (Nasdaq: SIAL) for the worldwide sales and marketing of the 3D Petri Dish®, a new technology for the culture of living cells in three dimensions (3D). Invented at Brown University, the 3D Petri Dish® maximizes cell-to-cell interactions critical for replicating the function of natural tissues and organs. Shown in numerous peer reviewed papers to work with over fifty different cell types, including cell lines, primary cells and stem cells, the 3D Petri Dish® has applications in cancer research, drug discovery, toxicity testing and regenerative medicine.

“Researchers are rapidly recognizing the importance of 3D cell culture and its ability to reliably mimic in vivo function” said Brian Morgan, Director of Business Development, Microtissues® Inc. “The 3D Petri Dish® creates a natural 3D environment without artificial scaffolds and we’re excited that this distribution agreement will bring our unique and innovative line of products to the worldwide research community.”

Unlike the conventional plastic Petri dish where cells are grown as a thin layer on the surface of the dish, the 3D Petri Dish® forms 3D aggregates of cells. Spheroid size is controlled by the number of cells seeded and hundreds of uniform sized spheroids are formed in a single pipetting step. Spheroids are formed in a well ordered array in a stable platform suitable for long term culture. All spheroids are positioned on the same optical plane making them easy to image (phase contrast, fluorescent). Spheroid size is controlled by the number of cells seeded and a mixture of cells forms mixed spheroids, suitable for investigating tumor-stroma interactions. Spheroids can be grown from single cells, applicable to the study of cancer stem cells. For histology, Western blots and RT-PCR, spheroids are harvested by simply inverting the 3D Petri Dish®. No need to dissolve or digest the gel. The 3D Petri Dish® is a new fundamental tool for the world wide industry of life sciences research.

About Sigma-Aldrich®: Sigma-Aldrich® is a leading Life Science and High Technology company whose biochemical, organic chemical products, kits and services are used in scientific research, including genomic and proteomic research, biotechnology, pharmaceutical development, the diagnosis of disease and as key components in pharmaceutical, diagnostics and high technology manufacturing. Sigma-Aldrich® customers include more than 1.3 million scientists and technologists in life science companies, university and government institutions, hospitals and industry. The Company operates in 38 countries and has nearly 9,000 employees whose objective is to provide excellent service worldwide. Sigma-Aldrich® is committed to accelerating customer success through innovation and leadership in Life Science and High Technology. For more information about Sigma-Aldrich®, please visit its website at www.sigma-aldrich.com.

About Microtissues® Inc: Microtissues® Inc. is a privately held company located in Providence, RI, advancing technologies and applications of 3D cell culture. Microtissues®, Inc.’s products are designed to serve the needs of researchers in a wide range of areas including cancer research, stem cell biology, toxicity testing, developmental biology, drug discovery, regenerative medicine and tissue engineering. Microtissues®, Inc. has an exclusive worldwide license from Brown University to US and international patent applications on the 3D Petri Dish®. For more information on Microtissues®, Inc., please visit www.microtissues.com.

Sigma-Aldrich and Sigma are trademarks of Sigma-Aldrich Co. LLC registered in the US and other countries. Microtissues and 3D Petri Dish are registered trademarks of Microtissues, Inc.

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Is it a Moment or an Abuse: the Boom of iPSCs Research after 2012 Medicine Nobel Prize

On Creative Biomart website, we can read a report about the 2012 Nobel Prize in Physiology or Medicine regarding the two winners. They bring hope for organ or tissue repair for human or even for rejuvenation, i.e. for long life through induced pluripotent stem cells (iPSCs).

Since the first appearance in 2006, iPSCs became the hit and focus. But there are still lots of unknowns waiting for us before achieving the ideal status. Thus, numerous scientists, researchers and businessmen are struggling and investing for that goal. Here are some examples:

On Dec. 5, 2012, Roche (SIX: RO, ROG; OTCQX: RHHBY) and the Innovative Medicines Initiative (IMI) announced today the launch of StemBANCC, a new academic–industry partnership that unites ten pharmaceutical companies and 23 academic institutions. Initiated and coordinated by Roche and managed by Oxford University, StemBANCC aims to use human induced pluripotent stem cells as research tools for drug discovery with the goal of using this ground-breaking new technology to develop human disease models and enhance drug development.

On Oct. 29, 2012, on the PANS Journal there is an article about Cartilage tissue engineering using differentiated and purified induced pluripotent stem cells.

On Oct. 4, 2012, on Cell Stem Cell, there is a report with the title be Genome Sequencing of Mouse Induced Pluripotent Stem Cells Reveals Retroelement Stability and Infrequent DNA Rearrangement during Reprogramming.

On Jan. 30, 2012, on the PANS Journal, there is a report about modeling hepatitis C virus infection using human induced pluripotent stem cells, which make the individual and tailor therapy further.

Above are only a small part of such studies. People still wonder does it is the moment or an abuse on the iPSCs research. When someone reviewed one of the winners, Shinya Yamanaka, about his opinion on the challenge of iPSCs research, he said, “I have two research directions, the first is to establish human iPSCs bank that comply with clinical application standards. The second is to study the cell mechanism of iPSCs regenerating. And I think the current threat is still to be the safety problem as good research respects both scientific and ethical standards.”

But no one deny the great potential of iPSCs.

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