Shire adds New technology platform and phase 2 product candidate to its Regenerative Medicine business.
Dublin, Ireland – April 12, 2012 – Shire plc (LSE: SHP, NASDAQ: SHPGY), the global specialty biopharmaceutical company, today announced that it has signed an agreement to acquire substantially all the assets of Pervasis Therapeutics. Shire will provide Pervasis with an upfront payment, plus potential post-closing milestone payments that are dependent on Shire’s achievement of certain clinical development, regulatory and sales targets.
- Clinical stage development assets bring to Shire a new cell-based technology platform (endothelial cell technology) with potential global opportunity, and leverage many existing capabilities—specialized marketing approach, cell-based manufacturing, unique reimbursement, outpatient call point
- Establishes technology relationship with world-leading scientist Elazer Edelman, MD, PhD, professor of Health Sciences and Technology at MIT, professor of medicine at Harvard Medical School, and coronary care unit cardiologist at the Brigham and Women’s Hospital in Boston
- Acquisition complements the 2011 purchase of Advanced BioHealing, further demonstrating Shire’s commitment to investing in and building out its portfolio of regenerative medicine therapies as the partner of choice for development-stage companies
- Lead program (Vascugel®) addresses significant unmet medical need for acute vascular repair technologies focused on improving hemodialysis access for patients with end-stage renal disease (ESRD)
- Strong strategic fit with existing product, Dermagraft, which is indicated for diabetic foot ulcers. Diabetes is the global leading cause of ESRD, and accounts for approximately 40% of ESRD patients treated in the U.S.i Diabetic patients on dialysis have a greater risk of developing a diabetic foot ulcer than diabetics not receiving dialysis treatment
- Shire will initially focus on completing a Phase II program to address maturation and maintenance of arteriovenous (AV) access for hemodialysis patients, which will instruct future development pathway
Shire’s Regenerative Medicine President, Kevin Rakin says:
“There are currently no approved therapies that directly target the underlying physiological processes associated with the creation of AV access sites in hemodialysis patients, including inflammation, thrombosis, and restenosis. As a result, there remains a significant unmet need for technologies that improve hemodialysis access for patients with ESRD. We believe Vascugel has the potential to enhance the rate of blood vessel repair while also providing for increased maintenance of the access site for a prolonged period of time as compared to current treatments. This acquisition marks a very important step for Shire in building a Regenerative Medicine business focused on tissue repair and regeneration.”
“Shire’s vision of bringing new regenerative medicine therapies to patients with chronic diseases was a critical factor in our decision to proceed with this transaction,” said Frederic Chereau, President and Chief Executive Officer at Pervasis. “I am excited to be partnering with Shire, which has demonstrated both the capability and commitment to bringing this promising cell-based technology to the patients with end stage renal disease who need it.”
The closing of the acquisition is subject to ancillary conditions.
Vascugel is an endothelial cell-based therapy in development for enhancing blood vessel repair and improving hemodialysis access for patients with end-stage renal disease. Vascugel utilizes adult allogeneic endothelial cells embedded into a polymer matrix, and is placed on the outside of the blood vessel at the arteriovenous (AV) access site during the surgical intervention to create the access. Vascugel has received Orphan Product designation from the U.S. Food and Drug Administration and the European Medical Agency.
About Arteriovenous (AV) Access for Hemodialysis
End-stage renal disease (ESRD) is an advanced and irreversible kidney disease, treated mainly by hemodialysis or kidney transplantation. It is estimated that each year, there are more than 570,000 patients with ESRD treated in the U.S. and more than 250,000 patients in the EUi,iii. Approximately 70% of these patients receive hemodialysisi. Before patients can undergo hemodialysis, an arteriovenous (AV) access site must be created where blood can be removed, filtered and returned to the body. The majority of AV access is achieved through either an AV fistula, where the vein is connected directly to the artery, or an AV graft, where the vein and artery are connected via a tube. There are an estimated 100,000 AV fistulas and 60,000 AV grafts occurring annually in the U.S.iv,v Unfortunately, complications following AV access procedures are common and can include infection, blood clots, and narrowing of the vessel, which frequently lead to AV access failure. An estimated 60% of AV grafts fail after one year, requiring a procedure to restore flow or to create another AV access site.