RxPG News Feed for RxPG News

Medical Research Health Special Topics World
  Home
 
   Health
 Aging
 Asian Health
 Events
 Fitness
 Food & Nutrition
 Happiness
 Men's Health
 Mental Health
 Occupational Health
 Parenting
 Public Health
 Sleep Hygiene
 Women's Health
 
   Healthcare
 Africa
 Australia
 Canada Healthcare
 China Healthcare
 India Healthcare
 New Zealand
 South Africa
 UK
 USA
 World Healthcare
 
   Latest Research
 Aging
 Alternative Medicine
 Anaethesia
 Biochemistry
 Biotechnology
 Cancer
 Cardiology
 Clinical Trials
 Cytology
 Dental
 Dermatology
 Embryology
 Endocrinology
 ENT
 Environment
 Epidemiology
 Gastroenterology
 Genetics
 Gynaecology
 Haematology
 Immunology
 Infectious Diseases
 Medicine
 Metabolism
 Microbiology
 Musculoskeletal
 Nephrology
 Neurosciences
 Obstetrics
 Ophthalmology
 Orthopedics
 Paediatrics
 Pathology
 Pharmacology
 Physiology
 Physiotherapy
 Psychiatry
 Radiology
 Rheumatology
 Sports Medicine
 Surgery
  CTVS
  Plastic Surgery
  Transplantation
 Toxicology
 Urology
 
   Medical News
 Awards & Prizes
 Epidemics
 Launch
 Opinion
 Professionals
 
   Special Topics
 Ethics
 Euthanasia
 Evolution
 Feature
 Odd Medical News
 Climate

Last Updated: Oct 11, 2012 - 10:22:56 PM
CTVS Channel

subscribe to CTVS newsletter
Latest Research : Surgery : CTVS

   EMAIL   |   PRINT
A novel collapsible heart valve can revolutionize the present invasive open heart surgery in children

Feb 14, 2006 - 5:35:00 PM , Reviewed by: Rashmi Yadav
“Using catheters and collapsible valves, heart valves can be replaced without stopping the heart, without cutting the chest open and without long recovery times."

 
[RxPG]
A novel collapsible heart valve can revolutionize the present invasive open heart surgery in children
Levi and Carman holding thin film nitinol in different forms
Children with congenital heart defects may soon have an alternative to invasive open heart surgery that will mean less time in the hospital, a quicker recovery and no need to break open the breastbone, thanks to a new collaboration between researchers at the UCLA Henry Samueli School of Engineering and Applied Science and pediatric cardiologists at Mattel Children’s Hospital at UCLA.

Using a super-elastic, shape-memory metal alloy called “thin film nitinol,” UCLA engineers are developing a collapsible heart valve for children that can be loaded into a catheter, inserted into a vein in the groin area, guided into place and then deployed in a precise location within the heart. As the valve is released from the catheter, it springs back to its original shape and begins to function.

“What is really novel about the valve UCLA Engineering has created is the memory retaining alloy and butterfly design that opens or hinges from the middle of the valve rather than the edges,” said UCLA mechanical and aerospace engineering professor Gregory Carman, who, along with UCLA researcher Lenka Stepan, crafted the valve. “The unobtrusive leaflets within the valve mean there is no obstruction to blood flow. This smaller, low-profile design is well suited for children and, over time, will potentially allow children born with heart valve defects to experience less pain and live much fuller lives.”

Dr. Daniel Levi, assistant professor of pediatric cardiology at Mattel Children’s Hospital at UCLA, designed the valve and joined Carman and Stepan to create and develop the revolutionary new device.

“Using catheters and collapsible valves, heart valves can be replaced without stopping the heart, without cutting the chest open and without long recovery times,” Levi said. “This will represent a huge improvement in care for children living with a very difficult condition.”

A defective heart valve fails to fully open or close, letting blood leak back into the heart chamber. This condition most often is treated surgically, and the valve is replaced with a human donor valve, a porcine valve or a mechanical one. All heart valve replacements have a limited life span and must be replaced eventually, but for children, there are even greater complications: the valves do not grow as children grow, which could mean as many as three or more open-heart surgeries during childhood and adolescence alone.

Open-heart surgery typically requires three to four days in intensive care, at least one or two weeks in the hospital and a lengthy recovery period at home. In contrast, patients who have valves replaced via catheter could go home as early as the following day, with little pain.

While catheter-based valve replacement procedures already are revolutionizing valve replacement for larger patients, smaller children have not yet benefited from this technology. Although many companies are competing to develop the ideal transcatheter heart valve, most of these valves are bulky and can be used only in adults. Thin film nitinol could allow doctors at UCLA to make a transcatheter heart valve suitable for use even in small children.

“By collaborating with UCLA Engineering, we are creating a pediatric heart valve that has great strength and biocompatibility. It could mean a shortened procedure, a lower level of risk, and much less stress on the patient and their family. It also will mean a lower cost to the health care system,” Levi said. “Our valve is presently being designed for replacement of the pulmonary valve, but eventually may also be able to be used for the aortic valve.”

The UCLA team also has used thin film nitinol successfully in other biomedical applications such as stents — short narrow metal mesh tubes inserted into an artery or bile duct to keep blocked passageways open — as well as in other applications.

“Although the medical community has used bulk nitinol for the past decade in stents and other implantable biomedical devices, thin film nitinol has yet to be incorporated into a commercially available biomedical device,” Carman said.

“Recent studies we’ve conducted have shown that thin film nitinol can be used to cover stents and to provide a barrier in preventing regrowth of tissue into stented arteries and veins. Beyond its use in either percutaneously or surgically placed valves, I anticipate that thin film nitinol will have a wide variety of applications in the development of future implantable biomedical devices for both adults and children,”Levi added.

In order to bring their new valves and stents for children to market, UCLA’s Mattel Children’s Hospital and researchers at UCLA Engineering are seeking to collaborate with industry, but both Levi and Carman say it will still be a number of years before the valves will be commercially available.

To date, the research done by Carman and Levi has been supported by a grant from the National Institute of Child Health and Human Development, part of the National Institutes of Health. Thin film nitinol originally was developed for defense applications with support from both the Air Force Office of Scientific Research and the Defense Advanced Research Projects Agency.




Publication: UCLA Henry Samueli School of Engineering and Applied Science and pediatric cardiologists at Mattel Children’s Hospital at UCLA.
On the web: http://www.engineer.ucla.edu/ 

Advertise in this space for $10 per month. Contact us today.


Related CTVS News
Clopidogrel does not increase postoperative bleeding risk in patients with Acute Coronary Syndrome
AAAs are best operated at large centres - study suggests
'Off-pump' CABG appears to have no benefit on cognitive or cardiac outcomes at 5 years
Minimally invasive approach and a revolutionary device to treat thoracic aortic aneurysm
Cox-maze IV: New simpler technique for persistent Atrial Fibrillation
Nesiritide may be beneficial in the prevention of renal dysfunction after CABG
Aprotinin use during CABG associated with increased mortality rates
Mayo Clinic surgeons propose a system of quality indicators for lung surgery
Off-pump CABG is a safer option
Off-pump CABG is a safer option

Subscribe to CTVS Newsletter

Enter your email address:


 Feedback
For any corrections of factual information, to contact the editors or to send any medical news or health news press releases, use feedback form

Top of Page

 
Contact us

RxPG Online

Nerve

 

    Full Text RSS

© All rights reserved by RxPG Medical Solutions Private Limited (India)