 |
|
Nanowire coating for bone implants, stents
August 28, 2007University of Arkansas researchers have found a simple, inexpensive way to create a nanowire coating on the surface of biocompatible titanium that can be used to create more effective surfaces for hip replacement, dental reconstruction and vascular stenting. Further, the material can easily be sterilized using ultraviolet light and water or using ethanol, making it useful in hospital settings and meat-processing plants
Wenjun Dong, Tierui Zhang, Lisa Cooney, Hong Wang, Yanbin Li, Andrew Cogbill, Vijay Varadan and Z. Ryan Tian of the University of Arkansas, Ying-Bing Jiang of the University of New Mexico, and Joshua Epstein of the University of Arkansas for Medical Sciences report their findings in an upcoming issue of the journal Chemistry of Materials.
The researchers used an alkali and heat to create titanium oxide-based ceramic nanowires that coat the surface of a titanium medical device.
"We can control the length, the height, the pore openings and the pore volumes within the nanowire scaffolds" by varying the time, temperature and alkali concentration in the reaction, said Z. Ryan Tian, assistant professor of chemistry and biochemistry in the J. William Fulbright College of Arts and Sciences. "This process is also extremely sustainable," requiring only that the device be rinsed in reusable water after the heating process.
Reconstructive bone surgeries, such as hip replacements, use titanium implants. However, muscle tissue may not adhere well to titanium's smooth surface, causing the implant to fail after a decade or so and requiring the patient to undergo a second surgery.
Tian and his colleagues created a nanowire-coated joint and placed it in mice. After four weeks, the researchers found that tissue had adhered to the joint.
"We saw beautiful tissue growth - lots of muscle fibers," Tian said. "We've added one more function to the currently-in-use titanium implant."
Because the researchers can control the size and shape of the pores in the nanowire scaffold, the material also could be coated onto stents used in patients with coronary artery disease and in potential stroke victims. Conventional stents sometimes become reclogged with fat after implantation. The most recent stent used to address this problem, called the drug-eluting stent, consists of a polymer coating mixed with the drugs, but the coating may be vulnerable to biodegradation, and may not function for long. The nanowire coating without the degradation problem could be used to carry drugs that would help keep the arteries clear over a long period of time.
"This drug release could be applied to the angioplasty catheter's surface," Tian said.
In addition to these biomedical applications, the nanofiber scaffold has a property that may make it useful in both hospitals and food processing plants: The material, when rinsed in water and exposed to ultraviolet light, kills more than 99 percent of bacteria on its surface. This effect occurs because photons from the light cause a charge separation on the material, splitting water molecules into free radicals that destroy the bacteria. Alternatively, immersion in 70 percent ethanol completely sterilizes the material, allowing growth of cells/tissues in the laboratory prior to implantation.
This property could prove extremely useful in bacteria-prone environments, performing such functions as sterilizing on-site surgery hospitals used during military actions or cleaning surfaces in meat-processing plants.
"You could just use water to rinse and UV light to sterilize surfaces," Tian said.
The researchers have applied for a provisional patent for the multifunctional nanowire bioscaffolds on titanium or titanium-containing alloys such as Nitinol.
American Chemical Society
"We can control the length, the height, the pore openings and the pore volumes within the nanowire scaffolds" by varying the time, temperature and alkali concentration in the reaction, said Z. Ryan Tian, assistant professor of chemistry and biochemistry in the J. William Fulbright College of Arts and Sciences. "This process is also extremely sustainable," requiring only that the device be rinsed in reusable water after the heating process.
Reconstructive bone surgeries, such as hip replacements, use titanium implants. However, muscle tissue may not adhere well to titanium's smooth surface, causing the implant to fail after a decade or so and requiring the patient to undergo a second surgery.
Tian and his colleagues created a nanowire-coated joint and placed it in mice. After four weeks, the researchers found that tissue had adhered to the joint.
"We saw beautiful tissue growth - lots of muscle fibers," Tian said. "We've added one more function to the currently-in-use titanium implant."
Because the researchers can control the size and shape of the pores in the nanowire scaffold, the material also could be coated onto stents used in patients with coronary artery disease and in potential stroke victims. Conventional stents sometimes become reclogged with fat after implantation. The most recent stent used to address this problem, called the drug-eluting stent, consists of a polymer coating mixed with the drugs, but the coating may be vulnerable to biodegradation, and may not function for long. The nanowire coating without the degradation problem could be used to carry drugs that would help keep the arteries clear over a long period of time.
"This drug release could be applied to the angioplasty catheter's surface," Tian said.
In addition to these biomedical applications, the nanofiber scaffold has a property that may make it useful in both hospitals and food processing plants: The material, when rinsed in water and exposed to ultraviolet light, kills more than 99 percent of bacteria on its surface. This effect occurs because photons from the light cause a charge separation on the material, splitting water molecules into free radicals that destroy the bacteria. Alternatively, immersion in 70 percent ethanol completely sterilizes the material, allowing growth of cells/tissues in the laboratory prior to implantation.
This property could prove extremely useful in bacteria-prone environments, performing such functions as sterilizing on-site surgery hospitals used during military actions or cleaning surfaces in meat-processing plants.
"You could just use water to rinse and UV light to sterilize surfaces," Tian said.
The researchers have applied for a provisional patent for the multifunctional nanowire bioscaffolds on titanium or titanium-containing alloys such as Nitinol.
American Chemical Society
Building better bone replacements with bacteria
Bacteria that manufacture hydroxyapatite (HA) could be used to make stronger, more durable bone implants. Professor Lynne Macaskie from the University of Birmingham this week (7-10 September) presented work to the Society for General Microbiology's meeting at Heriot-Watt University, Edinburgh.
High tech implants to aid facial reconstruction to be developed at Loughborough University
Loughborough University researchers have been awarded more than £200,000 to develop state-of-the-art tailor made implants for people requiring facial reconstructive surgery.
New bone bonding spheres aim to reduce implant replacement
Researchers at Oxford University’s Department of Materials have devised a new method of coating materials that are to be implanted into bone, resulting in encouraged bone in-growth and bonding while reducing the possibility of loosening implants.
More Bone Implants Current Events and Bone Implants News Articles
 |
Bone Biology, Harvesting, & Grafting For Dental Implants: Rationale and Clinical Applications by Arun K. Garg (Author) Many patients who are otherwise ideal candidates for implant therapy lack sufficient alveolar bone to support dental implants. This book presents all facets of bone augmentation in preparation for implant placement, including techniques for harvesting bone from the ramus, the anterior mandible, and the tibia; the various types of bone-grafting materials and their indications; step-by-step procedures for grafting the maxillary sinus and anterior alveolar ridge and for subnasal elevation and augmentation; and guidelines for the use of adjuncts such as platelet-rich plasma to enhance healing and predictability. Practitioners of implant dentistry at all levels will learn much from this book. |
 |
The He In The She Also With: FOX (Producer) |
 |
Like New: Dental Implants If you are missing one or more teeth and would like to smile, speak and eat again with comfort and confidence, Dr. Girod has good news: dental implants that look and feel like your own teeth. You do not have to worry about wobbly dentures and messy pastes and glues. Since dental implants integrate into the structure of your bone, they prevent the bone loss and gum recession that often accompany bridgework and dentures. No one will ever know that you have a replacement tooth. With new developments in dental implant surgery you can now get your new teeth within a day. |
 |
Implant Dentistry and Extraction Site Bone Grafting by Tischler Dental Seminars This 4 1/2 hour live instructional DVD covers many topics that will offer the general dentist and overview of Dental Implants and Extraction site bone grafting. Simplifying Fixed Implant Dental Prosthetics Justification of Dental Implant Treatment Treatment Planning Implant Dentistry Radiographs and CT Imaging Principles For Implant Dentistry Provisional Considerations for Implant Dentistry Dental Implants In The Esthetic Zone Clinical Application and Rationale Of Extraction Site Grafting Treatment Planning Extraction Grafts Bone Physiology / Cellular Sequence of Grafting Choosing The Appropriate Graft Material The Keys To Bone Grafting |
 |
20 Years of Guided Bone Regeneration in Implant Denistry by Daniel Buser (Author), Daniel Buser (Editor) This completely revised and updated edition of the bestselling book Guided Bone Regeneration in Implant Dentistry brings the reader up-to-date on the developments in GBR over the past 20 years. The first four chapters focus on the basic science of GBR in implant dentistry. These chapters help the reader to understand the biologic and biomaterial background of this well-documented and well-established surgical technique in implant dentistry essential knowledge for the use of barrier membranes in patients. The second half of the book focuses on the clinical applications of GBR. Each chapter presents specific indications and describes the criteria for patient selection, the step-by-step surgical procedure, and aspects of postoperative treatment. These five clinical chapters reflect the... |
 |
Mechanical Testing of Bone and the Bone-Implant Interface by Yuehuei H. An (Editor), Robert A. Draughn (Editor) The mechanical properties of whole bones, bone tissue, and the bone-implant interfaces are as important as their morphological and structural aspects. Mechanical Testing of Bone and the Bone-Implant Interface helps you assess these properties by explaining how to do mechanical testing of bone and the bone-implant interface for bone-related research. Articles explore the basic mechanical principles of bone-related study and how to conduct mechanical testing of bone specimens. More practical than theoretical, the text includes 42 chapters in three sections that cover mechanical properties of bone, general considerations of mechanical testing, basic facilities and instruments for mechanical testing; mechanical testing procedures on bone tissues; and mechanical testing procedures on the... |
 |
Lexi-Comp's Manual of Dental Implants (Lexi-Comp's Dental Reference Library) by David Sarment (Author), Beth Peshman (Author) Univ. of Michigan, Dearborn. Text is designed to initiate dental students, dentists, dental hygienists to the principles and practices of implant restorative dentistry and maintenance. Provides treatment plans, techniques, and protocols. Features more than 220 color illustrations. Thumb-indexed. Wire-spiral binding. |
 |
Bone Grafting Techniques for Maxillary Implants by Karl-Erik Kahnberg (Author) This book explores the potential of bone grafting techniques to rehabilitate the maxilla through the placement of dental implants. As implant dentistry becomes increasingly well established and sophisticated, this book will help experienced surgeons to involve implant solutions as part of more challenging reconstructions in the upper jaw. Starting with a recap on principles of bone biology, the book then considers implant integration in normal bone and with bone grafts. Grafting procedures are presented depicting a variety of bone harvest sites, followed by onlay and inlay grafting techniques. Approaches to sinus lifting, segmental osteotomy and distraction osteogenesis for augmentation protocols are provided. |
|
Guided Bone Regeneration in Implant Dentistry by Christer Dahlin (Author), Daniel Buser (Author), Christer Dahlin (Editor), Daniel Buser (Editor), Robert K. Schenk (Editor) University of Berne, Switzerland. Reference for dental clinicians on the guided bone regeneration technique (also called the membrane technique) in dental implants. Primarily color photographs. 16 contributors, 9 U.S. DNLM: Guided Tissue Regeneration. | |
 |
Micromechanics & Fiber-Reinforced Composites in Biomedical Research: Advanced Bone Implant and Reconstruction Device Materials, Free Radicals in Composites, ... Medicine, and Engineering Structural Biology by Richard Petersen (Author) Micromechanics presented in this Book are based on recent landmark published manuscripts with the first proof validation for the Rule of Mixtures and final accurate theoretical solutions for fiber lengths with strength and modulus. Fracture Toughness is presented for a bulk materials analyses requested by the U.S. National Academy of Sciences almost 30 years ago by accurate Strain-Energy Methods through Numerical Integration whereby the area under any data set can be easily calculated by computer spreadsheet technology. Fiber-Reinforced Composites are emphasized with leading-edge Biomedical Research presented for state-of-the-art Implant technology. Comprehensive, multidisciplinary topics range from accurate Fracture Mechanics with KIC analysis to Animal Testing, complete Free-Radical... |
| © 2009 BrightSurf.com |