 |
|
Breakthrough: UNC scientists have created world's tiniest uniform, precisely shaped organic particles
June 22, 2005CHAPEL HILL - University of North Carolina at Chapel Hill chemists have developed what they believe is a breakthrough method of creating the world's tiniest manufactured particles for delivering drugs and other organic materials into the human body.
Adapting technology pioneered by the electronics industry in fabricating transistors, the team has figured out for the first time how to create particles for carrying genetic material, pharmaceuticals and other compounds of unprecedented small size and uniformity. The tiny bits are so small they can be designed and constructed to measure only a hundred nanometers or so in diameter. A nanometer is a billionth of a meter.
Leading the group is Dr. Joseph M. DeSimone, William R. Kenan Jr. Distinguished professor of chemistry and chemical engineering at UNC and N.C. State University. A member of the UNC College of Arts and Sciences and the National Academy of Engineering, DeSimone also directs the National Science Foundation Science and Technology Center for Environmentally Responsible Solvents and Processes and the Institute for Advanced Materials, Nanoscience and Technology at UNC.
"Billions of dollars are being spent now on nanotechnology and nanoparticles, but 99 percent of the materials people are focusing on are metals and metal oxides, which are inorganic," DeSimone said. "Our method, which is really exciting, for the first time opens the world's door to marrying organic materials to nanotechnology. Biology, after all, is almost exclusively organic materials.
"We really believe this work will have a profound positive impact down the road on human health care. This includes, but is not limited to, chemotherapy, gene therapy, disease detection and drug delivery."
A report on the findings appeared online this morning (June 21) in the Journal of the American Chemical Society. Other authors - all in chemistry at UNC - are Drs. Jason P. Rolland and Ginger M. Denison, recent Ph.D. recipients; Drs. Benjamin W. Maynor and Larkin E. Euliss, postdoctoral fellows; and graduate student Ansley E. Exner.
Until now, DeSimone said, most current techniques for particle formation were incompatible with organic materials. That was because they involved baking, etching or processing robust metals and such with solvents that would have destroyed far more fragile organic matter such as genes or drugs.
The new method avoids harsh treatment but also allows formation of uniform particles in any shape designers choose - spheres, rods, cones, trapezoidal solids, etc. - and essentially any composition, he said. The relatively simple process, which he and colleagues are calling Particle Replication in Nonwetting Templates, or PRINT, also avoids creating films or "scum layers" that would clump particles together rather than allowing them to be harvested independent of one another.
"This is in contrast to traditional imprint lithography with silicon, glass or quartz molds where it is difficult to eliminate this residual material between objects," DeSimone said.
Particles injected into the body can be designed to be biodegradable, he said. Some are made from the same material used to make surgical sutures. They will incorporate as "cargo" whatever biological material designers want to get into patients' bloodstreams for more efficient uptake by cells for diagnostic testing or therapy.
Studies with various organic compounds have been very successful, the chemist said. New studies with mice have recently begun at the UNC School of Medicine, which DeSimone joined as professor of pharmacology.
"The process starts off when we make a master template in a clean room at places like the Triangle National Lithography Center at N.C. State University," DeSimone said. "From that we make impressions with what we call liquid Teflon, and the resulting molds look something like ice cube trays with tiny cavities in them. After that, we mold the carrier and fragile functional materials into whatever particles we want and gently wash them off the molds with buffer solutions into vials or other containers to concentrate them. Then they can be injected."
DeSimone, his colleagues, UNC and others have formed a new company, Liquidia Technologies Inc., with $2.5 million in angel funding and venture capital to further develop and commercialize the unique new technology. It is the second company for which DeSimone has been largely responsible.
The first was MiCell Technologies, which developed his research showing that it was possible to use carbon dioxide as a solvent in place of organic solvents, which polluted the environment.
"We are most excited about the commercial implications of Professor DeSimone's breakthrough with PRINT," said Dr. Lowry Caudill, chairman of Liquidia. "We believe that the PRINT process is an extremely versatile method that offers unparalleled uniformity and precision for making organic nanoparticles that will have profound implications in medicine and many other industries, including display technologies.
"Prior to this, no one else has fused the highly uniform and precise methods for fabricating transistors with the organic nanoparticle world," said Bruce Boucher, president of Liquidia. "It is truly a revolutionary discovery."
Support for the research came from the Office of Naval Research, the National Science Foundation and the William R. Kenan Jr. Distinguished Professorship.
University of North Carolina at Chapel Hill
"Billions of dollars are being spent now on nanotechnology and nanoparticles, but 99 percent of the materials people are focusing on are metals and metal oxides, which are inorganic," DeSimone said. "Our method, which is really exciting, for the first time opens the world's door to marrying organic materials to nanotechnology. Biology, after all, is almost exclusively organic materials.
"We really believe this work will have a profound positive impact down the road on human health care. This includes, but is not limited to, chemotherapy, gene therapy, disease detection and drug delivery."
A report on the findings appeared online this morning (June 21) in the Journal of the American Chemical Society. Other authors - all in chemistry at UNC - are Drs. Jason P. Rolland and Ginger M. Denison, recent Ph.D. recipients; Drs. Benjamin W. Maynor and Larkin E. Euliss, postdoctoral fellows; and graduate student Ansley E. Exner.
Until now, DeSimone said, most current techniques for particle formation were incompatible with organic materials. That was because they involved baking, etching or processing robust metals and such with solvents that would have destroyed far more fragile organic matter such as genes or drugs.
The new method avoids harsh treatment but also allows formation of uniform particles in any shape designers choose - spheres, rods, cones, trapezoidal solids, etc. - and essentially any composition, he said. The relatively simple process, which he and colleagues are calling Particle Replication in Nonwetting Templates, or PRINT, also avoids creating films or "scum layers" that would clump particles together rather than allowing them to be harvested independent of one another.
"This is in contrast to traditional imprint lithography with silicon, glass or quartz molds where it is difficult to eliminate this residual material between objects," DeSimone said.
Particles injected into the body can be designed to be biodegradable, he said. Some are made from the same material used to make surgical sutures. They will incorporate as "cargo" whatever biological material designers want to get into patients' bloodstreams for more efficient uptake by cells for diagnostic testing or therapy.
Studies with various organic compounds have been very successful, the chemist said. New studies with mice have recently begun at the UNC School of Medicine, which DeSimone joined as professor of pharmacology.
"The process starts off when we make a master template in a clean room at places like the Triangle National Lithography Center at N.C. State University," DeSimone said. "From that we make impressions with what we call liquid Teflon, and the resulting molds look something like ice cube trays with tiny cavities in them. After that, we mold the carrier and fragile functional materials into whatever particles we want and gently wash them off the molds with buffer solutions into vials or other containers to concentrate them. Then they can be injected."
DeSimone, his colleagues, UNC and others have formed a new company, Liquidia Technologies Inc., with $2.5 million in angel funding and venture capital to further develop and commercialize the unique new technology. It is the second company for which DeSimone has been largely responsible.
The first was MiCell Technologies, which developed his research showing that it was possible to use carbon dioxide as a solvent in place of organic solvents, which polluted the environment.
"We are most excited about the commercial implications of Professor DeSimone's breakthrough with PRINT," said Dr. Lowry Caudill, chairman of Liquidia. "We believe that the PRINT process is an extremely versatile method that offers unparalleled uniformity and precision for making organic nanoparticles that will have profound implications in medicine and many other industries, including display technologies.
"Prior to this, no one else has fused the highly uniform and precise methods for fabricating transistors with the organic nanoparticle world," said Bruce Boucher, president of Liquidia. "It is truly a revolutionary discovery."
Support for the research came from the Office of Naval Research, the National Science Foundation and the William R. Kenan Jr. Distinguished Professorship.
University of North Carolina at Chapel Hill
Drug Delivery Current Events and Drug Delivery News RSSNontoxic nanoparticle can deliver and track drugs
A nontoxic nanoparticle developed by Penn State researchers is proving to be an all-around effective delivery system for both therapeutic drugs and the fluorescent dyes that can track their delivery.
Conference report highlights new research into drug delivery to treat eye disease
Researchers are investigating microneedles, nanoparticles and polymer carriers as potential new techniques to combat the leading cause of visual impairment and blindness in the United States, according to a report from the Third Annual ARVO/Pfizer Ophthalmics Research Institute Conference.
Cancer drugs my build and not tear down blood vessels
Scientists have thought that one way to foil a tumor from generating blood vessels to feed its growth - a process called angiogenesis - was by creating drugs aimed at stopping a key vessel growth-promoting protein. But now the opposite seems to be true.
Iowa State researcher develops new treatment method for canine eye diseases
An Iowa State University researcher is exploring a new method of getting medicine to the eyes of infected dogs that is more effective and reliable than using eye drops.
Silencing a protein could kill T-Cells, reverse leukemia
Blocking the signals from a protein that activates cells in the immune system could help kill cells that cause a rare form of blood cancer, according to physicists and oncologists who combined computer modeling and molecular biology in their discovery.
Self-assembling nano-fiber gel delivers high concentrations of clinically approved drugs
Two teams of scientists from Harvard-MIT Division of Health Science and Technology (HST) at Brigham and Women's Hospital have developed a new self-assembling hydrogel drug delivery system that is biocompatible, efficient at drug release, and easy to tailor.
Nanodiamond drug device could transform cancer treatment
A Northwestern University research team has developed a promising nanomaterial-based biomedical device that could be used to deliver chemotherapy drugs locally to sites where cancerous tumors have been surgically removed.
Simulations help explain fast water transport in nanotubes
By discovering the physical mechanism behind the rapid transport of water in carbon nanotubes, scientists at the University of Illinois have moved a step closer to ultra-efficient, next-generation nanofluidic devices for drug delivery, water purification and nano-manufacturing.
Normalizing tumor vessels to improve cancer therapy
Chemotherapy drugs often never reach the tumors they're intended to treat, and radiation therapy is not always effective, because the blood vessels feeding the tumors are abnormal-"leaky and twisty" in the words of the late Judah Folkman, MD, founder of the Vascular Biology program at Children's Hospital Boston.
Biodegradable polymers show promise for improving treatment of acute inflammatory diseases
A family of biodegradable polymers called polyketals and their derivatives may improve treatment for such inflammatory illnesses as acute lung injury, acute liver failure and inflammatory bowel disease by delivering drugs, proteins and snips of ribonucleic acid to disease locations in the body.
More Drug Delivery Current Events and Drug Delivery News Articles
 | Ansel's Pharmaceutical Dosage Forms and Drug Delivery Systems by Loyd V Allen, Nicholas G Popovich, Howard C Ansel Long established as a core text for pharmaceutics courses, this book is the most comprehensive source on pharmaceutical dosage forms and drug delivery systems. Each chapter in this revised Eighth Edition includes two case studies—one clinical and one pharmaceutical. Content coincides with the CAPE, APhA, and NAPLEX competencies. This edition includes updated drug information and expanded... |
 | Electrochemotherapy, Electrogenetherapy, and Transdermal Drug Delivery: Electrically Mediated Delivery of Molecules to Cells (Methods in Molecular Medicine) (Methods in Molecular Medicine) Leading experts comprehensively review all aspects of the delivery of therapeutic molecules to cells using electrical impulses-i.e., the extraordinarily promising new areas of electrogenetherapy, electrochemotherapy, and transdermal drug delivery. Their survey ranges from outlines of the basic physical principles that govern cell permeabilization by pulsed electric fields, to descriptions of the... |
 | Spinal Drug Delivery This book provides a unified and comprehensive compendium of issues related to the spinal delivery of drugs. The text, consisting of 34 chapters, begins with an extensive review of the early history, reflecting the development of the spinal cord as a route of spinal drug delivery. It then presents 4 principal divisions. In the first, the embryology, anatomy of the spinal canal, the spinal canal... |
 | Biopharmaceutics of Ocular Drug Delivery (Handbooks in Pharmacology and Toxicology) by Peter Edman A significant new book on drug delivery to the eyeBiopharmaceutics of Ocular Drug Delivery examines the current physiological, anatomical, pharmaceutical/technological, and biopharmaceutical knowledge on ocular drug delivery. Leading ophthalmic researchers cover topics such as the formulation and usage of ophthalmic solutions and suspensions, the influence of surfactants and preservatives on... |
 | Drug Delivery: Engineering Principles for Drug Therapy (Topics in Chemical Engineering) by W. Mark Saltzman Synthetic materials are a tremendous potential resource for treating human disease. For the rational design of many of these biomaterials it is necessary to have an understanding of polymer chemistry and polymer physics. Equally important to those two fields is a quantitative understanding of the principles that govern rates of drug transport, reaction, and disappearance in physiological and... |
 | Polymers in Drug Delivery In recent years there has been an explosion in the use of polymers to solve various biomedical problems. Polymers play a crucial role in controlling drug release rate, enhancing drug solubility and uptake, and limiting drug degradation and toxicity. Polymers in Drug Delivery is a state-of-the-art documentation and review of all areas in which polymers are used in drug delivery, including... |
 | Drug Delivery: Principles and Applications (Wiley Series in Drug Discovery and Development) by Binghe Wang, Teruna J. Siahaan, Richard A. Soltero An indispensable tool for those working at the front lines of new drug development Written for busy professionals at the forefront of new drug development, Drug Delivery gets readers quickly up to speed on both the principles and latest applications in the increasingly important field of drug delivery. Recent developments in such areas as combinatorial chemistry, proteomics, and genomics... |
 | Modified-Release Drug Delivery Technology, Second Edition, Volume 1 (Drugs and the Pharmaceutical Sciences) This two volume Second Edition describes the anatomical, physiological, pharmaceutical, and technological aspects of oral, colonic and rectal, ocular, oral mucosal, dermal and transdermal, nasal, vaginal, and pulmonary delivery routes, providing insight and critical assessment of the many available and emerging modified release drug delivery systems for their current and future value. Topics... |
 | Polymeric Drug Delivery Systems (Drugs and the Pharmaceutical Sciences) Emphasizing four major classes of polymers for drug delivery-water-soluble polymers, hydrogels, biodegradable polymers, and polymer assemblies-this reference surveys efforts to adapt, modify, and tailor polymers for challenging molecules such as poorly water-soluble compounds, peptides/proteins, and plasmid... |
 | Drug Delivery Systems (Methods in Molecular Biology) The field of drug development and therapeutics can be overwhelmingly encyclopedic and vast. In Drug Delivery Systems, Dr. Kewal Jain and a team of experts select the most important, cutting-edge technologies used in drug delivery systems taking into account significant drugs, new technologies such as nanoparticles, and therapeutic applications. The chapters present step-by-step laboratory... |
| © 2008 BrightSurf.com |