 |
|
Tiny worms paving way for better anesthetics
October 24, 2005Ten genes that may make patients more or less susceptible to a common anesthetic agent have been identified by researchers using tiny worms and sophisticated technology that eliminates the activity of individual genes.
"We are anesthetizing 25 million patients a year in the United States alone; we put them to sleep and wake them up and we still don't know a lot about why it happens," said Dr. Steffen E. Meiler, vice chair of research for the Medical College of Georgia Department of Anesthesiology and Perioperative Medicine and a study author. "A lot of research has been done but the main mechanisms of how these volatile anesthetics (volatility means the anesthetics move easily from liquid to gaseous form) work have really alluded us."
Drs. Meiler, Aamir Nazir and their colleagues are taking advantage of advances in genomics and technology to begin to identify those mechanisms with the ultimate goal of better drugs.
"Eventually what we would like to do is design more specific drugs," says Dr. Meiler of the work being presented during the American Society of Anesthesiologists annual meeting Oct. 22-26 in Atlanta. "The principal question is how can we design anesthetic drugs that have the desired effect of rendering a patient unconscious during surgery without affecting other brain functions that lead to adverse effects," he says.
Critical pieces have come together to make the studies possible including the relatively recent finding that volatile anesthetics interact with proteins. Now that they know they need to look at proteins, sophisticated RNA interference technology enables researchers to do so by stopping the usual process in which information encoded by a singular gene is transformed into a cellular protein.
Tiny C. elegans, free-living soil nematodes that share 50 percent to 60 percent of their genes with humans and are the first study animals to have their genome decoded and sequenced, have given the scientists a manageable model for knocking out select genes, giving anesthetics and measuring the results.
The researchers started their work with the 637 genes known to be expressed in the nervous system of the C. elegans. They designed a tiny gas chamber to deliver Isofluran to the worms. Not unlike earlier days in anesthesiology - before sophisticated monitoring such as the bispectral index system that measures brainwave activity to determine a patient's level of consciousness during surgery - the researchers assessed the anesthetic effect from just watching their subjects. They compared the movement of anesthetized worms to controls.
"This is the best genetic model system," says Dr. Nazir. "The worms we study are about the same age and carry the same genes. If there is a difference between the control and the knock-down mutant, we know that particular gene has something to do with the anesthetic, he says. Using this method, they initially identified 37 candidate genes.
Next, they applied a sophisticated quantification system, developed in conjunction with the California Institute of Technology, that allows 144 precise, objective measures of how far anesthetized worms and the controls travel, including speed, top speed, roaming range, track patterns and other complex behaviors.
That systematic analysis narrowed the field to 10 genes - nine that are hypersensitive and one that is resistant - that are biological modifiers of the anesthetic effects of drugs, Dr. Nazir says.
"These are modifier genes that influence the effect, the degree, the extent of the anesthetic effect," says Dr. Meiler. "We cannot yet say these are direct targets of volatile anesthetics. That is to be tested in another series of studies."
Rather, these first steps have shown the researchers their approach works, so they are moving toward a genome screen in these tiny worms that includes genes whose function is unknown.
Drs. Zhong Chen, research associate, and C. Alvin Head, chair of the MCG Department of Anesthesiology, are co-authors on the study.
Medical College of Georgia
"Eventually what we would like to do is design more specific drugs," says Dr. Meiler of the work being presented during the American Society of Anesthesiologists annual meeting Oct. 22-26 in Atlanta. "The principal question is how can we design anesthetic drugs that have the desired effect of rendering a patient unconscious during surgery without affecting other brain functions that lead to adverse effects," he says.
Critical pieces have come together to make the studies possible including the relatively recent finding that volatile anesthetics interact with proteins. Now that they know they need to look at proteins, sophisticated RNA interference technology enables researchers to do so by stopping the usual process in which information encoded by a singular gene is transformed into a cellular protein.
Tiny C. elegans, free-living soil nematodes that share 50 percent to 60 percent of their genes with humans and are the first study animals to have their genome decoded and sequenced, have given the scientists a manageable model for knocking out select genes, giving anesthetics and measuring the results.
The researchers started their work with the 637 genes known to be expressed in the nervous system of the C. elegans. They designed a tiny gas chamber to deliver Isofluran to the worms. Not unlike earlier days in anesthesiology - before sophisticated monitoring such as the bispectral index system that measures brainwave activity to determine a patient's level of consciousness during surgery - the researchers assessed the anesthetic effect from just watching their subjects. They compared the movement of anesthetized worms to controls.
"This is the best genetic model system," says Dr. Nazir. "The worms we study are about the same age and carry the same genes. If there is a difference between the control and the knock-down mutant, we know that particular gene has something to do with the anesthetic, he says. Using this method, they initially identified 37 candidate genes.
Next, they applied a sophisticated quantification system, developed in conjunction with the California Institute of Technology, that allows 144 precise, objective measures of how far anesthetized worms and the controls travel, including speed, top speed, roaming range, track patterns and other complex behaviors.
That systematic analysis narrowed the field to 10 genes - nine that are hypersensitive and one that is resistant - that are biological modifiers of the anesthetic effects of drugs, Dr. Nazir says.
"These are modifier genes that influence the effect, the degree, the extent of the anesthetic effect," says Dr. Meiler. "We cannot yet say these are direct targets of volatile anesthetics. That is to be tested in another series of studies."
Rather, these first steps have shown the researchers their approach works, so they are moving toward a genome screen in these tiny worms that includes genes whose function is unknown.
Drs. Zhong Chen, research associate, and C. Alvin Head, chair of the MCG Department of Anesthesiology, are co-authors on the study.
Medical College of Georgia
Anesthetics Current Events and Anesthetics News RSSGeneral anesthetics lead to learning disabilities in animal models
Studies by researchers at Wake Forest University School of Medicine have shown that blocking the NMDA receptor in immature rats leads to profound, rapid brain injury and disruption of auditory function as the animals mature.
Infant pain, adult repercussions
Scientists at Georgia State University have uncovered the mechanisms of how pain in infancy alters how the brain processes pain in adulthood.
Finding of genetic region controlling cardiovascular sensitivity to anesthetic propofol
Researchers at The Medical College of Wisconsin in Milwaukee have identified the genetic region in rats responsible for cardiovascular collapse during anesthesia.
Mayo researchers find anesthesia not harmful for babies during birth process
Mayo Clinic researchers have found that children exposed to anesthesia during Cesarean section are not at any higher risk for learning disabilities later in life than children not delivered by C-section.
Long-lasting Nerve Block Could Change Pain Management
Researchers at Children's Hospital Boston have developed a slow-release anesthetic drug-delivery system that could potentially revolutionize treatment of pain during and after surgery, and may also have a large impact on chronic pain management.
Penn Researchers Demonstrate a New Model for Drug Discovery With a Fluorescent Anesthetic
A collaboration of University of Pennsylvania and University of Wisconsin chemists and anesthesiologists have identified a fluorescent anesthetic compound that will assist researchers in obtaining more precise information about how anesthetics work in the body and will provide a means to more rapidly test new anesthetic compounds in the search for safer and more effective drugs.
Mayo researchers find link between anesthesia exposure and learning disabilities in children
Mayo Clinic researchers have found that children who require multiple surgeries under anesthesia during their first three years of life are at higher risk of developing learning disabilities later.
Plastic and reconstructive surgery ... in brief
New web-based research has quantified the attractiveness of the female form. Using morphing software, German researchers manipulated the features of one woman into 243 variations with differing leg lengths, weights, bust sizes, and hip and waist widths.
Flowering plants speed post-surgery recovery
Contact with nature has long been suspected to increase positive feelings, reduce stress, and provide distraction from the pain associated with recovery from surgery. Now, research has confirmed the beneficial effects of plants and flowers for patients recovering from abdominal surgery.
GSU study first to confirm long-term benefits of morphine treatment in infants
A recent study conducted by researchers at Georgia State University is the first of its kind to demonstrate that administration of preemptive morphine prior to a painful procedure in infancy blocks the long-term negative consequences of pain in adult rodents.
More Anesthetics Current Events and Anesthetics News Articles
 |
Red Cross Oral Anesthetic/Analgesic, Maximum Strength, 0.25-Ounce Bottles (Pack of 6) by Red Cross Benzocaine. Canker sore medication. Faster pain relief. Long-lasting protection. Coats the sore while it heals. Better tasting with natural herbs. Acts like a Patch forms a protective layer. The name Red Cross and the Red Cross design are trademarks of The Mentholatum Co., Inc. Products bearing this trademark have no connection with the American Red Cross. Made in USA. |
 |
GiGi Anesthetic Numbing Spray 1.5 oz. by GiGi GiGi Anesthetic Numbing Spray is a topical analgesic spray that gently desenitizes the skin prior to waxing with 4% Lidocaine. Lidocaine penetrates the surface of the skin, numbing the area to be waxed within minutes. GiGi Anesthetic Numbing Spray mimimizes the discomfort associated with waxing. |
 |
Pharmacology and Physiology in Anesthetic Practice by Robert K Stoelting (Author), Simon C Hillier (Author) Dr. Stoelting's best-selling and highly acclaimed text, Pharmacology and Physiology in Anesthetic Practice, is now in its thoroughly updated Fourth Edition. In 60 concise, clearly written chapters, this book provides comprehensive, current, clinically oriented, authoritative information on all aspects of pharmacology and physiology that are relevant to perioperative patient management. This edition includes all new drugs and new findings on actions and interactions of established drugs. More than 400 diagrams and more than 100 tables complement the text. This edition's new two-color page design will help readers spot key information. A separate drug index is included for quick reference. "Doody's Core Titles™ 2009." |
 |
Tronolane Anesthetic Cream for Hemorrhoids, Dual-Action Formula, 2 Ounces (Pack of 3) by Monticello Rapid relief of pain & itching. Odor free, non-greasy, non staining. Tronolane's hospital-used anesthetic relieves pain and itching. Soothes and lubricates. Relieves pain. |
 |
NEW Lido 4% Lidocaine 1 oz Anesthetic Cream Numbing by lidocain Lido 4% Lidocaine Cream ~ 1 oz Treatment Cream Description: Rapid anesthetic cream Ingredients: Lidocaine 4% Deionized water, SD Alcohol, Carbopol, Disodium EDTA, Benzyl Alcohol, Jeechem MLD, Aloe Vera Oil, Upoval J, Glycerin. Directions: Apply a thin layer of Lido cream to treatment area approximately 30 minutes to an hour to treatment for optimal comfort; Reapply additional lido cream to area to be treated prior to be treated 1 minute to starting procedure. Lidocaine may also be used to relieve irritation and inflammation in the mouth and throat. Some forms of this medication are used during certain procedures to reduce pain such as hair removal and tatoo's. |
 |
GiGi Anesthetic Numbing Spray for Sensitive Skin 42g/1.5oz by GiGi Temporarily numbs the skin surface, takes the sting out of waxing and soothes skin. |
 |
Americaine Benzocaine Topical Anesthetic First Aid Spray, Hospital Formula - 2 Oz by HERITAGE. INDICATIONS:Americaine Benzocaine Topical Anesthetic First Aid Spray is the Maximum Strength Hospital Formula contains 20% benzocaine to quickly provide relief from the pain and itching from minor cuts, scrapes, burns and sunburns, insect bites, or minor skin irritations. |
 |
Altered States of Mind Local Anesthetic (Performer) Spanning a broad range of styles, from pop/rock, rock piano ballads and jazz/fusion, to electronic and experimental, the most interesting characteristic of these songs is that they continually change and evolve to maintain your interest, like movie soundtracks. The album was so named, not only because of the various styles of music, but for the places the music can take you and the images they may conjure in your mind. |
|
Radiology, Anesthetic, and Surgical Preparation of Animals Also With: ED (Narrator) | |
 |
I Could Feel The Anesthetic Flow Through My Vain (Original Mix) 2 Working Donkeys (Primary Contributor) |
| © 2009 BrightSurf.com |