REACH researchers are laying the foundation for interactive software that would allow drug developers, or maybe even doctors, to provide lots of information,
as well as genes that would indicate the pathogen is resistant to treatment with antibiotics or other drugs, said co-author Kristine Wylie, Phd, assistant professor of pediatrics.
In the meantime, the technology can be used by scientists to study viruses in a research setting. Kristine Wylie investigates the viruses that set up residence in and on the human body, collectively known as the virome.
whether HIV-positive people are infected with a drug-resistant strain or a non-resistant strain allow patients to get the most effective treatment as quickly as possible.
those pairs that perfectly match the target HIV RNA containing a mutation that causes drug resistance can rapidly become fused together,
quick and accurate HIV drug resistance mutation detection system for use in developing nations. e met soon thereafter
electrical devices (pacemakers or defibrillators) or drugs (eg beta blockers. However, these methods are relatively crude: they can stop
leading to new drug designs and reducing disease. DNA NANOSTRUCTURES: Conducting nanoscale biomolecular research could lead to low-cost DNA sequencing technologies,
and in turn create targeted drug delivery systems and help explain the molecular causes of disease.
and relapsing multiple sclerosis Three phase three clinical studies using the drug ocrelizumab to treat patients with multiple sclerosis (MS) have yielded positive results for treating two forms of the disease and the first ever positive results
on 732 patients with PPMS, found that those treated with the drug had a reduction in the progression of clinical disability of 24 per cent.
open up the possibility that a single drug designed to target this molecular fault could be developed to treat both diseases.
electrical devices (pacemakers or defibrillators) or drugs (eg beta blockers. However, these methods are relatively crude: they can stop
The findings, published Oct 19 in Nature Immunology, reveal previously unknown weapons in the body antiviral immune arsenal
and provide guidelines for designing drugs that could be effective against a broad range of viruses. The strategy involves enhancing the body interferon signaling system,
long understood to be a vital part of antiviral defenses. ee discovered a new component of the interferon system,
Despite the strong antiviral immune response seen in the new study, Holtzman and his colleagues reported no evidence of autoimmune disease in these mice.
and absence of destructive autoimmunity could be that the researchersstrategy did not involve increasing the amount of interferon, the first step of this important antiviral signaling cascade.
which sets off the rest of the antiviral cascade. It like greasing the wheels. Wee not pushing the system any harder.
and continue their destructive march through the body. his dual mechanism of action is a great guideline for how we would like to build a new antiviral drug,
according to Holtzman, is that a drug with this dual function could be effective against different kinds of viruses that affect a variety of tissues,
drug discovery Mini-kidney organoids have now been grown in a laboratory by using genome editing to re-create human kidney disease in petri dishes.
The work paves the way for personalized drug discovery for kidney disease. The mini-kidney organoids were grown from pluripotent stem cells.
as important for understanding the potential of mini-kidneys for clinical kidney regeneration and drug discovery.
better ways to perform linical trials in a dishto test drugs and therapies that might work in humans.
to model human kidney development and to test for drug toxicity. Now, using gene-editing tools,
better ways of testing out drugs and therapies that might work in humans. g
#Snake venom helps hydrogels stop the bleeding Rice university lab employs clotting powers of viper-derived drug,
even in presence of anticoagulants A nanofiber hydrogel infused with snake venom may be the best material to stop bleeding quickly, according to Rice university scientists.
particularly for patients who take anticoagulant drugs to thin their blood. t interesting that you can take something so deadly
an anticoagulant drug. rom a clinical perspective, that far and away the most important issue here, Hartgerink said. here a lot of different things that can trigger blood coagulation,
then we could potentially restore sensitivity to drugs, she explained. t would mean a better chance of survival for women with ovarian cancer.
However, chemoresistance to platinum drugs remains a serious challenge to curing ovarian cancer. Murph recommends more research on mtor inhibitors to see how they can be modified to respond to chemotherapy. ive years ago
The discovery has raised hopes that a drug that targets the receptors and stops the cancer will soon be developed.
not just those with hereditary ovarian cancer. ome drugs are showing promise as a treatment for patients with hereditary ovarian cancer,
Researchers believe the Ror amilyof receptor molecules are attractive drug targets for three reasons. First, the receptors are not usually present in normal adult tissues
which means that any drug therapy will likely have few side effects. Second the location of the receptors on the outer surface of cancer cells means they can be accessed easily by drugs.
Third, Ror1 and Ror2 are a specific type of receptor that controls many other genes,
and spread of ovarian cancer. nce we better understand the roles of these receptors we will be in a position to develop a drug to target these receptors and hopefully halt ovarian cancer in its tracks,
Originally discovered as an antiviral system in bacteria, CRISPR/Cas9 is one of the hottest topics in genetic research today.
and change how different people respond to drugs. But only if the CRISPR technique is specific enough.
and how they vary between cell types, during development or in response to drug treatment. urrent methods for controlling gene switches,
including drugs used in clinical trials, change the activity of many switches across the genome simultaneously,
and that could eventually lead to the development of a drug to enhance recovery from strokes n
and testing the water disinfectant. he goal of Madidrop PBC is to maximize health benefits,
#Bacterial hole puncher could be new broad-spectrum antibiotic Bacteria have many methods of adapting to resist antibiotics,
The antimicrobial agents are dressed for their mission in a positively charged shell that lets them travel in body fluids,
a co-first author of the paper. any antimicrobial agents can only cure one class of bacteria.
We need more broad-spectrum antimicrobial agents. The new antimicrobial polypeptides are designed specially to fold into a rigid spiral resulting in a rodlike structure,
ideal for punching holes in the bacterial membrane. e use a very set mechanism to puncture the bacterial membrane,
Many drugs are targeted very, interacting with a particular protein or interfering with a particular pathway in the bacterial cell.
Bacteria can develop resistance to the antibiotic by circumventing the specific target. Since the spiral structures simply poke holes in the physical structure of the membrane
In addition, the new antimicrobial agents could be coupled with other, targeted drugs to enhance their effectiveness. he polypeptides punch holes in the membrane,
which makes it very easy for other drugs to go through and bypass some of the drug-resistant mechanisms,
Cheng said. ogether, they work even better than a single agent. Because the proteins have a preset design,
Cheng predicts that scaling up production would not present significant challenges. The precursor elements are manufactured already at large scales and available commercially.
the researchers will continue to improve the antimicrobial polypeptides, further decreasing interaction with human cells,
Today, the disease is treated usually with drugs, which can have serious side effects. It can also be treated with a procedure called cardiac ablation that burns away the malfunctioning cells using a high-powered laser that threaded into the heart on a catheter.
Drugs that flip this switch rapidly reduced obesity and diabetes risk factors in mice fed a high fat diet.
The results suggest that drugs capable of targeting similar molecular pathways in human fat cells could one day become major tools for fighting the growing worldwide epidemics of obesity and type 2 diabetes, according to senior
Early drugs also had dangerous cardiovascular side effects, which are of particular concern in obese patients.
CK2-blocking drugs boost metabolism prevent weight gain The researchers tested two anti-CK2 drugs for their ability to stimulate the production of new brown fat in mice:
Both drugs succeeded in turning significant amounts of white fat brown and significantly increasing the amount of energy mice burned
The drugs also significantly reduced the negative effects of a high-fat diet in mice, including reducing weight gain and, to the researcherssurprise,
but cautious about the prospects for using these drugs to treat human obesity in the near future. t exciting,
The difference is that Ovastasis plans to use those protein biomarkers as targets for a novel female birth control medication. he identification of drug targets that are selective to the egg
or to the sperm gives you opportunities to create small-molecule drugs for female and male contraception, contraceptive vaccines,
and opens opportunities for biological drug strategies that selectively target the gametes in the ovary and testis,
While effective, these drugs are steroids and interact with receptors in many organ systems in the body.
Like Ovastasis, Neoantigenics is focused on creating a targeted drug that will affect only those cells identified by the correct cell surface biomarkers.
the antibody-drug burrows inside them to release a toxic payload. ou add an antibody with a drug on it
and release the drug payload, triggering changes that result in cell death within a few days.
The drug can be used by both women and men but for female cancer patients especially, a treatment that doesn touch their body healthy tissues is a huge breakthrough. e think we have a way
so may find applications in drug toxicity tests, the search for new drugs and cell therapy.
making them useful for applications in drug discovery and toxicology. This study was supported by CREST program of Japan Agency for Medical Research and development,
The goal of some antiviral therapies, therefore, is to buy more and give the immune system a leg up on the virus. A new study led by Bruce Freedman
said Freedman. e could also imagine this type of drug would be part of a cocktail therapy,
and reproduce, the Penn Vet scientists have focused on developing drugs that interfere with the host proteins
The researchers are working with Fox Chase Chemical Diversity Center scientists to develop even more potent ORAI1 inhibitors to improve antiviral activity
They noted that such drugs would only be given for a short duration, lessening the chance of serious side effects.
or drug targeting. The study by researchers Cheulhee Jung, Peter B. Allen and Andrew Ellington, published this week in the journal Nature Nanotechnology,
but it also suggests that these physical channels might be exploitable to deliver drug therapies. hope that the tools we have developed,
and by the pharmaceutical industry in the quest for novel anticancer drugs that block tumor-organ communication,
they observed a transfer of red material into the green healthy cells of the mice mammary fat pads. exican drug lords are not the only ones who use secret tunnels to move material across seemingly impenetrable borders,
when we discovered that a new drug we were studying specifically killed cancer cells with this mutation.
and his team showed that cancer cells with a mutated SETD2 gene were killed by a drug called AZD1775 that inhibits a protein called WEE1.
which could lead to new drugs for the disease. Tuberculosis, caused by Mycobacterium tuberculosis bacteria, has proved incredibly stubborn even in the age of powerful antibiotics,
infecting about one third of all people worldwide. Treatment can take up to nine months. It has stealth properties that protect it from antibiotics;
it can hide inside human cells, avoiding the body immune system while it waits for the opportune moment to multiply;
In order to make new drugs, researchers need to search through the thousands of proteins in the bacterial world to find one that does something so important the bacterium can live without itnd then make a little block to match.
Joachimiak said. his is very important for finding a molecule to build a drug aroundou don want to inhibit a human enzyme, just the pathogen one.
Researchers have been interested in the mycobacterium IMPDH enzyme as a drug target for years Joachimiak said,
When scientists develop a new drug, they need to work with the pharmaceutical industry to perform extensive tests to ultimately bring it to the consumers.
Even powerful drugs to block the immune attack can entirely stop it. In a famous 1984 case, a California newborn known as aby Faereceived a baboon heart.
Mohiuddin says the pig heart gave out only when he decided to stop giving the baboon the novel immune-blocking drugs he had used. e believe it could have gone on forever,
New drugs are the most obvious story that could be told with the technology. A startup company called Synthorx, created by Romesberg
a way for another drug to attach to the protein at a specific site. The technology might also pave the way to new biotech drugs.
Nearly all such drugs proteins like insulin or the blood cell-booster erythropoietin, are made inside a bacterium or other cell.
But synthetic DNA could vastly expand what drugs are possible. That is because a normal cell builds proteins from just 20 amino acids,
stringing them together into long chains. Exactly which amino acid gets added next is specified by three-letter sequences of DNA, called codons.
Unlike conventional drugs, where chemists exert exquisite control over the position of every atom, with proteins they mostly still need a living thing to do their manufacturing for them. hen you get to whole proteins,
Turner thinks the system could be of interest to drug companies who could use it to generate ideas for new drugs. ou could make a million proteins with unnatural amino acids
And once synthetic biology leads to a new drug or vaccine, he thinks, wel get used to the idea of inventing life for our own good. ne has to pick the most near-term applications of this technology to show what it can really do for the good of mankind,
and Drug Administration (FDA) has approved the first-ever 3d printed drug, and it likely won't be the last.
even in large doses. The pill is easy to take on the go since there's no measuring of medication.
Aprecia, which makes the drug, noted Spritam is designed to help epilepsy patients adhere to their treatment regimen
Aprecia uses its own Zipdose Technology platform to make the drug. Combining"formulation science"with 3d printing technology first developed at MIT, the company can make porous medications that disintegrate rapidly with very little liquid.
California, said in a press release. ur research is in the early phase of drug development process,
the structures could help scientists screen drugs for toxicity and model normal and diseased kidney function,
#Epilepsy drug is approved first FDA 3d printed pill The first 3d printed pill has been approved for use by the US Food and Drug Administration (FDA.
The drug is fabricated with Aprecia proprietary Zipdose Technology platform, which uses 3d printing to produce a porous,
The resultant drug is highly porous and can support doses of up to 1, 000mg that disintegrate in the patient in less than 10 seconds. y combining 3d printing technology with a highly-prescribed epilepsy treatment,
#Skin patch material releases drugs when it stretches Researchers have developed a method of drug delivery that consists of an elastic patch that can be applied to the skin
and release drugs when the patch is stretched. The wearable, tensile strain-triggered drug delivery device has been developed by researchers at North carolina State university
and the University of North carolina at Chapel hill. his could be used to release painkillers whenever a patient with arthritic knees goes for a walk,
These microcapsules, in turn, are packed with nanoparticles that can be filled with drugs. The university said in a statement that the microcapsules stick halfway out of the film, on the side of the film that touches a patient skin.
The drugs release slowly from the nanoparticles and are stored in the microcapsules. When the elastic film is stretched
and effectively squeezing some of the stored drug out onto the patient skin, where it can be absorbed. hen the microcapsule is stretched from left to right,
co-senior author of the paper and an associate professor of mechanical and aerospace engineering at NC State. hat compression helps push the drug out of the microcapsule.
After being stretched, the microcapsule is refilled by the drugs that continue to leak out of the nanoparticles. his can be used to apply drugs directly to sites on the skin
and antibiotics for wound healing, said Jin Di, co-lead author and a Ph d student in Gu lab. The researchers are said also to have incorporated microneedles into the system,
In this configuration, the drugs can be squeezed through the microneedles. The microneedles are small enough to be painless,
but large enough to allow drugs to diffuse into the bloodstream through tiny capillaries underneath the skin. his expands the range of drugs that can be applied using the technology,
and a Ph d student in Zhu lab. ee now exploring how this tool can be used to apply drugs efficiently
The paper, tretch-Triggered Drug Delivery from Wearable Elastomers Containing Therapeutic Depots, is published online in the journal ACS Nano.
but slow progress is being made towards developing a drug treatment. So this proof-of-concept study is important
because it demonstrates that the memory game can help where drugs have failed so far. ecause the game is interesting,
and direct drugs to damaged tissues. Writing in the journal Nature Communications the researchers describe how they used ultrasound to move tiny polystyrene beads measuring only 3mm across
said Marzo. r you could hold a drug wherever you wanted to inside a patient,
similar to an ultrasound scanner but for manipulating particles Targeted drug delivery and moving your kidney stones around are among the applications the researchers think could emerge from their work.*
#Genentech drug adds antibiotics to proteins to fight hidden bacteria Scientists at Genentech have armed the body immune system warriors with antibiotics
which means that bacteria that hide from drugs inside cells are now targets. In a study published today in Nature,
scientists linked an antibody with a derivative of a group of antibiotics called rifamycin. This resulting drug proved to be a powerful new treatment against Staphylococcus aureus;
it actually helped mice clear staph infections at a stage when conventional antibiotics normally stop being effective.
But that's only part of the reason why researchers are excited about the technique. What's truly different here is that unlike the related antibiotic rifampicin the linked antibody-antibiotic unit can kill Staphylococcus bacteria inside cells.
This means that it might one day be possible to use this technique to treat people with life-threatening antibiotic-resistant infections.
BACTERIA THAT HIDE FROM DRUGS INSIDE CELLS ARE TARGETS Staphylococcus aureus is a very common bacterium;
about 30 percent of people carry it around in their noses. Most of the time that isn't a problem,
certain strains have become resistant to common antibiotics. As a result, one type of resistant staph bacteria called MRSA causes over 80,000 infections and 11,285 deaths occur every year.
a hideout where antibiotics typically used against staph infections aren't as effective.""Staph can hide inside blood cells for a couple of hours or days,
That's a big problem because drugs that are used normally against staph infections can take over four hours to work far longer than it takes for Staph bacteria to move into new cells,
'Can we tag the bacteria with antibodies armed with really potent antibiotics and kill these pathogens inside the cell?'"
Then, the researchers attached the antibiotics to the antibody by using amino acids as glue. When combined
the drug becomes far better at specifically targeting staph at specifically targeting Staph bacteria compared with conventional antibiotics."
"The researchers showed that the drug was effective against this strain; it worked the way it was designed to,
The drug is definitely in its infancy, but it holds a lot of promise. Scientists haven't been able to conclusively say
Because the drug acts inside cells it's possible that this treatment might one day help people avoid repeated infections,
Because the antibiotic is only active inside infected cells, it won wipe out the other bacteria beneficial bacteria with drugs distributed more broadly in the body.
That means that people might end up being less vulnerable to other illnesses than they normally would following the treatment.
of which are good indicators of a drug's effect on humans. Mariathasan declined to tell The Verge
"In addition, the drug is very specific, and so if it does make it to humans, doctors will probably only be able to give it to patients with a firm diagnosis. In some parts of the world,
Still, the act of combining two different weapons antibodies and antibiotics to fight off infections is an intriguing idea.
which is known for its manually applied disinfectants. In 2014 the company entered the disinfection robot market
Nine patients were treated with tocilizumab an immunosuppressant drug that blocks the effects of the inflammatory cytokine IL-6
In July 2014 the U s. Food and Drug Administration granted CTL019 its Breakthrough Therapy designation for the treatment of relapsed and refractory adult and pediatric ALL a step
#Optimal particle size for anticancer nanomedicines discovered Nanomedicines consisting of nanoparticles for targeted drug delivery to specific tissues
and his collaborators systematically evaluated the size-dependent biological profiles of three monodisperse drug-silica nanoconjugates at 20 50 and 200 nm.
and Leber's congenital amaurosis by providing novel drug targets to prevent photoreceptor degeneration concludes Dr. Cayouette.
We were pleased quite that the work led us to NOS3-targeting drugs that are already available
along with a drug that selectively destroys the diseased cells brimming with the mineral leaving non-cancer cells healthy.
The combination approach which uses two drugs already commercially available for other uses could soon be tested in clinical trials among patients with late-stage disease.
and then use a drug that requires copper to be effective to attack the tumors.
Among those they found was disulfiram a drug approved by the FDA to treat alcoholism.
The Duke team found that the amount of copper cancer cells naturally hoard is not enough to make the cells sensitive to the drug.
and controlled drug release systems the researchers said. Biomedical applications include microfluidic devices that can handle
Researchers used tumour cells derived from 100 different glioblastoma patients to test drugs that could target the disease.
when using a drug AZD8055 combined with Temozolomide (TMZ)--a drug already taken by most glioblastoma patients--the life of the animals was extended by 30 per cent.
and Dr. Lesley Seymour (Director of the NCIC Clinical Trials Group's Investigational New Drug Program) and drug manufacturer Astrazeneca to plan a clinical trial testing a similar but newer drug
This is an important initiative--to test new drugs being developed for other types of cancers in the laboratory to identify which are most promising for testing in patients with glioblastoma.
Dr Burton's work could point to the potential development of new drugs as well as new approaches to preventing brain damage and death.
Dr Burton has found that applying a drug that closes the water channels can inhibit initial water entry helping to close the window of vulnerability.
A second drug used later in the progression of the injury acts to enhance the water channel activity letting superfluous moisture out when needed.
This work also demonstrates for the first time that recently discovered drug-like compounds can be used in series to initially reduce water entry
Continued work showed that Yohimbin a drug that had been deregistered for several years effectively blocked the gene variant's damaging effects both in animal experiments
The fact that this was an old drug made this journey a lot faster. The substance had already been tested for safety
The substance must also be tested on more patients before it can become a clinical drug says Anders Rosengren adding purely theoretically the drug should be effective for the 40 per cent of type 2 diabetes sufferers who are carriers of the genetic risk variant.
For instance these methods could be used to identify biochemical pathways that cancer cells may use to develop drug resistance
By preventing protein production RNA interference may be used to get around the problem of difficult-to-target proteins a frequent challenge in drug development.
which cancer cells develop resistance to anticancer drugs--a process that typically involves gene activation n
In a paper published today in the journal Cancer cell the researchers report how the drug known as DTP3 kills myeloma cells in laboratory tests in human cells
The new drug works by stopping a key process that allows cancer cells to multiply. The team have been awarded Biomedical Catalyst funding from the Medical Research Council (MRC) to take the drug into a clinical trial in multiple myeloma patients scheduled to begin in late 2015.
Multiple myeloma is an incurable cancer of the bone marrow which accounts for nearly two per cent of all cancer deaths.
The new drug was developed by studying the mechanisms that enable cancer cells to outlive their normal lifespan
Further refinements led to the experimental drug DTP3 which tests showed kills cancer cells very effectively
and other drug candidates based on Professor Franzoso's research with support from Imperial Innovations a technology commercialisation company focused on developing the most promising UK academic research.
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