Showing posts with label Drug Discovery. Show all posts
Showing posts with label Drug Discovery. Show all posts

Monday, September 28, 2015

Scientists identify new agent to combat tuberculosis


Click to see the large picture
(Griselimycin)



New hope in the fight against tuberculosis

Above pic: The protein forms a homodimeric ring (shown as blue cartoon & surface representation). Each polypetide chain binds one molecule of griselimycin (red). The optimized compound cyclohexylgriselimycin contains an additional cyclohexane moiety (yellow, shown only for the ligand in the foreground).

According to figures of the World Health Organization, some 8.7 million people contracted tuberculosis in 2012 and this disease is fatal for approximately 1.3 million people throughout the world each year. One of the main problems is that the tuberculosis pathogens have become resistant to the antibiotics used to fight them. Scientists from the Helmholtz Institute for Pharmaceutical Research Saarland (HIPS) in Saarbrücken, the Helmholtz Centre for Infection Research (HZI) in Braunschweig and the German Center for Infection Research (DZIF) joined forces with scientists from Sanofi, a global health care company, and identified a new agent, which might potentially remedy these problems. The scientists just described this agent and its unique mechanism of action in the highly renowned scientific journal Science.

Mycobacterium tuberculosis is the main cause of tuberculosis. The treatment for drug-susceptible tuberculosis consists of the daily administration of multiple drugs for a minimum of six months. Lack of adherence to this regimen can result in treatment failure and the emergence of drug resistance. "Complexity and duration of the treatment are true issues and the main reasons for the development of resistant pathogens," says Prof Rolf Müller, who is the Executive Director and head of the Microbial Natural Substances department of the HIPS, an institution jointly sponsored by the HZI and Saarland University.

Consequently, there is an urgent need for new medications and therapeutic approaches to both fight the resistant pathogens, as well as to shorten the duration for the treatment of drug-susceptible organisms. Based on earlier reports, Müller, in collaboration with Prof Jacques Grosset from the Johns Hopkins University School of Medicine in Baltimore, and his colleagues from the HZI and Sanofi scientists, initially focused on the natural substance called griselimycin. The potential of this natural substance, was discovered in the 1960s. However, due to the success of other tuberculosis medications and its low efficacy in an infection model, the substance was not developed any further at the time.

"We resumed the work on this agent and optimised it such that it shows excellent activity in the infection model - even against multi-resistant tuberculosis pathogens," says Müller. In the course of their work, the scientists discovered that cyclohexylgriselimycin, a variant of griselimycin, is particularly effective against Mycobacterium tuberculosis, both in cells and in the animal model. Importantly, cyclohexylgriselimycin was effective when administered orally, which is key in tuberculosis treatment, non-orally available drugs are extremely burdensome to administer daily during the many months of treatment. Moreover, combining this substance with current TB antibiotics increases the efficacy compared to the antibiotic cocktail that is usually administered.

Friday, September 25, 2015

Once-weekly Trulicity 0.75 mg shows promising results in Japanese patients with type 2 diabetes

Dapagliflozin - Structural Formula Illustration


In continuation of my update on dapagliflozin

Results from a new study of Japanese patients with type 2 diabetes showed once-weekly Trulicity™ 0.75 mg provided greater hemoglobin A1c (A1C) reduction compared to once-daily Victoza® 0.9 mg after 52 weeks of treatment. Eli Lilly and Company (NYSE: LLY) will present these data at the 75th American Diabetes Association (ADA) Scientific Sessions in Boston.

"These data not only reinforce once-weekly Trulicity as a safe and efficacious GLP-1 receptor agonist, but further support the value for Japanese patients, with greater A1C reductions compared to once-daily Victoza," said Jessie Fahrbach, M.D., medical director, Lilly Diabetes. "We are pleased to present these study findings, which capture important information about a key region where type 2 diabetes is on the rise."

The study's primary objective was met, with Trulicity 0.75 mg demonstrating a greater A1C reduction from baseline compared to placebo at 26 weeks. At the final endpoint of 52 weeks, which is the focus of the data presentation at the meeting, Trulicity 0.75 mg demonstrated statistically greater A1C reductions compared to Victoza 0.9 mg, the highest approved dose in Japan (-1.39 percent vs. -1.19 percent). Additional results showed:

Trulicity 0.75 mg provided statistically greater reductions in the average self-monitored blood glucose levels compared to Victoza 0.9 mg (-53.1 mg/dL vs. -46.8 mg/dL); and
Trulicity 0.75 mg significantly lowered average post-meal blood glucose levels from baseline compared to Victoza 0.9 mg (-63.7 mg/dL vs. -55.4 mg/dL).

Results from a new study of Japanese patients with type 2 diabetes showed once-weekly Trulicity™ 0.75 mg provided greater hemoglobin A1c (A1C) reduction compared to once-daily Victoza® 0.9 mg after 52 weeks of treatment. Eli Lilly and Company (NYSE: LLY) will present these data at the 75th American Diabetes Association (ADA) Scientific Sessions in Boston.

"These data not only reinforce once-weekly Trulicity as a safe and efficacious GLP-1 receptor agonist, but further support the value for Japanese patients, with greater A1C reductions compared to once-daily Victoza," said Jessie Fahrbach, M.D., medical director, Lilly Diabetes. "We are pleased to present these study findings, which capture important information about a key region where type 2 diabetes is on the rise."

The study's primary objective was met, with Trulicity 0.75 mg demonstrating a greater A1C reduction from baseline compared to placebo at 26 weeks. At the final endpoint of 52 weeks, which is the focus of the data presentation at the meeting, Trulicity 0.75 mg demonstrated statistically greater A1C reductions compared to Victoza 0.9 mg, the highest approved dose in Japan (-1.39 percent vs. -1.19 percent). Additional results showed:

Trulicity 0.75 mg provided statistically greater reductions in the average self-monitored blood glucose levels compared to Victoza 0.9 mg (-53.1 mg/dL vs. -46.8 mg/dL); and Trulicity 0.75 mg significantly lowered average post-meal blood glucose levels from baseline compared to Victoza 0.9 mg (-63.7 mg/dL vs. -55.4 mg/dL).

Monday, September 14, 2015

Promising preliminary results for AKB-9778 in diabetic macular oedema

The core structure of AKB-9778 (p-substituted phenylsulfamic acid).
AKB-9778, a small molecule competitive inhibitor of vascular endothelial-protein tyrosine phosphatase (VE-PTP), has a good safety and efficacy profile in patients with diabetic macular oedema, suggests a preliminary dose-escalation study. 

By blocking VE-PTP, AKB-9778 promotes the activation of Tie2, a protein involved in the regulation of vascular permeability, explain the researchers. In preclinical studies, AKB-9778 has been shown to suppress vascular leakage as well as neovascularisation of the retina and choroid, they add.

In this phase Ib trial, four groups of six patients were treated with open-label AKB-9778 self-administered twice daily via subcutaneous injections at doses of 5.0 mg, 15.0 mg, 22.5 mg or 30.0 mg for 4 weeks.
Participants treated with the higher 22.5 mg and 30.0 mg doses, but not those given the 5.0 mg and 15.0 mg doses, experienced headache, dizziness and vasovagal events such as presyncope or syncope – adverse events that are consistent with the anticipated vasodilatory activity of AKB-9778, say the researchers.

“Modest decreases” in resting systolic blood pressure were also observed in the 22.5 mg and 30.0 mg groups, they report, adding that these effects and the adverse events were “transient” and “generally resolved” shortly after dosing.

At 4 weeks, best-corrected visual acuity (BCVA) improved from intake in the 15.0 mg, 22.5 mg and 30.0 mg groups; of 18 participants, 10 achieved an improvement of five to 10 letters, one improved by 11 letters and two by over 15 letters.

Moreover, seven patients who received AKB-9778 at doses of 15.0 mg or more showed decreases in study eye central subfield thickness (CST) from baseline, with reductions of over 100 μm in five patients and of 50 to 100 μm in two patients.

Tuesday, September 8, 2015

Study expands understanding of the production of ET-743 compound



Trabectedin.png
In continuation of my update on Trabectedin

For decades, scientists have known that ET-743, a compound extracted from a marine invertebrate called a mangrove tunicate, can kill cancer cells. The drug has been approved for use in patients in Europe and is in clinical trials in the U.S.

Scientists suspected the mangrove tunicate, which is a type of a sea squirt, doesn't actually make ET-743. But the precise origins of the drug, which is also known as trabectedin, were a mystery.

By analyzing the genome of the tunicate along with the microbes that live inside it using advanced sequencing techniques, researchers at the University of Michigan were able to isolate the genetic blueprint of the ET-743's producer--which turns out to be a type of bacteria called Candidatus Endoecteinascidia frumentensis.

The findings greatly expand understanding of the microbe and of how ET-743 is produced, the researchers reported online May 27 in the journal Environmental Microbiology. They're optimistic that the insights will help make it possible to culture the bacteria in the laboratory without its host.

"These symbiotic microbes have long been thought to be the true sources of many of the natural products that have been isolated from invertebrates in the ocean and on the land. But very little is known about them because we're not able to get most of them to grow in a laboratory setting," said study senior author David Sherman, the Hans W. Vahlteich Professor of Medicinal Chemistry in the College of Pharmacy and a faculty member of the U-M Life Sciences Institute, where his lab is located.

"Currently, many of these compounds can only be harvested in small amounts from host animals, which is unsustainable from an economic and environmental perspective," said Michael Schofield, one of two first authors on the study and a member of the Sherman lab before she graduated from U-M this spring. "Our hope is that understanding the genomes of these micro-organisms and the chemical reactions that occur inside of them will provide new avenues to economical and sustainable production of the medicinal molecules they make."

ET-743 is currently made using a complicated, partially synthetic process.

"A major challenge of sequencing genomes from samples containing a mixture of different organisms is figuring out which DNA sequences go with which organisms. We used bioinformatic approaches that allowed us to tease that apart," said Sunit Jain, a bioinformatics specialist in the U-M Department of Earth and Environmental Sciences, and the study's other first author.

Monday, August 31, 2015

Chemical compound shows promise in treating rheumatoid arthritis



ChemSpider 2D Image | (11Z)-11H-Indeno[1,2-b]quinoxalin-11-one oxime | C15H9N3O





Montana State University researchers and their collaborators have published their findings about a chemical compound that shows potential for treating rheumatoid arthritis.

The paper ran in the June issue of the Journal of Pharmacology and Experimental Therapeutics (JPET), and one of its illustrations is featured on the cover. JPET
is a leading scientific journal that covers all aspects of pharmacology, a field that investigates the effects of drugs on biological systems and vice versa.

"This journal is one of the top journals that reports new types of therapeutics that are being developed," said Mark Quinn, senior author on the paper and a professor in MSU's Department of Microbiology and Immunology. The department is part of the College of Agriculture and the
College of Letters and Science.

Rheumatoid arthritis is a chronic autoimmune disorder that affects an estimated 1.3 million people in the world, Quinn said. Characterized by stiff, swollen joints, it's a progressive disease that occurs when the body's immune system attacks its own cells. Inflammation in the lining of the joints leads to loss of bone and cartilage. People who have rheumatoid arthritis lose mobility and joint function without adequate treatment.

New kinds of drugs have been developed for treating the disease, Quinn said. Called biological drugs, or "biologics," they are made from genetically engineered proteins or antibodies that act on substances in the immune system. When used to treat rheumatoid arthritis, they interrupt signals that fuel the inflammatory process. Two such drugs are ENBREL and HUMIRA.

Biologics can be expensive, however, and some people don't respond to
them, Quinn said. Some people respond at first, but not forever.

"There is a real need to develop new kinds of drugs that are different," Quinn said. "They could be combined with other available drugs or replace drugs that aren't working for patients."

Researchers in his laboratory and elsewhere identified a new chemical compound, called IQ-1S, in a previous study, Quinn said. Then they conducted a new study to understand how the   small-molecule  compound
works against rheumatoid arthritis. They explained their findings in the JPET paper.  

Ref : http://jpet.aspetjournals.org/content/353/3/505.abstract?sid=8b8e3977-7bbd-40f4-ab43-f37402878df0



Chemical compound shows promise in treating rheumatoid arthritis

Tuesday, August 25, 2015

First-line axitinib ‘feasible’ in advanced, metastatic RCC


Axitinib2DACS.svg




We know that, Axitinib (AG013736; trade name Inlyta) is a small molecule tyrosine kinase inhibitor developed by Pfizer. It has been shown to significantly inhibit growth of breast cancer in animal (xenograft) models and has shown partial responses in clinical trials with renal cell carcinoma (RCC) and several other tumour types.  It was approved by the U.S. Food and Drug Administration after showing a modest increase in progression-free survival, though there have been reports of fatal adverse effects...
--------------------------------------------------------------------------------------

Now..

A Japanese single-institution study suggests that axitinib may be a feasible first-line option for patients with locally advanced or metastatic renal cell carcinoma (RCC). Axitinib treatment resulted in “improved oncological outcomes” and had an “acceptable safety profile”, say the researchers in BMC Urology.

The team reviewed medical records for 18 patients with locally advanced or metastatic RCC who received first-line axitinib for a median duration of 10.8 months, five and nine patients had a partial response and stable disease, respectively, while four progressed.



Wednesday, August 12, 2015

Potential new painkiller provides longer lasting effects ..........



Medications have long been used to treat pain caused by injury or chronic conditions. Unfortunately, most are short-term fixes or cause side effects that limit their use. Researchers at the University of Missouri have discovered a new compound that offers longer lasting painkilling effects, and shows promise as an alternative to current anesthetics.

"Because of its versatility and effectiveness at quickly numbing pain in targeted areas, lidocaine has been the gold standard in local anesthetics for more than 50 years," said George Kracke, Ph.D., associate professor of anesthesiology and perioperative medicine at the MU School of Medicine and lead author of the study. "While lidocaine is effective as a short-term painkiller, its effects wear off quickly. We developed a new compound that can quickly provide longer lasting relief. This type of painkiller could be beneficial in treating sports injuries or in joint replacement procedures."

Painkillers work by interfering with the nervous system's transmission of nerve signals that the body perceives as pain. Lidocaine is used as an injectable pain reliever in minor surgical or dental procedures, or as a topical ointment or spray to relieve itching, burning and pain from shingles, sunburns, jellyfish stings and insect bites. The new compound developed at MU, boronicaine, could potentially serve many of those same functions as an injectable or topical painkiller.
National Academy of Sciences member M. Frederick Hawthorne, Ph.D., director of MU's International Institute of Nano and Molecular Medicine and a pioneer in the field of boron chemistry, synthesized boronicaine as a derivative of lidocaine. By changing aspects of the chemical structure of lidocaine, the researchers found that the new compound provided pain relief that lasted five times longer than lidocaine. In pre-clinical, early stage studies, boronicaine provided about 25 minutes of relief, compared to about five minutes of pain relief with lidocaine.

"Although some conditions may warrant the use of a short-lasting painkiller, in many cases a longer lasting anesthetic is a better option," Kracke said. "Having a longer lasting anesthetic reduces the dosage or number of doses needed, limiting the potential for adverse side effects." While other types of painkillers can provide longer pain relief than lidocaine, they can cause heart toxicity, gastrointestinal issues and other side effects. Preliminary findings show no toxicity in single-dose studies of boronicaine, though more studies are needed.
"Boronicaine could have distinct advantages over existing painkilling medications," said Hawthorne, who also serves as the Curators' Distinguished Professor of Chemistry and Radiology at MU. "We're conducting more research into the side effects of the compound, but in time it could very well become a useful material to use as an anesthetic."

Ref : http://onlinelibrary.wiley.com/doi/10.1002/cmdc.201402369/pdf

Monday, April 20, 2015

Designed Molecules Trap Cancer Cells in Deadly Cages




Chemists have designed a carbohydrate-based molecule that can surround and strangle bone cancer cells by self-assembling into a tangled web of nanofibers (J. Am. Chem. Soc. 2014, DOI: 10.1021/ ja5111893). The molecule spares healthy cells because its assembly is triggered by an enzyme that’s overexpressed on cancer cells.
The inspiration for spinning a molecular cage around cells came from nature, says Rein V. Ulijn of the City University of New York’s Hunter College. Many of the body’s cells are enmeshed in an extracellular matrix—a complex web of biomolecules that provides structure for tissues, facilitates intercellular communication, and traps nutrients. Scientists are developing molecules that spontaneously assemble into simpler versions of this matrix to provide a growth medium for cells, in particular for tissue engineering.
The field has focused mainly on self-assembling peptides. In a recent study, Bing Xu of Brandeis University and colleagues designed a nonnurturing peptide that aggregates and engulfs cancer cells only when its phosphate group is removed (Angew. Chem. Int. Ed. 2014, DOI: 10.1002/anie.201402216). The phosphate-free peptides have a hydrophilic end and a hydrophobic one, which allow them to assemble like lipids in a cell membrane. The negative charge on the phosphate groups creates electrostatic repulsion between the molecules and prevents this. This phosphate on-off switch is great for targeting cancer because some types of cancer cells overexpress alkaline phosphatase, an enzyme that cleaves phosphates.
Ref : http://onlinelibrary.wiley.com/doi/10.1002/anie.201402216/abstract

Thursday, March 19, 2015

New version of common antibiotic could eliminate risk of hearing loss

"All I remember is coming out of treatment not being able to hear anything," said Bryce, now a healthy 14-year-old living in Arizona. "I asked my mom, 'Why have all the people stopped talking?'" He was 90 percent deaf.


"The loss has been devastating," said his father, Bart Faber. "But not as devastating as losing him would have been."
Treatment with aminoglycosides, the most commonly used class of antibiotics worldwide, is often a lifesaving necessity. But an estimated 20-60 percent of all patients who receive these antibiotics suffer partial or complete hearing loss.
Now, in a study that will be published online Jan. 2 in the Journal of Clinical Investigation, researchers at the Stanford University School of Medicine report that they have developed a modified version of an aminoglycoside that works effectively in mice without the risk of causing deafness or kidney damage, another common side effect.
The researchers hope to test versions of the modified antibiotic in humans as soon as possible.
"If we can eventually prevent people from going deaf from taking these antibiotics, in my mind, we will have been successful," said Anthony Ricci, PhD, professor of otolaryngology-head and neck surgery and co-senior author of the study. "Our goal is to replace the existing aminoglycosides with ones that aren't toxic."
Four years in the making
It took the scientists four years of research to produce 5 grams of the newly patented antibiotic, N1MS, which is derived from sisomicin, a type of aminoglycoside.
N1MS cured urinary tract infection in mice just as well as sisomcicin, but did not cause deafness, study results show. The study presents a promising new approach to generating a new class of novel, nontoxic antibiotics, Ricci said.
The two senior authors -- Ricci and Alan Cheng, MD, associate professor of otolaryngology-head and neck surgery -- joined forces in 2007 to explore the idea of creating new and improved versions of these antibiotics based on a simple yet groundbreaking idea born of Ricci's basic science research into the biophysics of how hearing works within the inner ear.
"It's a nice example of how basic science research is directly translatable into clinical applications," said Ricci.
Ricci is an expert on the process by which sound waves open ion channels within the sensory hair cells of the inner ear, allowing their conversion to electrical signals that eventually reach the brain.
Because aminoglycosides cause deafness by killing these nonregenerating hair cells, Ricci postulated, why not simply make the drug molecules unable to enter the cells' channels?
The idea made sense to Cheng.
"As a clinician-scientist, I treat kids with hearing loss," Cheng said. "When a drug causes hearing loss it is devastating, and it's especially disturbing when this happens to a young child as they rely on hearing to acquire speech.
"When I came to Stanford seven years ago from the University of Washington, I was exploring the angle that maybe we could add drugs to protect the ear from toxicity. Tony brought up this new idea: Why don't we just not let the drug get in? Great idea, I thought. When do we start to work?"
A potent antibiotic
For 20 years, and despite newer, alternative antibiotics, aminoglycosides have remained the mainstay treatment worldwide for many bacterial diseases, including pneumonia, peritonitis and sepsis. They also are often used when other antibiotics have failed to treat infections of unknown origins.
Their popularity is due, in part, to their low cost, lack of need for refrigeration and effectiveness at treating bacterial infections at a time when the declining potency of antibiotics is a major public health concern. They are frequently used in neonatal intensive care units to battle infections, or even the threat of infections, which pose a life-threatening risk for babies. Exactly how many premature babies suffer hearing loss as a side effect of treatment with the drug is unknown, Ricci said.
"The toxicity of these drugs is something we accept as a necessary evil," said Daria Mochly-Rosen, PhD, director of SPARK, a program at Stanford that assists scientists in moving their discoveries from bench to bedside.

Ref : http://dx.doi.org/10.1172/JCI77424

Tuesday, March 17, 2015

Honey offers new approach to fighting antibiotic resistance ............





In continuation of my update on Honey..

Honey, that delectable condiment for breads and fruits, could be one sweet solution to the serious, ever-growing problem of bacterial resistance to antibiotics, researchers said in Dallas* today. Medical professionals sometimes use honey successfully as a topical dressing, but it could play a larger role in fighting infections, the researchers predicted.

"The unique property of honey lies in its ability to fight infection on multiple levels, making it more difficult for bacteria to develop resistance," said study leader Susan M. Meschwitz, Ph.D. That is, it uses a combination of weapons, including hydrogen peroxide, acidity, osmotic effect, high sugar concentration and polyphenols -- all of which actively kill bacterial cells, she explained. The osmotic effect, which is the result of the high sugar concentration in honey, draws water from the bacterial cells, dehydrating and killing them.

In addition, several studies have shown that honey inhibits the formation of biofilms, or communities of slimy disease-causing bacteria, she said. "Honey may also disrupt quorum sensing, which weakens bacterial virulence, rendering the bacteria more susceptible to conventional antibiotics," Meschwitz said. Quorum sensing is the way bacteria communicate with one another, and may be involved in the formation of biofilms. In certain bacteria, this communication system also controls the release of toxins, which affects the bacteria's pathogenicity, or their ability to cause disease.

Meschwitz, who is with Salve Regina University in Newport, R.I., said another advantage of honey is that unlike conventional antibiotics, it doesn't target the essential growth processes of bacteria. The problem with this type of targeting, which is the basis of conventional antibiotics, is that it results in the bacteria building up resistance to the drugs.

Honey is effective because it is filled with healthful polyphenols, or antioxidants, she said. These include the phenolic acids, caffeic acid, p-coumaric acid and ellagic acid, as well as many flavonoids. "Several studies have demonstrated a correlation between the non-peroxide antimicrobial and antioxidant activities of honey and the presence of honey phenolics," she added. A large number of laboratory and limited clinical studies have confirmed the broad-spectrum antibacterial, antifungal and antiviral properties of honey, according to Meschwitz.

She said that her team also is finding that honey has antioxidant properties and is an effective antibacterial. "We have run standard antioxidant tests on honey to measure the level of antioxidant activity," she explained. "We have separated and identified the various antioxidant polyphenol compounds. In our antibacterial studies, we have been testing honey's activity against E. coliStaphylococcus aureus and Pseudomonas aeruginosa, among others."

Friday, March 13, 2015

Can-Fite BioPharma completes RA Phase III study of lead drug candidate CF101



Methyl 1 N6 3 Iodobenzyl Adenin 9 Yl B D Ribofuronamide Drug



Can-Fite BioPharma Ltd.  a biotechnology company with a pipeline of proprietary small molecule drugs that address inflammatory and cancer diseases, announced today that it completed the design of the Rheumatoid Arthritis (RA) Phase III study of its lead drug candidate CF101. Dr. M. Silverman, Can-Fite Medical Director, and Dr. Lee Simon, a key opinion leader in the field of autoimmune inflammatory diseases, designed the Phase III clinical study.

The Phase III study will be a multicenter, randomized, double-blind, placebo-controlled, parallel-group study that will investigate the efficacy and safety of daily CF101 administered orally as a monotherapy for 12 weeks to patients with active RA. The study will have three arms, a 2 mg CF101 dose, a 3mg CF101 dose and placebo, given orally twice daily in the form of tablets. Approximately 300 patients are expected to be enrolled in the study, where sample size for each treatment group will be approximately 100 patients and will provide a statistical power of at least 90%. The study primary end point will be ACR 20 response at Week 12. The A3 adenosine receptor biomarker will be evaluated prior to treatment and its correlation to patients' response to the drug will be analyzed upon study conclusion.

Tuesday, March 10, 2015

Final Phase 1 data of zoptarelin doxorubicin Phase 1/2 trial published in Clinical Cancer Research



Zoptarelin doxorubicin.svg


Aeterna Zentaris Inc. (NASDAQ: AEZS, TSX: AEZ) (the "Company")  announced that an article on final data for the Phase 1 portion of the ongoing Phase 1/2 trial in prostate cancer with zoptarelin doxorubicin (formerly AEZS-108), a hybrid molecule composed of a synthetic peptide carrier and a well-known chemotherapy agent, doxorubicin, has been published in the December issue of Clinical Cancer Research. The article outlines data previously disclosed in June 2013 at the American Society of Clinical Oncology's ("ASCO") Annual Meeting, which demonstrated the compound's safety profile and promising anti-tumor activity in heavily pre‑treated men with castration- and taxane-resistant prostate cancer. These results led to the current investigator-driven Phase 2 portion in this same indication under the supervision of lead investigator, Jacek Pinski, MD, PhD, of the USC Norris Comprehensive Cancer Center. Titled, "Phase I, Dose-Escalation Study of the Targeted Cytotoxic LHRH Analog AEZS-108 in Patients with Castration- and Taxane-Resistant Prostate Cancer", Liu SV, Tsao-Wei DD, Xiong S, Groshen S, Dorff TB, Quinn DI, Tai YC, Engel J, Hawes D, Schally AV, Pinski J., the article is available at this link: Clin Cancer Res.

Sunday, February 1, 2015

SLU researcher discovers new information about how antibiotics stop staph infections


In research published in Proceedings of the National Academy of Sciences, assistant professor of biochemistry and molecular biology at Saint Louis University Mee-Ngan F. Yap, Ph.D., discovered new information about how antibiotics like azithromycin stop staph infections, and why staph sometimes becomes resistant to drugs.

Her evidence suggests a universal, evolutionary mechanism by which the bacteria eludes this kind of drug, offering scientists a way to improve the effectiveness of antibiotics to which bacteria have become resistant.

Staphylococcus aureus (familiar to many as the common and sometimes difficult to treat staph infection) is a strain of bacteria that frequently has become resistant to antibiotics, a development that has been challenging for doctors and dangerous for patients with severe infections.

Yap and her research team studied staph that had been treated with the antibiotic azithromycin and learned two things: One, it turns out that the antibiotic isn't as effective as was previously thought. And two, the process that the bacteria use to evade the antibiotic appears to be an evolutionary mechanism that the bacteria developed in order to delay genetic replication when beneficial.

The team studied the way antibiotics work within the ribosome, the site where bacteria translates the genetic codes into protein. When the bacteria encounter a potential problem in copying its genetic material, as posed by an antibiotic, it has a mechanism to thwart antibiotic inhibition by means of "ribosome stalling" that is mediated by special upstream peptide elements.

Ref  http://www.pnas.org/content/111/43/15379.abstract?sid=94feec3e-058d-4239-97fb-bb9db8f148bb


Friday, January 16, 2015

Cimetidine drug could be one of many common over-the-counter medicines to treat cancer...

Cimetidine2DACS.svg   
We know that, Cimetidine is a histamine H2-receptor antagonist that inhibits stomach acid production. It is largely used in the treatment of heartburn and peptic ulcers. It has been marketed by GlaxoSmithKline (which is selling the brand to Prestige Brands) under the trade name Tagamet (sometimes Tagamet HB or Tagamet HB200). Cimetidine was approved in the UK in 1976 and was approved in the US by the Food and Drug Administration for prescriptions starting January 1, 1979.
Now, it has been concluded that, a popular indigestion medication can increase survival in colorectal cancer, according to research published in ecancermedicalscience. But in fact, scientists have studied this for years - and a group of cancer advocates want to know why this research isn't more widely used.

Wednesday, December 31, 2014

Basilea reports granting of U.S. orphan drug designation to isavuconazole for the treatment of invasive candidiasis



Isavuconazole structure.svg


In continuation of my up date on isavuconazole

Isavuconazole (BAL4815) is an experimental triazole antifungal. Its prodrug, isavuconazonium sulfate (BAL8557) is currently in two Phase III clinical trials (SECURE and VITAL), the results of which are expected in the second half of 2013. 

Basilea Pharmaceutica Ltd. reports today that the U.S. Food and Drug Administration (FDA) has granted orphan drug designation to isavuconazole for the treatment of invasive candidiasis/candidemia, a potentially life-threatening infection caused by Candida yeasts. Isavuconazole has previously been granted orphan drug status in the European Union and the U.S. for the treatment of invasive aspergillosis and mucormycosis.

Wednesday, December 24, 2014

Experimental anti-cancer drugs PF-04691502 and PD-0325901 excel against colorectal cancer models




Genes make proteins and proteins tell your body's cells what to do: one talks to the next, which talks to the next, and to the next. Like a game of telephone, researchers call these  "signaling pathways". Abnormalities in these signaling pathways can cause the growth and survival of cancer cells. Commonly, mutations or rearrangements of genes in the MAPK  signaling pathway create cancer's fast growth, and alterations in the PI3K signaling pathway allow cancer cells to survive into virtual immortality.

Of course, researchers have extensively targeted these two signaling pathways, designing drugs that turn on or off genes in these pathways, thus interrupting the transmission of cancer-causing signals. Unfortunately, these pathways have proven difficult to drug and also it has been difficult to show the effectiveness of drugs that successfully interrupt the transmission of signals along these pathways.

A study by the University of Colorado Cancer Center published in the journal PLoS ONE and concurrent phase I clinical trial is examining a new strategy: targeting both these important cancer-causing pathways simultaneously.

"Well, these two pathways are mutated frequently in cancer. Why not hit both of them? It was as simplistic as that," says Todd Pitts, MS, research instructor in the Program for the Evaluation of Targeted Therapies, and the study's first author.

The study used colorectal cancer tumors grown on mice from samples of patient tumors, called "patient-derived xenograft" models. To these tumors, Pitts and colleagues added the experimental anti-cancer drugs PF-04691502 (left structure) and PD-0325901 (right structure), the first of which mutes a link in the PI3K signaling pathway and the second of which mutes a link in the MAPK signaling pathway. In this case, the combination was greater than the sum of the parts - alone, PF-04691502 and PD-0325901 modestly inhibit the growth and survival of colorectal cancer in these models; after 30-day exposure to the combination, colorectal cancer cells were killed much more effectively than by either drug alone, and even more effectively than if you added together the cells killed by each drug alone.

Friday, December 5, 2014

Chemotherapy drug combined with cancer-killing virus may treat recurrent ovarian cancer



Doxorubicin2DCSD.svg


In continuation of my update on doxorubicin

In six out of 10 cases, ovarian cancer is diagnosed when the disease is advanced and five-year survival is only 27 percent. A new study suggests that a cancer-killing virus combined with a chemotherapy drug might safely and effectively treat advanced or recurrent forms of the disease.

Researchers at The Ohio State University Comprehensive Cancer Center - Arthur G. James Cancer Hospital and Richard J. Solove Research Institute (OSUCCC - James), led the cell and animal study. Reporting in the journal Clinical Cancer Research, the researchers showed that the oncolytic virus called 34.5ENVE has significant antitumor activity against ovarian cancer on its own, and that its activity is even greater when combined with the chemotherapy drug doxorubicin in an animal model of disseminated peritoneal ovarian cancer.

"Our findings suggest that this could be a promising therapy, and we believe it should be further developed for the treatment of recurrent or refractory ovarian cancer in humans," says principal investigator Balveen Kaur, PhD, professor of neurological surgery and an OSUCCC - James researcher.

Among women treated for ovarian cancer whose tumors regress, 70 percent experience recurrence. The recurrent tumors are thought to develop from reserves of cancer stem-like cells that are chemotherapy-resistant and survive therapy. Consequently, recurrent tumors also tend to be resistant to primary chemotherapy regimens, and lethal.

The oncolytic herpes simplex virus 34.5ENVE is engineered to target cancer cells that overexpress the protein nestin and to inhibit the growth of blood vessels to tumors.

Monday, December 1, 2014

New anti-cancer drug may protect normal cells against radiation





Although radiation treatments have become much more refined in recent years, it remains a challenge to both sufficiently dose the tumor while sparing the surrounding tissue. A new anti-cancer drug, already in clinical development, may help address this issue by protecting normal cells - but not the cancer - from the effects of radiation. The research, published November 14th in Molecular Cancer Therapeutics, further suggests this drug may also be useful in treating accidental exposure to radiation.

"It was a stroke of luck that the drug that most effectively protected normal cells and tissues against radiation also has anti-cancer properties, thus potentially increasing the therapeutic index of radiation therapy," says Ulrich Rodeck, M.D., Ph.D., Professor of Dermatology and Cutaneous Biology and Radiation Oncology at Thomas Jefferson University, and senior author on the study.

Together with first author Vitali Alexeev, Ph.D., Assistant Professor, Dermatology and Cutaneous Biology, Dr. Rodeck and colleagues tested five compounds that were shown to have radiation-protective properties in earlier studies. The researchers gave the mice one of the five compounds a day before and for several days after radiation treatment. A compound called RTA 408 emerged from this screen as a robust radiation protector and its effect was comparable to the only drug currently approved by the FDA for that purpose. (The approved drug, called amifostine, however, has a number side effects including severe nausea or vomiting that make it an unappealing choice for clinicians.) Sites that are usually most susceptible to radiation damage including the gut and blood cells in the bone marrow were both protected in mice treated with RTA 408.
Ref : http://mct.aacrjournals.org/content/early/2014/11/12/1535-7163.MCT-14-0354.abstract?sid=22fc8faf-65af-4c60-8a08-265701e2f6ad

Friday, November 21, 2014

FDA Approves Olysio (simeprevir) in Combination with Sofosbuvir for Genotype 1 Chronic Hepatitis C Infection


In continuation of my update on sofosbuvir

Janssen Therapeutics, Division of Janssen Products, LP (Janssen) announced the U.S. Food and Drug Administration (FDA) has approved Olysio (simeprevir), a hepatitis C virus (HCV) NS3/4A protease inhibitor, in combination withsofosbuvir as an all-oral, interferon- and ribavirin-free treatment option for genotype 1 chronic hepatitis C (CHC) infection in adult patients as part of a combination antiviral treatment regimen. Sofosbuvir is an HCV nucleotide analog NS5B polymerase inhibitor developed by Gilead Sciences, Inc.

Thursday, October 30, 2014

VAL-083 drug compound shows promise against non-small cell lung cancer



We know that, VAL-083 is a bi-functional alkylating agent; inhibit U251 and SF188 cell growth in monolayer better than TMZ and caused apoptosis.

DelMar Pharmaceuticals, Inc., (OTCQB: DMPI), a clinical-stage oncology company, today announced the presentation of promising new data supporting the activity of its lead drug compound, VAL-083, in the treatment of non-small cell lung cancer (NSCLC) at the AACR's New Horizons in Cancer Research: Harnessing Breakthroughs – Targeting Cures. The conference takes place October 9th to 12th in Pudong, Shanghai.
"The data presented today showed that VAL-083 is superior to cisplatin in both tumor models that are sensitive and resistant to tyrosine kinase inhibitors and has synergistic effect in combination with cisplatin," said Jeffrey Bacha, president and CEO of DelMar Pharmaceuticals. "This data suggests important clinical and market potential of VAL-083 in non-small cell lung cancer."

DelMar's lead clinical compound, VAL-083 (dianhydrogalactitol) is a first-in-class alkylating agent with a novel cytotoxic mechanism distinct from other alkylating agents used in the treatment of cancer.

In historical studies sponsored by the National Cancer Institute in the United States, VAL-083 exhibited clinical activity against a range of tumor types including CNS tumors, solid tumors and hematologic malignancies. VAL-083 is approved in China for the treatment ofchronic myelogenous leukemia (CML) and lung cancer (Approval No. Guoyao Zhunzi H45021133; manufactured by Guangxi Wuzhou Pharmaceutical (Group) Co. Ltd.)

NSCLC is usually treated with either tyrosine kinase inhibitors (TKIs) (e.g. gefitinib) or platinum-based regimens (e.g. cisplatin). TKIs have resulted in vastly improved outcomes for patients with EGFR mutations; however, TKI resistance has emerged as a significant unmet medical need, and long-term prognosis with platinum-based therapies is poor. Compared to other countries, Asian patients with NSCLC have a higher incidence of EGFR mutations (up to 60 percent; compared to 10-20 percent in Western populations) and are more susceptible to TKI resistance.

Additionally, NSCLC patients have a high incidence of brain metastases, which is associated with a poor prognosis. The median overall survival time for patients with stage IV NSCLC is four months, while one-year and five-year survival is less than 16 percent and 2 percent, respectively. VAL-083 can cross the blood-brain barrier and is currently being evaluated in the United States in a Phase 1/2 clinical trial to treat the most common form of brain cancer, glioblastoma multiforme (GBM).