Antibiotics are powerful medicines that fight bacterial infections. They either kill bacteria or stop them from reproducing, allowing the body’s natural defenses to eliminate the pathogens. Used properly, antibiotics can save lives. But growing antibiotic resistance is curbing the effectiveness of these drugs. Taking an antibiotic as directed, even after symptoms disappear, is key to curing an infection and preventing the development of resistant bacteria. Show
Antibiotics don’t work against viral infections such as colds or the flu. In those cases, physicians often prescribe antiviral drugs, which fight infection by inhibiting a virus’s ability to reproduce. There are several different classes of drugs in the antiviral family, and each is used for specific kinds of viral infections. (Unlike antibacterial drugs, which may cover a wide spectrum of pathogens, antiviral medications are used to treat a narrower range of organisms.) Antiviral drugs are now available to treat a number of viruses, including influenza, human immunodeficiency virus (HIV), herpes, and hepatitis B and C. Like bacteria, viruses mutate over time and develop resistance to antiviral drugs. Modern medicine needs new kinds of antibiotics and antivirals to treat drug-resistant infections. But the pipeline of new drugs is drying up. The last new class of antibiotics to be approved was the lipopeptides (e.g., daptomycin) discovered in 1987. Major pharmaceutical companies have limited interest in dedicating resources to the antibiotics market because these short-course drugs are not as profitable as drugs that treat chronic conditions and lifestyle-related ailments such as high blood pressure or high cholesterol. Antibiotic research and development is also expensive, risky, and time consuming. Return on that investment can be unpredictable, considering that resistance to antibiotics develops over time and eventually makes them less effective. New antiviral drugs are also in short supply. These medicines have been much more difficult to develop than antibacterial drugs because antivirals can damage host cells where the viruses reside. Today, there are more antiviral drugs for HIV than for any other viral disease, transforming an infection that was once considered a death sentence into a manageable chronic condition. But novel drugs are needed to combat other epidemic viral infections such as influenza and hepatitis B. Several programs have been developed to stimulate research and development of new vaccines and medicines. In 2007, the U.S. Department of Health and Human Services formed the Biomedical Advanced Research and Development Authority, which provides an integrated, systematic approach to the development and purchase of the vaccines, drugs, therapies, and diagnostic tools necessary for public health medical emergencies. This group has supported the development of several treatments and vaccines. The Cures Acceleration Network (CAN) provision of the Patient Protection and Affordable Care Act, signed into law by President Obama in March 2010, is designed to move research discoveries through to safe and effective therapies by awarding grants through the National Institutes of Health (NIH) to biotech companies, universities, and patient advocacy groups. In 2012, CAN was moved to the newly authorized National Center for Advancing Translational Sciences (NCATS) within the NIH. CAN continues to explore ways to accelerate the movement of “high-need cures,” including drugs, from the bench to the bedside. And nonprofit organizations dedicated to accelerating the discovery and clinical development of new therapies to treat infectious diseases are bringing together philanthropists, medical research foundations, industry leaders, and other key stakeholders to forge effective collaborations. Along with efforts to develop new vaccines and medicines, increased vigilance is needed to reduce the overall use of antibiotics. This can be accomplished by reducing infections that lead to the need for antibiotics in the first place. Increasing vaccination rates and improving sanitation and the availability of clean water worldwide are three effective ways to realize this goal. Other strategies include avoiding antibiotic use for growth promotion in animals and restricting the use of medically important drugs across the board, in both humans and animals. Polices that support these strategies and restrict overall use should prolong the effectiveness of antibiotics.
Healthcare professionals are always keen to stress that antibiotics are ineffective against viral infections, with some rare exceptions. Antibiotics have saved the lives of millions of people since they came into widespread use early in the 20th century, but overuse accelerates the evolution of bacterial resistance to the drugs. According to the Centers for Disease Control and Prevention (CDC), there are more than 2.8 million cases of antibiotic-resistant infection and 35,000 resulting deaths annually in the United States alone. Therefore, there are serious concerns that overprescribing antibiotics to patients with COVID-19 — in the absence of any evidence of a bacterial coinfection — promotes the spread of antibiotic resistance. In the United Kingdom, the National Institute for Health and Care Excellence reports that under 8% of people hospitalized with COVID-19 also have a bacterial infection. But one study in the U.K. found that around 85% of COVID-19 patients receive treatment with an antibiotic during their hospital stay. During the pandemic, there had been early hopes that the antibiotic azithromycin might be an effective treatment for COVID-19. However, a recent Cochrane review of clinical trials found no evidence for this. So the findings of a small study that suggests either of two antibiotics, in combination with the steroid dexamethasone, may be an effective treatment for the disease are controversial. The study involved 370 patients with moderate or severe COVID-19 who were admitted to Beni-Suef University Hospital in Beni Suef, Egypt. Researchers randomly assigned the patients to three groups:
The mean recovery time for patients receiving treatment with cefepime or ceftazidime was 12 days and 13 days, respectively, while the mean recovery time with standard treatment was 19 days. The researchers emphasize that the study was not a clinical trial and that there were insufficient numbers of patients in each group to draw firm conclusions. However, they also conducted lab tests and computer simulations, which suggested that these two antibiotics inhibit the activity of a protease enzyme called Mpro. Mpro is an important part of a virus’s life cycle — a reduced activity of the enzyme impairs the replication rate of the virus. The study appears in the journal Antibiotics. Cefepime and ceftazidime are broad-spectrum, beta-lactam antibiotics in the class known as cephalosporins. Both are on the WHO’s AWaRe watchlist, meaning there is a high potential for bacteria to develop resistance to them. However, in their paper, the researchers argue that using existing antibiotics with proven antiviral potential against COVID-19 could actually delay the emergence of antibiotic resistance. Ahmed M. Sayed, Ph.D., a pharmacist at Nahda University in Beni Suef and one of the authors, told Medical News Today that using antibiotics that have both antiviral and antibacterial effects could avoid resistance to other antibiotics. “Usually, upper respiratory tract viral infections are associated with secondary bacterial infections that need antibiotics coverage,” said Dr. Sayed. “Accordingly, if we use only a certain set of broad-spectrum antibiotics — that have additional antiviral potential like the two studied antibiotics in our article — in such types of infections, we will save, to some extent, other essential antibiotics from the rapid development of bacterial resistance, and speed up the patient’s recovery rate,” he explained. He argued that using the full arsenal of antibiotics against bacterial coinfections will make these other drugs more ineffective. In contrast, drugs, such as cefepime and ceftazidime, which may have multiple therapeutic benefits, could reduce the number of other necessary treatments and their associated side effects. The authors acknowledge that their study only involved a single hospital and was too small to draw firm conclusions. “Of course, the study needs a much higher number of patients to get more solid results,” said Dr. Sayed. He said they are planning a multisite clinical trial of these antibiotics that will involve a larger number of patients and be more likely to provide statistically significant findings. In their paper, the researchers also note that their computer simulations and lab results could provide helpful leads for designing more potent antiviral drugs that target the Mpro enzyme of SARS-CoV-2. For live updates on the latest developments regarding the novel coronavirus and COVID-19, click here. Can antiviral and antibiotic be taken together?Compared with patients prescribed only an antiviral, patients who are prescribed both an antiviral and an antibiotic have a lower risk for 3-day respiratory hospitalization, according to a study published in Clinical Infectious Diseases.
Can I take valacyclovir with antibiotics?Interactions between your drugs
No interactions were found between amoxicillin and valacyclovir. However, this does not necessarily mean no interactions exist. Always consult your healthcare provider.
How do antibiotics and antivirals work?An antibiotic can usually treat many different types of bacterial infections. But the drugs do not affect viruses. Each antiviral only works against a specific virus. Because viruses inside cells are harder to target, antiviral drugs are more challenging to develop.
Can I take amoxicillin with acyclovir?Interactions between your drugs
No interactions were found between acyclovir and amoxicillin. However, this does not necessarily mean no interactions exist. Always consult your healthcare provider.
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Can i take antibiotics and antivirals at the same time
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