Global report on antimicrobial resistance
In 2014, the World Health Organization announced the results of its first global report on antimicrobial resistance, including antibiotic resistance. They say that antibiotic resistance is happening right now in every region of the world.
Washing hands
Washing hands is an important part of preventing the spread of cold and flu viruses.
One day soon, common infections and minor injuries that have been treatable for decades may be able to kill again – as they did before the discovery of antibiotics.
In early May 2014, the World Health Organization (WHO) announced the results of its first global report on antimicrobial resistance, including antibiotic resistance. They say that antibiotic resistance is happening right now in every region of the world and has the potential to affect anyone of any age in any country.
Examples of bacterial resistance
The extensive report incorporated data from 114 countries and looked at resistance to treatment for a range of illness-causing bacteria. Among the key findings were that resistance to carbapenem antibiotics, the treatment for life-threatening infections caused by the common intestinal bacterium Klebsiella pneumoniae, has spread to all regions of the world.
K. pneumoniae causes hospital-acquired infections such as pneumonia, bloodstream infections, infections in newborns and intensive-care unit patients. According to the report, carbapenem antibiotics would no longer work in more than half of people treated for K. pneumoniae infections in some countries.
Resistance to fluoroquinolones, for the treatment of urinary tract infections caused by Escherichia coli, is also widespread. When fluoroquinolones were introduced in the 1980s, resistance was virtually zero. However, there are now countries where treatment is ineffective in more than half of patients.
Escherichia coli bacteria
Escherichia coli (E. coli) is a rod-shaped bacterium that lives in the gut of warm-blooded animals. It is a crucial tool in modern biotechnology and often used in molecular biology laboratories due to its ease of culture and rapid growth. Scientists use E. coli to work with DNA and proteins from other organisms. It is a normally harmless bacteria that lives in the lower intestine though some strains of this bacterium can cause infection of the intestine, urinary tract and other parts of the body.
In the early 1990s, ciprofloxacin (a fluoroquinolone) and cephalosporins were the usual treatments for the sexually transmitted disease (STD) gonorrhea, caused by infection with the Neisseria gonorrhoeae bacterium. By then, the bacterium had already developed resistance to penicillin and tetracyclines. Alarmingly, by the late 1990s, the bacteria were developing increasing ciprofloxacin resistance around the world, and by the mid to late 2000s, cephalosporins were the only remaining recommended treatments in most countries.
Now, worryingly, the WHO has reported treatment failures to third-generation cephalosporins in Austria, Australia, Canada, France, Japan, Norway, South Africa, Slovenia, Sweden and the United Kingdom. The latest available statistics from WHO for infection rates estimated that there were 106 million new cases of gonorrhea worldwide in 2008 – unless new treatments are developed, it may soon be untreatable.
“A world without antibiotics is a scary place”
Microbiologist Dr Siouxsie Wiles at the University of Auckland says that the latest estimates put the number of potential antibiotic resistance genes that exist at more than 20,000. “But it doesn’t end there, microbes have crafty ways in which they can share resistance genes between themselves, and this has exacerbated the problem.”
Dr Wiles says the WHO report highlights what microbiologists have been shouting for a while now, “that a world without antibiotics is a scary place, and we are likely to be living in that world in as little as 10 years … It is clear that we need novel ways to tackle infectious microbes.”
A need for more research to develop new approaches
Professor Nigel Brown, President of the Society for General Microbiology in the UK, says that, while the WHO report is right to raise the importance of good surveillance data, if we are to understand the extent of antimicrobial resistance, scientific research, rather than more data, is the solution to the problem.
“It is vital that microbiologists and other researchers work together to develop new approaches to tackle antimicrobial resistance. These approaches will include new antibiotics but should also include studies to develop new rapid-diagnostic devices, fundamental research to understand how microbes become resistant to drugs and how human behaviour influences the spread of resistance.”
Household products may be part of the problem
In terms of ongoing human behaviour, Dr Sally Gaw, the Director of Environmental Science at the University of Canterbury, commented that the use of household products containing antimicrobial agents such as triclosan and triclorban may also contribute to the development of antibiotic-resistant bacteria. “These antimicrobial agents can be found in soaps, deodorants, toothpaste, kitchenware, sportswear and children’s toys. These chemicals are released into the environment via discharges from sewage treatment plants. There is growing evidence that widespread domestic use of antimicrobial compounds is contributing to the development of antibiotic resistance in bacteria in the environment. Soaps containing triclosan have been shown to be no more effective at controlling illness in people’s homes than ordinary soap. The domestic use of antimicrobial agents needs to be reassessed to ensure that these products do not reduce the effectiveness of medical treatment. Our obsession with killing germs may actually be putting people’s lives at risk.”
In general, people with antibiotic-resistant strains of infections of any bacteria tend to be sick for longer, often require hospitalisation and are at increased risk of death. For example, people with MRSA (methicillin-resistant Staphylococcus aureus), which is an increasing issue in New Zealand, are reported to be 64% more likely to die than people with a non-resistant form of the infection.
The report also includes information on resistance to medicines for treating other infections such as HIV, malaria, tuberculosis and influenza.
Related content
Find out more in the articles Antibiotic resistance explained and Is the post-antibiotic era now here?
Learn more about the history of antibiotics and antimicrobial resistance with this article and timeline. Find out what you can do to reduce the risk. The context for learning provides ideas on how to incorporate this wicked problem into authentic cross-curricular learning.
Help the Infection Inspection citizen science project develop a faster test for antibiotic resistance by using your observation skills to identify bacteria that have been impacted by antibiotics.
Useful links
There are lots of resources and information on the World Health Organization website under the topic antimicrobial resistance.
Royal Society Te Apārangi has produced a series of articles and videos about antimicrobial resistance, including the te reo Māori resource He uaua ake te rongoā i ngā whakapokenga ātete rongoā.
Find out more about the Infectious disease and antimicrobial resistance report from The Office of the Prime Minister's Chief Science Advisor released in March 2022. There are a series of recommendation under six themes to help Aotearoa New Zealand unite against the threat of infectious disease and antimicrobial resistance.
The Ministry of Health has information and links on its website – Resources for antibiotic awareness.
Listen to Dr Siouxsie Wiles as she discusses the rise of resistant superbugs in this Radio New Zealand interview.
Watch antibiotic resistance evolve in this video from Harvard Medical School.
References
World Health Organization. (2014). Antimicrobial resistance: global report on surveillance 2014. ISBN: 978 92 4 156474 8. Retrieved 14 June 2014.
