Action is needed to stop most powerful treatments in modern medicine from becoming ineffective
| FREDDY ERIC KITUTU | Even before the COVID crisis, excessive use and misuse of lifesaving antibiotics had contributed to the emergence of resistant strains of disease-causing organisms. This has rendered many of the most powerful treatments in modern medicine ineffective.
It’s estimated that drug-resistant infections caused more than 1.2 million deaths in 2019. That is more than malaria and AIDS combined. And resistance contributed to about 5 million additional deaths.
A study published this January in the medical journal The Lancet found an estimated 4.95 million deaths associated with bacterial AMR in 2019, including 1.27 million deaths attributable to bacterial AMR.
The authors of the study entitled: “Global burden of bacterial antimicrobial resistance in 2019: a systematic analysis” estimated the all-age death rate attributable to resistance to be highest in western sub-Saharan Africa, at 27.3 deaths per 100 000.
Lower respiratory infections accounted for more than 1.5 million deaths associated with resistance in 2019, making it the most burdensome infectious syndrome. The six leading pathogens for deaths associated with resistance (Escherichia coli, followed by Staphylococcus aureus, Klebsiella pneumoniae, Streptococcus pneumoniae, Acinetobacter baumannii, and Pseudomonas aeruginosa) were responsible for 929 000 deaths attributable to AMR and 3.57 million deaths associated with AMR in 2019.
One pathogen–drug combination, meticillin-resistant S aureus, caused more than 100 000 deaths attributable to AMR in 2019, while six more each caused 50 000–100 000 deaths: multidrug-resistant excluding extensively drug-resistant tuberculosis, third-generation cephalosporin-resistant E coli, carbapenem-resistant A baumannii, fluoroquinolone-resistant E coli, carbapenem-resistant K pneumoniae, and third-generation cephalosporin-resistant K pneumoniae.
There’s some evidence that the COVID-19 pandemic made matters worse. COVID-19 can create a perfect storm for AR infections in healthcare settings: increased length of stay, increased number of patients, staffing shortages, sick patients, antibiotic use, challenges implementing infection prevention and control.
COVID-19 is caused by a virus. And viruses are not treated with antibiotics. But early treatment guidelines for COVID-19 assumed that patients admitted to hospitals would develop bacterial superinfections that required antibiotics. The sheer volume of people who were sick with respiratory infections also seemed to encourage additional use of antimicrobial drugs.
Antimicrobials are drugs that treat bacterial, viral or other microbial infections. Antimicrobial resistance, the drop in effectiveness of this broader class of drugs, is a broader term, encompassing resistance to drugs to treat infections caused by other microbes as well, such as parasites (e.g. malaria), viruses (e.g. HIV) and fungi (e.g. Candida). Antimicrobial resistance was already a rising threat to global public health before the outbreak of COVID-19 in December 2019.
In general, sub-Saharan Africa suffers from the highest rate of drug resistance-related deaths. But the prevalence varies by country.
A recent research set out to document the magnitude of antimicrobial use, a known driver of antimicrobial resistance, in selected healthcare facilities in Uganda.
The `Point Prevalence Survey of Antibiotic Use across 13 Hospitals in Uganda’ was done by Dr. Reuben Kiggundu and others from Management Sciences for Health (MSH) in Kampala, the USAID Medicines, Technologies, and Pharmaceutical Services (MTaPS), the School of Pharmacy, University of Washington, and the Department of Pharmaceuticals and Natural Medicines in the Ministry of Health.
They found a high use of antibiotics across all surveyed health facilities. And compliance to Uganda’s clinical guidelines among healthcare workers was low. Also, men were more likely to be on antibiotics than women. In addition, antibiotic use was two times higher in public health facilities than in the private sector. But this could be attributed to the higher proportion of public healthcare facilities in our study sample.
The study results highlight areas for intervention to address antimicrobial resistance. These findings also provide a baseline against which we can compare the impact of such interventions.
Trends in antibiotic use
The researchers surveyed antibiotic use in 13 hospitals in Uganda. Their analysis included nearly 1,100 patients and was done between December 2020 and April 2021.
Nearly three-quarters of all patients in their study were taking at least one antibiotic. This is high and could indicate overuse, some of which may be unnecessary. In addition less than 30% of the antibiotic prescriptions complied with Uganda’s clinical guidelines for choice of drugs.
Ceftriaxone is a drug used to manage a wide range of infections. It was among the most prescribed antimicrobials. But it’s not recommended for first-line use. A possible explanation for this is convenience and ease of its use as compared to the current first-line medicines.
In a first, the researchers looked at differences in antibiotic use among males and females as a preliminary indication of gender differences in adequate access to antibiotics. They found that men had 15% greater odds of antibiotic use. Reasons for this observation were not obvious. But other studies have attributed it to differences in access to healthcare between men and women. In those studies, boys were more likely to take antimicrobials for longer periods and to complete the regimen.
They also found antibiotic use substantially higher in public and nonprofit hospital settings compared with private ones. This contradicts our expectations that the profit motive typically drives the overuse of antibiotics in private hospitals and should be examined further.
The researchers say they are concerned about the observed levels of use of antibiotics in Uganda. Efforts to examine whether this use is appropriate or necessary or not are compromised by inadequate patient record systems and diagnostic capacity. Proper and complete patient records and diagnostic capacity are the minimum requirements for the desired antimicrobial consumption and use surveillance. And for better quality of healthcare in these healthcare facilities.
On a positive note, Uganda has been strengthening the antibiotic consumption and use surveillance system and health facility diagnostic capacity at higher levels. Efforts are being made to address policy gaps, and training of healthcare workers at both undergraduate and graduate levels.
The researchers say their findings should be used to accelerate implementation of ongoing strategies to reduce misuse of medicines, and guide research in other sub-Saharan countries.
Recommendations
They say what’s needed next are sustained investments from government and development partners. Here are a few places they proposed to start:
- Invest in new, better, and easier-to-administer single-dose antibiotics that target a narrow range of bacteria, known as narrow spectrum antibiotics. So-called broad spectrum antibiotics are associated with more resistance. This will enable health workers to treat infections better and comply with guidelines.
- Improve laboratory infrastructure and technologies. Clinicians must be able to identify the microorganism that caused the infection, so they can choose the appropriate antimicrobial to administer. Current capacity for diagnosing bacterial infections in Uganda is minimal. The Alliance for the Prudent Use of Antibiotics APUA in 2011 carried out a study in Uganda and produced a report in which 29 laboratories in Uganda were surveyed to examine their capacity to reliably provide clinical diagnostics, perform antibiotic sensitivity testing and transmit the data to be used by policy makers for clinical management and decision making. The laboratories were examined on their ability to detect pathogens and perform sensitivity testing, systems for quality control, mechanisms for dissemination of laboratory/surveillance data, systems for collection, analysis and transmission of the data to be used for antibiotic management decisions, to deliver accurate results, and availability and use of the WHONET software for antimicrobial resistance surveillance.
- The study found that the laboratory capacity to conduct sensitivity testing was poor and only a few facilities were able to provide routine clinical diagnostics and sensitivity testing.
- Strengthen the health workforce with more staff and training in infection prevention and control. Better infection control will reduce the incidence of bacterial infections, hence reduced need for antibiotic use.
- Implement and enforce policies on the use of antibiotics including proper patient record keeping which can act as an indirect force to improve quality of healthcare. Lessons for proper patient record systems use can be borrowed from the health insurance industry.
Uganda is only one country that needs to improve its stewardship of antimicrobial resistance. Without a coordinated global response, drug-resistant infections will cost the global economy US$100 trillion in economic output by 2050, and lead to more disease and mortality than all noncommunicable diseases combined.
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Freddy Eric Kitutu is Senior Lecturer of Health Systems Pharmacy and Researcher, Makerere University
Source: The conversation. This article was re-written for length.
Antibiotic use
This is a great detailed writing that calls for self reflection:
How we move in circles?
at the begginong of a career, we had prescription of antibiotic being supervised by seniours, they were available and took prompt action, they were trying to protect dear ampicillin and her cousin septrin and restricting use of chloramphenicol!
On admission, we took samples to the laboratory and by the ward round next day results were available to guide subsequent treatment.
In control of my memory today, I do not recall prescribing drugs for patient to purchase
The drugs were only accessible to registered practioner in private practice
Privy to the APUA findings Uganda was compared with Zambia using a similar tool
One of the actions for mitigation should be a review of what has changed
When it comes to recommendations, the laboratories are implementing activity as planned by the region, how does Uganda compare at the level of investigation of infections?
In the early days of the HIV/AIDS epidemic, there was an attempt to implement infection control activity, then what happened?
Last but not least, it is on such a day that a resource that significantly complements clinicians is requesting for recognition, to be facilitated (reasonable salary) as an attempt to sustain service.
Hello Kankomibii,
You express some fascinating ideas.
We could talk about these further; I’d like to hear more about the evolution in practice that you mention briefly. Thank you ahead of time.
I cannot seem to find your contact. However, you can be reached on dickson.aruhomukama@mak.ac.ug
Excellent
Great writing and we look forward to implementation
BUT
If we have minimal diagnostic capacity
How do we determine the causative agent of an infection in an individual patient?
Then resort to targeted therapy using a narrow spectrum agent?
The clinicians must know the causative agent:
Well this agent comes from a sample that represents the disease process; a story from a patient, who then gets examined, a sample is collected and investigated
Status quo; we have a blood picture being used to predict a bacterial infection!
Nay
It should be present, isolated in pure form or presence of its components confirmed
Behold
It’s presence necessitates a subsequent probing, which antibiotic can handle you dear bug?
The findings inform immediate care, planning and control of use
So let the public know that there is a problem becoming worse
It needs to be stopped
But the message to the public should be in the language they understand by messengers that they believe in
Ceftriasone is highly resisted by N Gonorea ,now what the govt is going to do to solve this problems?