Why Public Health Depends Upon Antimicrobial Stewardship

Public health is facing a looming crisis. However, unlike many more obvious public health emergencies, the majority of us may not recognize or realize the culprit: antimicrobial resistance. As hundreds of thousands of patients come face-to-face with health issues related to antibiotic-resistant infections, the scientific community must address the significance of antimicrobial stewardship and its core principles.

What is antimicrobial stewardship?

According to the Centers for Disease Control and Prevention (CDC), antimicrobial stewardship is the endeavor to measure and improve how antibiotics are prescribed and used in a healthcare setting.1 This type of conservancy creates an innovative approach to identifying the critical and complex need for antibiotic therapies, while measuring the outcome to prevent misuse or overuse of antibiotics.

While antibiotics are prescribed to fight bacterial infections, the CDC reports approximately 30% of all antibiotics prescribed to acute care patients in the United States are not necessary in the progression of treatment.2 Overuse of antibiotics has led to an increase in antimicrobial resistance, which has been identified as a serious ongoing threat to public health.

Who was Sir Alexander Fleming, and how did he contribute to antimicrobial stewardship?

In 1928, Scottish scientist Sir Alexander Fleming made his monumental discovery of penicillin while experimenting with staphylococcal bacteria.3 Quite by accident, he found one of his uncovered agar plates had become contaminated with mold spores, and bacteria surrounding the mold growth were inhibited. He later identified the mold as a member of the Penicillium genus and began to perform further experiments to determine the inhibitory agent. The agent, now termed penicillin, was later found to fight against bacteria that cause diseases such as pneumonia, meningitis and scarlet fever.3

Fleming’s findings did not catch on quickly, as it took more than a decade from the time of his publications for the scientific community to embrace penicillin. It was scientists Howard Florey and Ernst Chain who wanted to use penicillin as a treatment for soldiers during World War II.3 After mass production and successful use of penicillin throughout the war, Fleming was ultimately awarded the Nobel Prize for Physiology/Medicine in 1945.3

What we now refer to as antimicrobial resistance was first addressed by Fleming during a 1945 interview with the New York Times.  While noting the importance of an antibiotic, such as penicillin, he also warned about the abuse of such a critical discovery, “In such cases, the thoughtless person playing with penicillin is morally responsible for the death of the man who finally succumbs to infection with the penicillin-resistant organism. I hope this evil can be averted.”4 As if on cue from Fleming’s ominous prediction, just ten years into its widespread use, penicillin resistance began to emerge.

Rising resistance

During the past few decades, many strains of bacteria have evolved resistant to antibiotics. Infectious bacteria are much harder to control than their predecessors were ten or twenty years ago.

The uptick in multi-drug resistant organisms (or MDROs) has resulted in the magnification of hospital-acquired infections (HAI) and a decrease in antibiotic efficacy against certain microorganisms. These consequences bring complexities to medical decisions regarding patient treatment and patient management. MDRO diagnosis in a hospital or long-term care setting requires additional controls, patient isolation, often-prolonged patient hospitalization, and the use of last-line-of-defense treatments, which bring even further risk. While the pace of antibiotic discovery was stunted in the early 2000s, there has been an uptick of new broad spectrum antibiotics approved by the FDA within the last ten years geared toward MDROs such as Ceftolozane/Tazobactam, Ceftazidime/Avibactam, Meropenem/Vaborbactam, Delafloxacin, Plazomycin, Omadacycline, Eravacycline, Lefamulin, Imipenem/Relebactam, and Cefiderocol. In order to confront the matter of the escalation of antimicrobial resistance, hospitals and medical staff must establish procedures in correlation to an antimicrobial stewardship mindset.

How hospitals and clinicians can help

Saving patients from contracting resistant organisms must start with initiating the development of an antimicrobial stewardship group within the facility. There are several elements needed of an effective infection prevention team: leadership, accountability, drug expertise, action, tracking, reporting and education.7 These key points encompass the mission of antimicrobial stewardship.

Leadership comes first in the medical institution by simply incorporating an antimicrobial stewardship standard of duty in professional job descriptions, exhaustive stewardship training, and contractual obligations required by those positions. With that principle at the foundation, accountability follows by forming policies to support antibiotic use, requiring interventions with certain prescriptions, and reassessment by a subject matter expert (i.e. pharmacists, clinicians, etc.).

The action comes when policies are implemented into the daily course of action, and are enforced when an “antibiotic time-out” must occur to reassess the most fitting treatment for the patient. As the strategy for preserving antibiotic stewardship is solidified, it can be tracked through documentation, noting dosage, duration and indication before reporting information. All of these steps ultimately help achieve a successful antimicrobial stewardship program, which is the core consensus of the process.

Hardy Diagnostics’ role in the fight against antimicrobial resistance

Patient health is our priority. We know antimicrobial resistance is on the rise. We also know that our company can and has made a difference by focusing on detection, identification and diagnosis to assist laboratorians and physicians keep patients safe and healthy. Because we know that public health is facing this threat on an evolutionary scale, Hardy Diagnostics continues to strive to set a standard of antimicrobial stewardship through leadership, accountability, expertise, research, education and action. Reducing the flow of resistant genes among pathogenic bacteria and developing new treatments for future generations is key to this fight.

In 1996, Hardy Diagnostics became the first manufacturer to introduce chromogenic prepared culture media to the United States. Since then, Hardy continues to expand its line of chromogenic media to aid in the detection of resistant strains by creating media such as: HardyCHROM™ ESBL (extended spectrum β-lactamases); HardyCHROM™ CRE (carbapenem resistant Enterobacterales); and HardyCHROM™ MRSA  (methicillin-resistant Staphylococcus aureus).

Additionally, Hardy has been offering an array of products focused on promoting antimicrobial stewardship, from environmental monitoring to patient management, including culture media and rapid identification tests targeted at detection and effective treatment.

HardyCHROM™ MRSA

Studies show 33% of the population carry S. aureus as part of their microbiome. Furthermore, the CDC estimates two out of every 100 people routinely carry MRSA, most commonly in their anterior nares.8 Though most do not develop a serious infection, the potential to transmit MRSA to other patients in a healthcare setting is significant. Over the past five decades, the CDC has engaged in surveillance of HAI using a combination of voluntary reporting and a national system of sentinel hospitals. HardyCHROM™ MRSA can be used in that capacity, and is recommended for the qualitative detection of nasal colonization by MRSA to aid in the prevention and control of this organism.

HardyCHROM™ ESBL

Regarding the Gram negative organisms, ESBLs are enzymes produced by certain Enterobacterales that can break down and destroy commonly used antibiotics, such as broad spectrum penicillins or cephalosporins, making these drugs ineffective in treating infections. These mechanisms of resistance have been around for some time, first emerging in the medical literature as a β-lactamase (narrow spectrum) identified in Escherichia coli even prior to the medical use of penicillin.10 However, the number of known β-lactamases has quickly grown and, being plasmid and transposon mediated, they’ve spread rapidly worldwide. These mechanisms of resistance have broadened to new enzymes capable of hydrolyzing newer β-lactam antibiotics, leaving very few remaining effective antibiotic treatment options available for patient care. HardyCHROM™ ESBL can aid in the detection of these microorganisms. The medium is intended for the qualitative and presumptive detection of Enterobacterales potentially non-susceptible to broad spectrum cephalosporins, and ESBL-producing E. coli, Klebsiella pneumonia, and K. oxytoca from stool.

NG-Test® CARBA 5

Carbapenem antibiotics are one of the few remaining antibiotics effective in treating ESBL infections or MDRO.9 However, carbapenemases, or enzymes produced by bacteria that cause resistance to this class of antibiotics, are also on the rise. NG-Test® CARBA 5 is a rapid, multiplex, phenotypic lateral flow confirmatory test for the qualitative detection of five common carbapenemases produced by Enterobacterales and Pseudomonas aeruginosa: KPC, OXA-48-like, VIM, IMP, and NDM, that can be used with colonies that screen positive via HardyCHROM™ CRE. CARBA 5 is a game-changer in effective patient management, allowing clinicians a clear and rapid understanding of which drugs will benefit patient treatment from those that will not. This allows for better outcomes and more cost-effective care, better control over potential HAI, and aids in the principals of antimicrobial stewardship.

Additional lateral flow format detection devices (NG-Test® MCR-1 and NG-Test® CTX-M MULTI), both labeled for Research Use Only.

Hardy is expanding the diversity of antimicrobial resistance tests to include NG-Test® MCR-1, to detect the colistin resistance gene mcr-1, and NG-Test® CTX-M MULTI, to detect CTX-M variants when an ESBL is suspected, though both products are labeled for Research Use Only as of now. NG-Test® MCR-1 is a rapid immunoassay designed to detect the colistin resistance gene mcr-1 from bacterial colonies. The MCR (mobilized colistin resistance) gene family— mcr-1, mcr-2, and mcr-3—are an emerging AMR threat. These genes confer plasmid-mediated resistance to colistin (polymyxin E), known as one of the last-line antibiotics for treating patients infected with multi-drug resistant Enterobacterales.  NG-Test® CTX-M MULTI is to detect CTX-M variants in bacterial colonies when an ESBL is suspected. Currently, more than 170 CTX-M variants have been identified and are presently the most widespread resistance enzymes of clinical significance. All plasmid-mediated types of resistance are easily transferable within hospitals and in the community. Identifying CTX-M ESBLs early is crucial for preventing spread of resistance genes. Although ESBLs are less common in the U.S. compared to other regions in the world, NG-Test® CTX-M MULTI is useful in cases where hospitals have a higher CTX-M prevalence within the institution or in the immediate community, as it would provide a more rapid and cost-effective tool compared to molecular detection methods.

Here at Hardy Diagnostics, we take our mission statement to heart: “We are committed to producing and distributing the finest products for the detection of microorganisms, as we partner with our laboratory customers to diagnose and prevent disease.” Hardy Diagnostics pledges to continue to do its part to provide innovative solutions to promote antimicrobial stewardship.

By:
Kelly Brickey, Digital Marketing Specialist
Daniel Ballew, Marketing Manager
Megan Roesner, Clinical Marketing Coordinator
Kerry Pierce, M.S., RM(NRCM), Design and Development Specialist
Andre Hsiung, M.S., M(ASCP), Chief Scientific Officer

References

  1. “Core Elements of Antibiotic Stewardship | Antibiotic Use | CDC.” Centers for Disease Control and Prevention, 2019, https://www.cdc.gov/antibiotic-use/core-elements/index.html.
  2. “Core Elements of Hospital Antibiotic Stewardship Programs | Antibiotic Use | CDC.” Centers for Disease Control and Prevention, 2019, https://www.cdc.gov/antibiotic-use/core-elements/hospital.html#.
  3. Tan, MD, JD, Siang Yong, and Yvonne Tatsumura, MA, MD. “Alexander Fleming (1881–1955): Discoverer of Penicillin.” PubMed Central (PMC), Singapore Med J, July 2015, https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4520913/.
  4. Rosenblatt-Farrell, Noah. “The Landscape of Antibiotic Resistance.” PubMed Central (PMC), Environment Health Perspectives, June 2009, https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2702430/.
  5. Doron, MD, Shira, and Lisa Davidson, MD. “Antimicrobial Stewardship.” PubMed Central (PMC), Mayo Clinic Proceedings, Nov. 2011, https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3203003/#R1.
  6. “CRE Bacteria: What You Should Know – Mayo Clinic.” Mayo Clinic, Mayo Clinic, 24 Feb. 2021, https://www.mayoclinic.org/diseases-conditions/infectious-diseases/in-depth/cre-bacteria/art-20166387#:~:text=Carbapenem-resistant%20Enterobacteriaceae%20(CRE),cases%20to%20all%20available%20antibiotics.
  7. Frieden, Thomas R., and Beth P. Bell. “Core Elements of Hospital Antibiotic Stewardship Programs.” American Hospital Association’s Physician Leadership Forum, 2014, https://www.ahaphysicianforum.org/resources/appropriate-use/antimicrobial/.
  8. Healthcare Settings – Preventing the spread of MRSA. Accessed April 21, 2021. https://www.cdc.gov/mrsa/healthcare/index.html  
  9. ESBL-producing Enterobacterales in Healthcare Settings. Accessed April 21, 2021. https://www.cdc.gov/hai/organisms/ESBL.html
  10. Bradford, P.A. Extended-Spectrum β-Lactamases in the 21st Century: Characterization, Epidemiology, and Detection of this Important Resistance Threat.
  11. . 2001 Oct; 14(4): 933-951. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC89009/pdf/cm0401000933.pdf



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