Antibiotic prophylaxis

Antibiotic prophylaxis refers to, for humans, the prevention of infection complications using antimicrobial therapy (most commonly antibiotics). Antibiotic prophylaxis in domestic animal feed mixes has been employed in America since at least 1970.[1]

For humans

Antibiotic prophylaxis is most commonly used prior to dental surgery[2] or medical surgery,[3] however, may be used in other cases, such prior to sexual intercourse for patients who suffer from recurrent urinary tract infections.[4]

Even when sterile techniques are adhered to, surgical procedures can introduce bacteria and other microbes in the blood (causing bacteremia), which can colonize and infect different parts of the body. An estimated 5 to 10 percent of hospitalized patients undergoing otolaryngology ("head and neck") surgery acquire a nosocomial ("hospital") infection, which adds a substantial cost and an average of 4 extra days to the hospital stay.

Antibiotics can be effective in reducing the occurrence of such infections. Patients should be selected for prophylaxis if the medical condition or the surgical procedure is associated with a considerable risk of infection or if a postoperative infection would pose a serious hazard to the patient's recovery and well-being.[5]

Local wound infections (superficial or deep-sided), urinary tract infections (caused by a bladder catheter inserted for surgery), and pneumonia (due to impaired breathing/coughing, caused by sedation and analgesics during the first few hours of recovery) may endanger the health of patients after surgery. Visibly worse are postoperative bacterial infections at the site of implanted foreign bodies (sutures, ostheosynthetic material, joint replacements, pacemaker implants, etc.) Often, the outcome of the procedure may be put into question and the life of the patient may even be put at risk.

Worldwide experience with antimicrobial prophylaxis in surgery has proven to be effective and cost-efficient, both avoiding severe patient suffering while saving lives (provided the appropriate antibiotics have been carefully chosen and used to the best of current medical knowledge).

Antibiotic selection

A proper regimen of antibiotics for perioperative prophylaxis of septic complications decreases the total amount of antimicrobials needed and eases the burden on hospitals. The choice of antibiotics should be made according to data on pharmacology, microbiology, clinical experience and economy. Drugs should be selected with a reasonable spectrum of activity against pathogens likely to be encountered, and antibiotics should be chosen with kinetics that will ensure adequate serum and tissue levels throughout the risk period. Depending on the type of surgery and anticipated contamination associated with it, combinations of different agents or different routes of administration (e.g. intravenous and oral antibiotics) might be beneficial in reducing perioperative adverse events.[6][7]

For prophylaxis in surgery, only antibiotics with good tolerability should be used. Cephalosporins remain the preferred drugs for perioperative prophylaxis due to their low toxicity. Parenteral systemic antibiotics seem to be more appropriate than oral or topical antibiotics because the chosen antibiotics must reach high concentrations at all sites of danger. It is well recognized that broad-spectrum antibiotics are more likely to prevent gram-negative sepsis. New data demonstrate that third generation cephalosporins are more effective than first and second generation cephalosporins if all perioperative infectious complications are taken into consideration. Dermatologic surgeons commonly use antibiotic prophylaxis to prevent bacterial endocarditis. Based on previous studies, though, the risk of endocarditis following cutaneous surgery is low and thus the use of antibiotic prophylaxis is controversial. Although this practice is appropriate for high-risk patients when skin is contaminated, it is not recommended for noneroded, noninfected skin.[8] There are many factors that affect physicians’ compliance with guideline recommendations, including cultural factors, educational background, training, nurse and pharmacist influences, medication supply, and logistics.[3]

For dental procedures, the American protocol in 2017 called for the prescription of amoxicillin or ampicillin.[3] The American Dental Association (ADA) recommends antibiotic prophylaxis for very few people since only a small number of cases of endocarditis might be caused by dental procedures.[9]

Advantages of long-acting antibiotics

Long-acting, broad-spectrum antibiotics offer the following advantages by comparison to short-acting antimicrobials in perioperative prophylaxis:

  • A single dose covers the whole perioperative risk period - even if the operation is delayed or long-lasting - and with regard to respiratory and urinary tract infections
  • Repeat administrations for prophylaxis are not necessary, so that additional doses are less likely to be forgotten (an advantage of practical value in a busy working situation such as a hospital)
  • Less risk of development of resistance and less side effects
  • Increased compliance and reduced errors of administration
  • Possibly better-effectiveness (less material and labor cost, less septic perioperative complications)

There are many factors that affect physicians’ compliance with guideline recommendations, including cultural factors, educational background, training, nurse and pharmacist influences, medication supply, and logistics.

American Heart Association recommendations

The American Heart Association (AHA) now recommends antibiotic prophylaxis for very few patients since only a small number of cases of endocarditis might be prevented by this procedure.[10]

For livestock

Antibiotic prophylaxis in domestic animal feed mixes has been employed in America since at least 1970.[1] Over time, the use of antibiotics for growth promotion purposes in livestock was discovered. In 1986, some European countries banned the use of antibiotics because of research they found that linked antibiotic use in livestock and drug resistant bacteria in humans.[11] The European Union regulated in 2006 against antibiotics for growth promotion purposes.[12]

It was estimated in 2014 that over 80% of the world's antibiotic use was on farms.[13][12] Coccidiosis in fowl had evolved increased tolerance to the antibiotic feed.[12] The WHO warned in April 2014 that farm use was a contributor to superbugs in humans.[13] The Auditor General of Canada found lack of progress in 2014 on antimicrobial resistance despite three years of government funds that should have been used to implement a reduction programme.[12] A CBC writer was concerned that there was in Canada "no coordinated national system to control antibiotics in agriculture."[13]

Due to the serious problem of superbugs (which are bred in antibiotic-rich environments) the Food and Drug Administration issued a guidance document in December 2013. The chief public health officer of Canada said four months later that "antibiotics should only be used in animals to treat infection rather than guard against disease or promote growth." The Canadian guidance document calls for "the prudent use of antibiotics in animal agriculture and a gradual phasing out of growth promoting drugs in feed and water over the three years" ending in 2017.[14] Producers will no longer be allowed to continuously feed animals doses of antibiotics as a way to promote growth.[15] A veterinarian said that ""If you don't put (antibiotics) in the feed, and you wait until you get an outbreak of necrotic enteritis, you've got a lot of dead birds and you've lost a lot of money."[15] The Beef Cattle Research Council were irritated by the change, while the Chicken Farmers of Canada had pre-empted it by teamwork four years earlier.[14] However, concerns were raised by the Chief Veterinarian of Ontario that "In other jurisdictions, they've found that, the drugs are not used for growth promotion, wink, wink, they're used for disease prevention."[13]

As of 2016, Health Canada had approved for employment in cattle three natural hormones and three synthetic hormones.[11]

References

  1. 1 2 Weichenthal, B. A; Russell, H. G (1970): "Beef cattle feeding suggestions : nutrient requirements, balancing rations, protein supplements, suggested rations" Urbana, IL : University of Illinois at Urbana-Champaign , College of Agriculture, Cooperative Extension Service
  2. "Antibiotic Prophylaxis". www.ada.org. Retrieved 2022-02-11.
  3. 1 2 "Prophylactic Antiobiotics: Types, Uses, and Administration". Healthline. 2014-01-22. Retrieved 2022-02-11.
  4. Ahmed, Haroon; Davies, Freya; Francis, Nick; Farewell, Daniel; Butler, Christoper; Paranjothy, Shantini (2017-05-01). "Long-term antibiotics for prevention of recurrent urinary tract infection in older adults: systematic review and meta-analysis of randomised trials". BMJ Open. 7 (5): e015233. doi:10.1136/bmjopen-2016-015233. ISSN 2044-6055. PMC 5729980. PMID 28554926.
  5. "Archived copy". Archived from the original on 2002-10-18. Retrieved 2005-10-17.{{cite web}}: CS1 maint: archived copy as title (link)
  6. Pellino, Gianluca; Espín-Basany, Eloy (2021-12-17). "Bowel decontamination before colonic and rectal surgery". British Journal of Surgery. 109 (1): 3–7. doi:10.1093/bjs/znab389. ISSN 0007-1323.
  7. Espin Basany, Eloy; Solís-Peña, Alejandro; Pellino, Gianluca; Kreisler, Esther; Fraccalvieri, Doménico; Muinelo-Lorenzo, Manuel; Maseda-Díaz, Olga; García-González, José María; Santamaría-Olabarrieta, Marta; Codina-Cazador, Antonio; Biondo, Sebastiano (August 2020). "Preoperative oral antibiotics and surgical-site infections in colon surgery (ORALEV): a multicentre, single-blind, pragmatic, randomised controlled trial". The Lancet Gastroenterology & Hepatology. 5 (8): 729–738. doi:10.1016/S2468-1253(20)30075-3.
  8. Scheinfeld N, Ross B (2002). "Antibiotic prophylaxis guideline awareness". Dermatol. Surg. 28 (9): 841–4. doi:10.1046/j.1524-4725.2002.02033.x. PMID 12269880. S2CID 42388624.
  9. "Antibiotic Prophylaxis Prior to Dental Procedures". American Dental Association. 23 March 2020. Retrieved 10 September 2020.
  10. Wilson, Walter; Taubert, Kathryn; Gewitz, Michael; Lockhart, Peter; Baddour, Larry; Levison, Matthew; Bolger, Ann; Cabell, Christopher; Takahashi, Masato; Baltimore, Robert; Newburger, Jane; Strom, Brian; Tani, Lloyd; Gerber, Michael; Bonow, Robert; Pallasch, Thomas; Shulman, Stanford; Rowley, Anne; Burns, Jane; Ferrieri, Patricia; Gardner, Timothy; Goff, David; Durack, David (April 19, 2007). "Prevention of Infective Endocarditis. Guidelines From the American Heart Association. A Guideline From the American Heart Association Rheumatic Fever, Endocarditis, and Kawasaki Disease Committee, Council on Cardiovascular Disease in the Young, and the Council on Clinical Cardiology, Council on Cardiovascular Surgery and Anesthesia, and the Quality of Care and Outcomes Research Interdisciplinary Working Group". Circulation. 116 (15): 1736–1754. doi:10.1161/CIRCULATIONAHA.106.183095. PMID 17446442. Retrieved 2 June 2017.
  11. 1 2 revivewellness.ca: "Is Canadian Beef Hormone & Antibiotic Free?", April 17, 2016
  12. 1 2 3 4 globalnews.ca: "Medicating meat: What's Canada's plan for animal antibiotics?", 08/06/2014
  13. 1 2 3 4 cbc.ca: "Health Canada's quiet move to end use of antibiotics to fatten up animals", 09/07/2014
  14. 1 2 producer.com: "Health Canada tightens antibiotic use", 17/04/2014
  15. 1 2 ctvnews.ca: "Health Canada restricts use of growth-promoting antibiotics in livestock", 12/07/2014

Further reading

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