Evolutionary model for antibiotic resistance reveals dose timing critical to care

A Cleveland Clinic study highlights how early antibiotic doses are key to preventing resistance. Using evolutionary modeling, researchers found inconsistent timing, especially in initial doses, leads to treatment failure. Lab tests confirmed bacteria missed early doses developed resistance even with later compliance. The findings could reshape patient guidance and dosing strategies for antibiotics.

"Missing early doses plays a bigger role in resistance than missing later ones." – Eshan King, Case Western Reserve

Researchers are working to improve the way we use evolutionary modeling to understand drug resistance. The study uses a "fitness seascape" evolutionary model to predict whether an infection will develop antibiotic resistance. It found that inconsistent timing and missing early doses can lead to treatment failure.

Key Points

1 Fitness seascape model tracks antibiotic resistance evolution

2 Early dose timing more crucial than total medication amount

3 Lab tests confirm late doses less harmful than skipped initial ones

4 Findings may change how doctors prescribe and monitor antibiotic use

Using a form of evolutionary modelling, Cleveland Clinic researchers can predict what happens if you miss a dose of antibiotics.

.A team led by Jacob Scott, MD, DPhil., including study first author Eshan King, an MD/PhD student at Case Western Reserve University School of Medicine, is refining models that determine recommended antibiotic doses by incorporating bacterial evolutionary dynamics.

"With the rise of 'superbugs,' or antibiotic-resistant bacterial infections, the world is reaching a crisis point," says Dr. Scott, the study's senior author. "We've already seen from MRSA what can happen if a bacterium becomes antibiotic-resistant. We need to address the problem before it impacts our ability to use antibiotics in more routine aspects of medical care, like surgery or childbirth."

Doctors typically use guidelines from drug companies to decide medication dosages for their patients. These guidelines rely on equations that describe how antibiotics are absorbed in the body to calculate the smallest effective dose that treats the disease, without letting the diseased area evolve a drug-resistant mutation. Under Dr. Scott's mentorship, King has been expanding some of these models to better reflect how changes in a medication's concentration in our bloodstream affect treatment resistance.

"Many models assume the environment around a diseased area doesn't change, but the environment of an infection is our own bodies. That's never truly constant," King says. "Our manuscript builds on previous work to account for changes in drug concentration over time within our bodies."

Seascape models are equations that include variables that change over time or space , like drug concentration. This allows investigators like King to study new aspects of antibiotic resistance, like how the timing between doses influences medication levels in diseased areas. King used seascape modeling to simulate the outcomes of hundreds of virtual patients being treated for bacterial infections with IV and oral antibiotics.

"Other models have drug concentration as an input, and evolutionary outcome (treatment resistance) as an output. Instead of testing different drug concentrations in separate patients, our model lets us kind of turn a dial to change concentrations in one patient over time to better reflect how our bodies process drug doses ," Dr. Scott explains.

Before this study, missing a dose or stopping antibiotics treatment early was emphasized as a main contributor to treatment resistance. King was surprised to find simulated patients who developed treatment resistance were taking roughly the same amount of medication as those who successfully eliminated their infection.

Instead of the presence or absence of medication at all, it was the timing of the medication doses that differed between these two groups. The team found that missing or being late with early doses played a bigger role in developing antibiotic resistance than missing or being late with a later dose.

The team tested these findings in the lab by treating bacteria with different antibiotic regimens. The bacteria that received all the recommended dose at the recommended time were unlikely to develop treatment resistance. Similarly, bacteria that were appropriately received the early doses but missed later doses did not develop resistance. In contrast, the bacteria that missed early doses but were appropriately treated later evolved treatment resistance, highlighting a potential mechanism of treatment failure in a patient.

"These results are shaping how I will counsel my patients," King says. "I will emphasize that they really need to be on top of taking their antibiotics at the recommended time intervals, especially at the beginning. If they take the first dose and then miss the second dose and then take the third dose, that might not work out so well. There is a higher likelihood that this treatment will fail, and we will have to try something else."

https://www.newkerala.com/news/o/evolutionary-model-antibiotic-resistance-reveals-dose-timing-critical-care-186