the challenge of surrogate testing for air sanitizers
Surrogates are stand-ins for actual pathogens, chosen for their similarity in characteristics such as size, structure, or susceptibility to sanitizing methods. While useful in standardized laboratory tests, surrogate-based studies often struggle to replicate real-world conditions.
For instance:
- Time Adjustments: Many tests require extrapolation of short-term data to predict long-term effects, introducing potential inaccuracies.
- Controlled Environments: Laboratory conditions often fail to mimic the complexity of real-world airflows, temperature changes, and human activity in buildings.
- Questionable Relevance: Surrogates may not behave identically to actual pathogens under real-world conditions, leading to results that over- or underestimate efficacy
The case for using a building's natural microbiome
A building's microbiome—the community of microorganisms naturally present in its environment—offers a more representative testing framework. Here's why this approach could be a game-changer:
1. Realistic Pathogen Interactions:
Testing air sanitizers against the natural microbial population of a building captures a more authentic picture of their effectiveness. These microorganisms include bacteria, fungi, and viruses that are commonly encountered, making the results immediately relevant.
2. No Need for Surrogates:
By analyzing how the existing microbiome changes after applying an air sanitizer, there’s no need to
introduce surrogate pathogens. This eliminates a layer of uncertainty in interpreting results.
3. Time-Integrated Results:
Monitoring the microbiome over time provides dynamic insights into how effectively an air sanitizer performs in reducing or neutralizing harmful organisms in real-world conditions.
4. Easier Public Understanding:
Results derived from a natural microbiome are inherently relatable. Communicating reductions in familiar terms, such as the prevalence of mold spores or specific bacterial strains, can resonate more with end users.
Implementing Microbiome-Based Testing
Transitioning to microbiome-based testing:
· Baseline
Microbiome Mapping: Before testing, researchers must establish a baseline profile of a building's microbiome using tools like air sampling and genetic sequencing.
· Intervention
Monitoring: Air sanitizers can be applied, and subsequent changes to the microbiome can be monitored over days or weeks, offering insights into both immediate and long-term effects.
· Data Analysis:
Advanced bioinformatics can help quantify changes in microbial diversity, abundance, and the presence of potential pathogens.
conclusion:
By utilizing a building's natural microbiome, air sanitizer testing can move closer to real-world relevance. This approach not only addresses the limitations of surrogate-based testing but also provides results that are easier to interpret and more meaningful for building owners, managers, and he occupants. As indoor air quality becomes a growing public health priority, adopting innovative testing methodologies will ensure we can trust the products designed to protect the built environment.