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Harmful microbes found on sewer pipe walls

Study could lead to better understanding of risks and disinfection methods

a combined sewer overflow outfall

A new study could lead to better disinfection methods of sewer pipes.


July 15, 2020

Can antibiotic-resistant bacteria escape from sewers into waterways and cause disease outbreaks?

To answer this question, scientists at Rutgers University built a simulated sewer to examine the microbe-laden biofilms that cling to sewer walls. The research was funded by the National Science Foundation.

The results are published in the journal Environmental Science: Water Research & Technology.

The researchers found that biofilms often contain antibiotic-resistant bacteria and can withstand standard treatment used to disinfect sewers. Cleaning with bleach can reduce the density of the biofilms but not entirely remove them, potentially leaving wastewater treatment workers and the public exposed to health risks.

Still, disinfecting a sewer line may be a good idea before sewer maintenance is done, especially following events such as a disease outbreak or bioterrorism incident that might expose sewer lines to high-risk microbes.

Normally, what's flushed down a toilet goes to a wastewater treatment plant. But rainfall can cause overflows of untreated waste into bays, rivers, streams and other waterways. The researchers say a potential worst-case scenario would be an infectious disease outbreak following a sewer overflow that releases wastewater, sewer solids and biofilms to surface water.

"Given the current interest in wastewater-based epidemiology, our study highlights the need to consider sewer processes and how best to combat pathogens," said senior author Nicole Fahrenfeld.

The researchers found that sewer pipe materials -- concrete or polyvinyl chloride plastic (PVC) -- did not affect the formation of biofilms but played a role in the effectiveness of bleach to disinfect them. Bleach is better at removing biofilms from PVC than from concrete, likely because PVC is smoother.

"This research is timely in the midst of the COVID-19 pandemic," says Karl Rockne, a program director in NSF's Directorate for Engineering. "The study may help us focus our efforts to understand the risks to the public from SARS-CoV-2 and other pathogens."

--  NSF Public Affairs, researchnews@nsf.gov