"Even now, I don't think most people spend a full 20 seconds washing their hands," says Emory chemist Bill Wuest, who researches disinfectants. "But maybe if they understood the chemistry of soap and water it would make them more conscious of the need to do so."
By Carol Clark
Scientists are rushing to find effective treatments and vaccines for the COVID-19 infections sweeping the globe. Meanwhile, social distancing and hygiene are the best defense.
Emory University chemist Bill Wuest — who researches disinfectants — recently appeared on The Weather Channel to explain how washing your hands with plain soap and water can destroy the coronavirus that causes the infections, to help minimize its spread.
“There are so many unknowns about this pandemic that are driving fear and leading to irrational actions, like panic buying of toilet paper,” Wuest says. “It’s important to focus on what we do know — washing your hands properly and often with soap and water can help reduce your chances of getting infected with many pathogens and for spreading them to others.”
Soap and water work through the hydrophobic effect, a basic chemistry concept that explains why oil and water don’t mix. The effect drives protein folding, a process that alters the structures of amino acids and allows them to perform different functions within a cell.
“I usually use the example of protein folding to teach the hydrophobic effect to chemistry undergraduates,” Wuest says. “But now I realize that soap provides a much more relatable example.”
Soap molecules have hydrophilic heads — meaning they cling to water molecules — and tails that are hydrophobic — which means “water-fearing.” When immersed in water, the soap molecules form into tiny balls, called micelles, with their hydrophobic tails pointed inwards. While the soap molecule tails want to avoid water, they are attracted to oils and fats.
Many bacteria and viruses, including coronaviruses, are encased in a fatty acid membrane. In the most simplistic terms, the soap molecule tails poke into these bilayer membranes, breaking them apart, and destroying the pathogens.
Warmer temperatures boost the hydrophobic effect, and may help hand soap to lather and remove grime or microbes sticking to your skin, just as hot water and soap helps remove grease from a kitchen pan. Wuest recommends lathering your hands in water that’s warm to the touch. Evidence suggests it’s best to spend at least 20 seconds washing your hands to remove more germs, he adds.
Wuest plans to use the soap and water example in his Chem 202 classroom from now on. Emory’s Chemistry Unbound curriculum is designed to give undergraduates context for real-world problems and solutions. Although washing with soap and water may sound too basic a topic for college students, Wuest now realizes that it is not.
“This pandemic has changed the way I think about teaching,” he says. “Even now, I don’t think most people spend a full 20 seconds washing their hands, but maybe if they understood the chemistry of soap and water it would make them more conscious of the need to do so.”
Hand washing is important to reduce illnesses and deaths for many diseases, including seasonal influenza, he notes.
If soap and water is not available, hand sanitizer containing at least 60 percent alcohol is also effective at breaking up the membranes surrounding coronaviruses and bacteria. It should be rubbed thoroughly into the hands until all the liquid evaporates, Wuest says.
Wuest is a Georgia Research Alliance Distinguished Investigator and associate professor in Emory’s Department of Chemistry. He is also a member of the Emory Antibiotic Resistance Center.
For everyday use in a non-medical setting, Wuest encourages people to choose soaps and hand sanitizers that do not contain anti-bacterial ingredients. Proper use of plain soap and water or an alcohol-based sanitizer product is key, he stresses.
“I worry that there could be a spike in anti-bacterial resistance in a few years if too many people start using antibacterial products to clean their hands,” he says.
Related:
Chemists teach old drug new tricks to target deadly staph bacteria
from eScienceCommons https://ift.tt/3dbg2St
"Even now, I don't think most people spend a full 20 seconds washing their hands," says Emory chemist Bill Wuest, who researches disinfectants. "But maybe if they understood the chemistry of soap and water it would make them more conscious of the need to do so." By Carol Clark
Scientists are rushing to find effective treatments and vaccines for the COVID-19 infections sweeping the globe. Meanwhile, social distancing and hygiene are the best defense.
Emory University chemist Bill Wuest — who researches disinfectants — recently appeared on The Weather Channel to explain how washing your hands with plain soap and water can destroy the coronavirus that causes the infections, to help minimize its spread.
“There are so many unknowns about this pandemic that are driving fear and leading to irrational actions, like panic buying of toilet paper,” Wuest says. “It’s important to focus on what we do know — washing your hands properly and often with soap and water can help reduce your chances of getting infected with many pathogens and for spreading them to others.”
Soap and water work through the hydrophobic effect, a basic chemistry concept that explains why oil and water don’t mix. The effect drives protein folding, a process that alters the structures of amino acids and allows them to perform different functions within a cell.
“I usually use the example of protein folding to teach the hydrophobic effect to chemistry undergraduates,” Wuest says. “But now I realize that soap provides a much more relatable example.”
Soap molecules have hydrophilic heads — meaning they cling to water molecules — and tails that are hydrophobic — which means “water-fearing.” When immersed in water, the soap molecules form into tiny balls, called micelles, with their hydrophobic tails pointed inwards. While the soap molecule tails want to avoid water, they are attracted to oils and fats.
Many bacteria and viruses, including coronaviruses, are encased in a fatty acid membrane. In the most simplistic terms, the soap molecule tails poke into these bilayer membranes, breaking them apart, and destroying the pathogens.
Warmer temperatures boost the hydrophobic effect, and may help hand soap to lather and remove grime or microbes sticking to your skin, just as hot water and soap helps remove grease from a kitchen pan. Wuest recommends lathering your hands in water that’s warm to the touch. Evidence suggests it’s best to spend at least 20 seconds washing your hands to remove more germs, he adds.
Wuest plans to use the soap and water example in his Chem 202 classroom from now on. Emory’s Chemistry Unbound curriculum is designed to give undergraduates context for real-world problems and solutions. Although washing with soap and water may sound too basic a topic for college students, Wuest now realizes that it is not.
“This pandemic has changed the way I think about teaching,” he says. “Even now, I don’t think most people spend a full 20 seconds washing their hands, but maybe if they understood the chemistry of soap and water it would make them more conscious of the need to do so.”
Hand washing is important to reduce illnesses and deaths for many diseases, including seasonal influenza, he notes.
If soap and water is not available, hand sanitizer containing at least 60 percent alcohol is also effective at breaking up the membranes surrounding coronaviruses and bacteria. It should be rubbed thoroughly into the hands until all the liquid evaporates, Wuest says.
Wuest is a Georgia Research Alliance Distinguished Investigator and associate professor in Emory’s Department of Chemistry. He is also a member of the Emory Antibiotic Resistance Center.
For everyday use in a non-medical setting, Wuest encourages people to choose soaps and hand sanitizers that do not contain anti-bacterial ingredients. Proper use of plain soap and water or an alcohol-based sanitizer product is key, he stresses.
“I worry that there could be a spike in anti-bacterial resistance in a few years if too many people start using antibacterial products to clean their hands,” he says.
Related:
Chemists teach old drug new tricks to target deadly staph bacteria
from eScienceCommons https://ift.tt/3dbg2St
By Carol Clark
Scientists are rushing to find effective treatments and vaccines for the COVID-19 infections sweeping the globe. Meanwhile, social distancing and hygiene are the best defense.
Emory University chemist Bill Wuest — who researches disinfectants — recently appeared on The Weather Channel to explain how washing your hands with plain soap and water can destroy the coronavirus that causes the infections, to help minimize its spread.
“There are so many unknowns about this pandemic that are driving fear and leading to irrational actions, like panic buying of toilet paper,” Wuest says. “It’s important to focus on what we do know — washing your hands properly and often with soap and water can help reduce your chances of getting infected with many pathogens and for spreading them to others.”
Soap and water work through the hydrophobic effect, a basic chemistry concept that explains why oil and water don’t mix. The effect drives protein folding, a process that alters the structures of amino acids and allows them to perform different functions within a cell.
“I usually use the example of protein folding to teach the hydrophobic effect to chemistry undergraduates,” Wuest says. “But now I realize that soap provides a much more relatable example.”
Soap molecules have hydrophilic heads — meaning they cling to water molecules — and tails that are hydrophobic — which means “water-fearing.” When immersed in water, the soap molecules form into tiny balls, called micelles, with their hydrophobic tails pointed inwards. While the soap molecule tails want to avoid water, they are attracted to oils and fats.
Many bacteria and viruses, including coronaviruses, are encased in a fatty acid membrane. In the most simplistic terms, the soap molecule tails poke into these bilayer membranes, breaking them apart, and destroying the pathogens.
Warmer temperatures boost the hydrophobic effect, and may help hand soap to lather and remove grime or microbes sticking to your skin, just as hot water and soap helps remove grease from a kitchen pan. Wuest recommends lathering your hands in water that’s warm to the touch. Evidence suggests it’s best to spend at least 20 seconds washing your hands to remove more germs, he adds.
Wuest plans to use the soap and water example in his Chem 202 classroom from now on. Emory’s Chemistry Unbound curriculum is designed to give undergraduates context for real-world problems and solutions. Although washing with soap and water may sound too basic a topic for college students, Wuest now realizes that it is not.
“This pandemic has changed the way I think about teaching,” he says. “Even now, I don’t think most people spend a full 20 seconds washing their hands, but maybe if they understood the chemistry of soap and water it would make them more conscious of the need to do so.”
Hand washing is important to reduce illnesses and deaths for many diseases, including seasonal influenza, he notes.
If soap and water is not available, hand sanitizer containing at least 60 percent alcohol is also effective at breaking up the membranes surrounding coronaviruses and bacteria. It should be rubbed thoroughly into the hands until all the liquid evaporates, Wuest says.
Wuest is a Georgia Research Alliance Distinguished Investigator and associate professor in Emory’s Department of Chemistry. He is also a member of the Emory Antibiotic Resistance Center.
For everyday use in a non-medical setting, Wuest encourages people to choose soaps and hand sanitizers that do not contain anti-bacterial ingredients. Proper use of plain soap and water or an alcohol-based sanitizer product is key, he stresses.
“I worry that there could be a spike in anti-bacterial resistance in a few years if too many people start using antibacterial products to clean their hands,” he says.
Related:
Chemists teach old drug new tricks to target deadly staph bacteria
from eScienceCommons https://ift.tt/3dbg2St
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