Crawling Babies Stir Up Dust and Microbes—But That’s a Good Thing

Robot baby shows infants inhale four times as much biomatter as adults walking across the same floor.

When babies crawl, their movement across floors, especially carpeted surfaces, kicks up high levels of dirt, skin cells, bacteria, pollen, and fungal spores, a new study has found. The infants inhale a dose of bio bits in their lungs that is four times (per kilogram of body mass) what an adult would breathe walking across the same floor.

As alarming as that sounds, lead researcher Brandon Boor, an assistant professor of civil engineering at Purdue University is quick to add that this isn’t necessarily a bad thing.

“We are interested in the biological material an infant inhales, especially during their first year of life when they are crawling,” Boor said. “Many studies have shown that inhalation exposure to microbes and allergen-carrying particles in that portion of life plays a significant role in both the development of, and protection from, asthma and allergic diseases. There are studies that have shown that being exposed to a high diversity and concentration of biological materials may reduce the prevalence of asthma and allergies later in life.”

Scientists have previously done studies to determine how much dirt and biological material is kicked up and resuspended into the air when an adult walks indoors, but this is the first study to look at what happens with infants and their unique forms of locomotion.

The results are published in Environmental Science & Technology.

Human babies are one of the few mammals that can’t get up and walk soon after being born. Elephants, giraffes, horses, all can take a few wobbly steps soon after they enter the world, but it’s months before a human can claim the same accomplishment.

Being able to feed themselves is another major milestone for human babies, and this engineering project to create anti-tremble utensils for toddlers is aiming to make it easier to achieve.

Anthropologist David Tracer of the University of Colorado has suggested that, based on studies of indigenous cultures, crawling is not necessary for human development. In fact, he has suggested, it only became common once people began living in structures with wooden floors.

As babies roll, slide and crawl on the floor, their movements stir up more particulates into the air, and their mouths and nostrils are much closer to the floor where the concentrations are greater. This is countered somewhat by the fact that babies tend to move in much shorter bursts of activity than older children or adults.

To study just how much of the floor debris babies breathe, the research team built a robotic crawling baby (which is much less adorable than the real thing) and tested it crawling on actual carpet samples they had removed from homes. Then the researchers measured and analyzed the particulates in the breathing zone.

“We used state-of-the-art aerosol instrumentation to track the biological particles floating in the air around the infant in real-time, second by second,” Boor explained. “The instrument uses lasers to cause biological material to fluoresce. Most bacterial cells, fungal spores, and pollen particles are fluorescent, so they can be reliably distinguished from non-biological material in the air. We also worked with a microbiology group at Finland’s National Institute for Health and Welfare, which conducted DNA-based analysis of the microbes we collected onto filters.”

The researchers found that a concentrated cloud of resuspended particles forms around the Pig-Pen wannabes, and that the concentrations around them can be as much as 20 times greater than the levels of material higher in the room.

Brandon Boor, a Purdue University assistant professor of civil engineering and environmental and ecological engineering, together with graduate students Danielle Wagner and Tianren Wu, are studying air quality in indoor environments. Their most recent study focused on what babies breathe while crawling on carpets. (Image courtesy of Marshall Farthing.)

Brandon Boor, a Purdue University assistant professor of civil engineering and environmental and ecological engineering, together with graduate students Danielle Wagner and Tianren Wu, are studying air quality in indoor environments. Their most recent study focused on what babies breathe while crawling on carpets. (Image courtesy of Marshall Farthing.)

Moreover, infants’ bodies aren’t as good at blocking this dust storm, Boor says.

“For an adult, a significant portion of the biological particles are removed in the upper respiratory system, in the nostrils and throat. But for very young children, they more often breathe through their mouths, and a significant fraction is deposited in the lower airways–the tracheobronchial and pulmonary regions. The particles make it to the deepest regions of their lungs.”

Counterintuitively, perhaps, this may be just what nature intended.

In the late 1980s, British epidemiologist David Strachan was the first to propose the “hygiene hypothesis,” which says that too clean of an environment may suppress the development of the immune system. Allergists also sometimes refer to this as “the farming effect.”

“Exposure to certain bacterial and fungal species can result in the development of asthma, but numerous studies have shown that when an infant is exposed to a very high diversity of microbes, at a high concentration, they can have a lower rate of asthma later in life. Such exposures act to stimulate and challenge your immune system,” Boor said.

In Western societies, infants spend nearly all of their time indoors, where indoor dust resuspension may contribute significantly to their respiratory encounters with biological material.

“While our research established new methods for infant microbial exposure assessment, much remains to be discovered,” Boor says. “I hope to continue to work with microbiologists and immunologists to better understand the role of indoor air microbes and allergens on early-childhood health.”

For more news at the intersection of healthcare and engineering, find out how this 3D-Printed Pump Could Make Heart Transplants Obsolete.

Source: Purdue University