Two researchers wearing white lab coats standing back-to-back with arms crossed...
Assistant Professor Jungwook “Jay” Paek and PhD student Anika Alim worked together on research to find out how airway tissues react to mechanical forces.

Image source: Binghamton University; credit: Jonathan Cohen 

News • Mechanical stress-induced tissue remodelling

How asthma permanently alters the airways

Mechanical forces cause overproduction of extracellular proteins and overgrowth of blood vessels, which over time constrict breathing

About 25 million people in the U.S. — roughly eight out of 100 — are diagnosed with asthma. Allergens, air pollution, extreme weather conditions, or other irritants can cause chronic lung inflammation, leading to coughing, wheezing, or shortness of breath. 

One lesser-studied side effect: Asthma attacks induce mechanical forces that permanently alter airway tissue — damage that occurs independently of inflammation alone. New research led by Binghamton University used leading-edge lung-on-a-chip technology to show that the repeated mechanical stress from asthma attacks causes overproduction of proteins for the extracellular matrix that joins cells together. It also leads to the overgrowth of blood vessels, a condition known as angiogenesis. Over time, both factors cause thickened airway tissue that constricts breathing. 

For a paper published in Nature Biomedical Engineering, Assistant Professor Jungwook “Jay” Paek — a faculty member at the Thomas J. Watson College of Engineering and Applied Science’s Department of Electrical and Computer Engineering — collaborated with colleagues at Binghamton as well as the University of Pennsylvania, the University of Toledo, and the Pacific Northwest National Laboratory.

Closeup photo of a hand in a protective rubber glove holding a small transparent plastic rectangle with fine red and blue structures in it
Assistant Professor Jungwook “Jay” Paek uses organ-on-a-chip technology to research biological systems.

Image source: Binghamton University; credit: Jonathan Cohen

The new paper continues postdoctoral research that Paek did at Penn with his advisor, Professor Dan Huh, before coming to Binghamton in 2023. “This is the first time that anyone has demonstrated the effect of a mechanical process on tissue remodeling — including both fibrosis and angiogenesis — in asthma patients,” he said. 

Organ-on-a-chip uses microfabrication techniques borrowed from the semiconductor industry to reproduce conditions in the human body with just a small culture of cells. 

For this study, the researchers built the microfluidic device so that the tissue could undergo structural deformation by pressurizing or evacuating a connecting chamber. As part of their observations, they tested the potential for medication delivery to modulate the cells’ activity, laying the foundation for possible future asthma treatments. “This technology is at the intersection of biological science, biomedical engineering, electrical engineering, and mechanical engineering,” Paek said. 

Binghamton doctoral student Anika Alim contributed to the research as part of Paek’s project team. As an electrical engineering student, she had little experience with bioengineering principles or lab work, but she got up to speed quickly. “I started to learn about organ-on-a-chip on the very basic level,” she said. “Then I did a dive deep into how it can replicate human physiology. With this technology, we can see how our human body actually functions when asthma attacks happen.” 

Paek’s current research at Binghamton centers on Parkinson's and other neurodegenerative diseases, including a study published earlier this year about how those conditions affect blood circulation and a National Institutes of Health grant to investigate how protein aggregates called Lewy bodies contribute to neurological breakdown. 

“Focusing on how neurons are electrically active within the human body leans more toward electrical engineering principles based in biological science,” he said. 


Source: Binghamton University 

01.07.2026

Related articles

Photo

News • Methylation pattern analysis

cfSort: New tool could improve liquid biopsy

A research team at UCLA has made an important advancement to address one of the major challenges in cell-free DNA (cfDNA) testing, also known as liquid biopsy.

Photo

Article • Cancer diagnostics I

Ambiguity calls for a second opinion

Each year, approximately 1.6 million women in the USA have breast biopsies to diagnose or rule out cancer. Pathological diagnosis is considered the gold standard – how accurate are these…

Photo

News • Dynamic in vitro platform

“Breathing” organoid offers new insights into lung disease

A new type of “breathing” lung organoid enables quantitative measurement of how easily the lung expands - and may provide a new way to study diseases such as pulmonary fibrosis.

Subscribe to Newsletter