The objective of this work is to develop an innovative and quantitative method to study cell failure under fluidic pressure to understand cell membrane mechanical properties. Due to lack of experimental data related to cell failure property, the current research focuses on investigating the cell failure using a micro pipette aspiration experiment method to elaborate gradually increasing hydrostatic pressure to the cell causing the membrane to deform and eventually rupture. Based on our observation, the prostate cancer cells (PC-3) deformed into a deflated and flattened shape under higher hydrostatic pressure (249 Pa) while prostate epithelial cells (PrEC LH) cells generate a spherical and rounded shape. The stress along the cell membrane was estimated from the curvature data captured from the 2D microscopic images for each pressure magnitude to quantify the damage before rupture state. From the results, non-transformed prostate epithelial cells (PrEC LH) presented a stiffer and rupture resilient property compared to transformed prostate cancer cells (PC-3) which presented a softer and vulnerable property. Besides, the alteration of shape of the aspirated membrane directly affected the stress distribution over the membrane and as a result, provoked membrane failure. Multiple pieces of research have shown a higher stiffness of healthy cells compared to cancer cells including one of the previous studies done by our group which have also found that cancer cell tends to become stiffer after exposing to fluid shear stress. The discovery of this cellular behavior and novel numerical quantification method of cell failure could advance the study of cancer cell membrane failure, cellular matrix structure, response to mechanical loadings and potentially foundation in developing new treatment for cancer other than destructive chemical treatment.
Experimental and numerical study on failure strength of aspirated cell membrane
Abstract
Details
- Title: Subtitle
- Experimental and numerical study on failure strength of aspirated cell membrane
- Creators
- Yang Wu - University of Iowa
- Contributors
- Sarah C. Vigmostad (Advisor)Jia Lu (Advisor)Michael D. Henry (Committee Member)
- Resource Type
- Thesis
- Degree Awarded
- Master of Science (MS), University of Iowa
- Degree in
- Mechanical Engineering
- Date degree season
- Autumn 2017
- DOI
- 10.17077/etd.wakdnfcd
- Publisher
- University of Iowa
- Number of pages
- xii, 49 pages
- Copyright
- Copyright © 2017 Yang Wu
- Language
- English
- Description illustrations
- color illustrations
- Description bibliographic
- Includes bibliographical references (pages 48-49).
- Public Abstract (ETD)
Cancer, which was responsible for 595,690 cases of death in 2016 according to national statistics, has surpassed heart disease and became the most severe cause of death in the United States. Among all cancer related cases, 90% cancer death was due to cancer cell metastasis which is caused by transformed cancer cells reproduced from the primary tumor, travel and relocate causing destructive damage to vital organs in that area. To develop an in-depth understanding of failure property, the current research uses a micropipette aspiration system to elaborate hydrostatic pressure to the cell causing the membrane to deform and eventually rupture. Based on our observation, the prostate cancer cells (PC-3) deformed into a deflated and flattened shape under higher hydrostatic pressure while prostate epithelial cells (PrEC LH) cells generate a spherical and rounded shape. By analyzing stress data generated from processed microscopic images, our study shows that cancer cells may be not only softer than healthy cells but also more susceptible to rupture. The alteration of shape of the aspirated membrane directly affected the stress distribution over the membrane and as a result, provoked membrane failure. Multiple pieces of research have shown a higher stiffness of healthy cells compared to cancer cells including one of the previous studies done by our group which have also found that cancer cell tends to become stiffer after exposing to fluid shear stress. The discovery of this cellular behavior and novel numerical quantification method of cell failure could advance the study of cancer cell membrane failure, cellular matrix structure, response to mechanical loadings and potentially foundation in developing new treatment for cancer other than destructive chemical treatment.
- Academic Unit
- Mechanical Engineering
- Record Identifier
- 9983777001802771