Chung-Ang University Researchers Use
Biomolecule-Loaded Metal-Organic Frameworks Nanopatterns to Aid Artificial Stem
Cell Differentiation
A new platform mimics live cellular environment to
guide stem cell differentiation outside the body without needing complex
experimental steps
Stem cells give rise to all kinds of cells and tissues in
our body through a conversion process called “differentiation.” However, guiding
stem cell differentiation in the laboratory is a complex and laborious process.
Now, researchers from Korea have developed a novel platform that uses metal-organic
framework nanoparticle–embedded nanopit arrays to enable highly efficient stem cell
differentiation without complex experimental steps. This could open up new
possibilities in regenerative stem cell therapy.
Title: Neural stem cell.
Researchers from Korea
have developed a novel platform that promotes highly efficient stem cell differentiation
outside the body using metal-organic framework nanoparticle – embedded in
nanopit arrays. This could open doors to treatment of neurologic
disorders such as Alzheimer's and Parkinson’s diseases.
Image credit: CodonAUG
from openverse.
License
type: CC
BY-SA 2.0.
Image link: https://wordpress.org/openverse/image/57bfe2ed-9cc7-47f8-ac0a-5e2e72413586
Stem cells are essentially our body’s raw materials –
cells that give rise to all other cells and tissues with specialized functions.
The conversion into specific cells occurs through a process called
“differentiation,” in which stem cells divide to form daughter cells. This lends
itself to practical applications in regenerative therapy, where functional
healthy cells generated from stem cells can be used to cure injuries and
cellular damages in our body.
However, things are easier said than done. Performing
stem cell differentiation in the laboratory requires meticulous preparation and
addition of differentiation factors into a cell cultivation medium, a laborious
and time-consuming process. Moreover, it is largely reliant on the researcher’s
skill. In light of this, a new platform that facilitates a stable supply of
differentiation factors over a long period is highly desirable.
In a new study, researchers from Korea, led by Associate
Professor Tae-Hyung Kim of school of integrative engineering at Chung-Ang
university, came up with an ingenious solution. They developed a novel platform
based on metal-organic frameworks (MOFs), hybrid crystalline porous materials constructed
using metal ions and organic ligands (ions/molecules attached to the metal
ion). Due to their porous nature, MOFs are excellent for trapping and releasing
molecules of interest over a long period of time. This gave the team the idea to
use MOFs for storing and releasing biocompatible nanoparticles necessary for
stem cell differentiation. This paper was made available online on 20 April
2022 and was published
in Volume 8, Issue 16 of the journal Science
Advances on 20 April 2022.
In their study, the team chose neural stem cells as a
proof of concept and embedded nanoparticles loaded with retinoic acid, an
essential component for neuronal differentiation, into the nanocrystalline MOF,
nUiO-67. There was, however, one issue to be considered. “Adding nanoparticles directly to the cell cultivation medium may cause
safety issues when used for therapeutic purposes and can also cause damage to
the nanoparticle structures owing to the presence of redox enzymes and reactive
oxygen species (ROS) in the intracellular environment,” explains Dr. Kim.
To get around this problem, the team separated the
stem cells from MOFs by creating periodic pattern of nanopit arrays using a
technique called “laser interference lithography.”
By optimizing these nanopit arrays such that each
array captured a single MOF, the team came up with the platform called “single
metal-organic framework (MOF) nanoparticle–embedded nanopit arrays (SMENA)” that
could automatically convert stem cells into neurons.
SMENA offered two big advantages over the conventional
method for in vitro stem cell
differentiation. Firstly, it obviated all the complex experimental steps and
typical issues related to cell contamination and batch-to-batch variation. Secondly,
and surprisingly, the continuous and stable supply of differentiation factors made
for accelerated differentiation, resulting in approximately 40-fold higher expression
of neuronal cell markers (indicating the generation of neurons) compared to
that for standard protocols.
These findings have excited the team about the future
prospects of SMENA. “The platform developed in our study could facilitate
and accelerate the use of various stem cell sources for clinical applications
and drug screening. The functional cells produce through SMENA can be used to
treat various diseases and disorders, including Alzheimer's and Parkinson’s
diseases,” speculates Dr. Kim. The
paper was also recently featured as a research highlight in Nature Reviews
Materials by the Associate Editor, Charlotte Allard.
We certainly hope Dr. Kim’s
visions about SMENA are realized soon!
Reference
Authors
Title of original paper
Journal |
Yeon-Woo
Cho1, Seohyeon Jee2, Intan Rosalina Suhito1,
Jeong-Hyeon Lee1, Chun Gwon Park3,4, Kyung
Min Choi 2,5, Tae-Hyung Kim1
Single
metal-organic framework–embedded nanopit arrays: A new way to control neural stem
cell differentiation
Science
Advances |
|
|
DOI
Affiliations |
1School of Integrative Engineering, Chung-Ang
University 2Department of Chemical and
Biological Engineering, Sookmyung Women’s University 3Department of Biomedical Engineering, SKKU
Institute for
Convergence, Sungkyunkwan University (SKKU) 4Department of Intelligent
Precision Healthcare Convergence, SKKU Institute for Convergence, Sungkyunkwan
University (SKKU) 5LabInCube Co. Ltd. |
About Chung-Ang University
Chung-Ang University is a private
comprehensive research university located in Seoul, South Korea. It was started
as a kindergarten in 1918 and attained university status in 1953. It is fully
accredited by the Ministry of Education of Korea. Chung-Ang University conducts
research activities under the slogan of “Justice and Truth.” Its new vision for
completing 100 years is “The Global Creative Leader.” Chung-Ang University
offers undergraduate, postgraduate, and doctoral programs, which encompass a
law school, management program, and medical school; it has 16 undergraduate and
graduate schools each. Chung-Ang University’s culture and arts programs are
considered the best in Korea.
Website: https://neweng.cau.ac.kr/index.do
About Associate Professor Tae-Hyung
Kim
Tae-Hyung Kim is an Associate Professor at
Chung-Ang University's School of Integrative Engineering in Korea. He received
his B.S. in Chemical Engineering and Ph.D. in Chemical and Biomolecular
Engineering from Sogang University, Korea. He was a postdoctoral researcher at
the Department of Chemistry and Chemical Biology at Rutgers University, USA.
His study focuses on the non-destructive and non-invasive regulation and
monitoring of cellular processes using different nanomaterials. He has over 90
peer-reviewed publications to his credit. He serves on the editorial boards of
several international journals, notably as Managing Editor of Nano Convergence
and Associate Editor of BioChip Journal.