Corey Neu /bme/ en NSF: Engineers examine the mechanical forces that influence cell development /bme/2022/01/20/nsf-engineers-examine-mechanical-forces-influence-cell-development <span>NSF: Engineers examine the mechanical forces that influence cell development</span> <span><span>Anonymous (not verified)</span></span> <span><time datetime="2022-01-20T09:30:45-07:00" title="Thursday, January 20, 2022 - 09:30">Thu, 01/20/2022 - 09:30</time> </span> <div> <div class="imageMediaStyle focal_image_wide"> <img loading="lazy" src="/bme/sites/default/files/styles/focal_image_wide/public/article-thumbnail/nsf_article.jpeg?h=b718709e&amp;itok=lYtjwUOp" width="1200" height="600" alt="Nuclear deformation research"> </div> </div> <div role="contentinfo" class="container ucb-article-categories" itemprop="about"> <span class="visually-hidden">Categories:</span> <div class="ucb-article-category-icon" aria-hidden="true"> <i class="fa-solid fa-folder-open"></i> </div> <a href="/bme/taxonomy/term/9"> Research </a> </div> <div role="contentinfo" class="container ucb-article-tags" itemprop="keywords"> <span class="visually-hidden">Tags:</span> <div class="ucb-article-tag-icon" aria-hidden="true"> <i class="fa-solid fa-tags"></i> </div> <a href="/bme/taxonomy/term/17" hreflang="en">2021</a> <a href="/bme/taxonomy/term/75" hreflang="en">Corey Neu</a> <a href="/bme/taxonomy/term/93" hreflang="en">Media Coverage</a> <a href="/bme/taxonomy/term/29" hreflang="en">Spring</a> </div> <div class="ucb-article-content ucb-striped-content"> <div class="container"> <div class="paragraph paragraph--type--article-content paragraph--view-mode--default"> <div class="ucb-article-content-media ucb-article-content-media-above"> <div> <div class="paragraph paragraph--type--media paragraph--view-mode--default"> </div> </div> </div> <div class="ucb-article-text d-flex align-items-center" itemprop="articleBody"> </div> </div> </div> </div> <div>Engineers at the University of Colorado Boulder and Purdue University, funded in part by the U.S. National Science Foundation, explored how mechanical forces guide the early cell development of organisms.</div> <script> window.location.href = `https://www.nsf.gov/discoveries/disc_summ.jsp?WT_mc_id=USNSF_1&amp;cntn_id=304252&amp;utm_medium=email&amp;utm_source=govdelivery`; </script> <h2> <div class="paragraph paragraph--type--ucb-related-articles-block paragraph--view-mode--default"> <div>Off</div> </div> </h2> <div>Traditional</div> <div>0</div> <div>On</div> <div>White</div> Thu, 20 Jan 2022 16:30:45 +0000 Anonymous 237 at /bme The Conversation: Mechanical forces in a beating heart affect its cells’ DNA, with implications for development and disease /bme/2021/12/21/conversation-mechanical-forces-beating-heart-affect-its-cells-dna-implications <span>The Conversation: Mechanical forces in a beating heart affect its cells’ DNA, with implications for development and disease</span> <span><span>Anonymous (not verified)</span></span> <span><time datetime="2021-12-21T13:28:39-07:00" title="Tuesday, December 21, 2021 - 13:28">Tue, 12/21/2021 - 13:28</time> </span> <div> <div class="imageMediaStyle focal_image_wide"> <img loading="lazy" src="/bme/sites/default/files/styles/focal_image_wide/public/article-thumbnail/file-20211208-23-3udfl3.png?h=f294d448&amp;itok=_7PDWZoG" width="1200" height="600" alt="Contracting heart cells exert forces on their genetic material "> </div> </div> <div role="contentinfo" class="container ucb-article-categories" itemprop="about"> <span class="visually-hidden">Categories:</span> <div class="ucb-article-category-icon" aria-hidden="true"> <i class="fa-solid fa-folder-open"></i> </div> <a href="/bme/taxonomy/term/9"> Research </a> </div> <div role="contentinfo" class="container ucb-article-tags" itemprop="keywords"> <span class="visually-hidden">Tags:</span> <div class="ucb-article-tag-icon" aria-hidden="true"> <i class="fa-solid fa-tags"></i> </div> <a href="/bme/taxonomy/term/17" hreflang="en">2021</a> <a href="/bme/taxonomy/term/75" hreflang="en">Corey Neu</a> <a href="/bme/taxonomy/term/33" hreflang="en">Fall</a> <a href="/bme/taxonomy/term/93" hreflang="en">Media Coverage</a> <a href="/bme/taxonomy/term/95" hreflang="en">The Conversation</a> </div> <div class="ucb-article-content ucb-striped-content"> <div class="container"> <div class="paragraph paragraph--type--article-content paragraph--view-mode--default"> <div class="ucb-article-content-media ucb-article-content-media-above"> <div> <div class="paragraph paragraph--type--media paragraph--view-mode--default"> </div> </div> </div> <div class="ucb-article-text d-flex align-items-center" itemprop="articleBody"> </div> </div> </div> </div> <div>In a new study published in the journal Nature Biomedical Engineering, Professor Corey Neu and his team found that mechanical forces can reorganize the genetic material inside the nucleus of heart cells and affect how they develop and function.</div> <script> window.location.href = `https://theconversation.com/mechanical-forces-in-a-beating-heart-affect-its-cells-dna-with-implications-for-development-and-disease-173484`; </script> <h2> <div class="paragraph paragraph--type--ucb-related-articles-block paragraph--view-mode--default"> <div>Off</div> </div> </h2> <div>Traditional</div> <div>0</div> <div>On</div> <div>White</div> Tue, 21 Dec 2021 20:28:39 +0000 Anonymous 221 at /bme Nuclear deformation research could advance artificial tissue engineering /bme/2021/12/02/nuclear-deformation-research-could-advance-artificial-tissue-engineering <span>Nuclear deformation research could advance artificial tissue engineering</span> <span><span>Anonymous (not verified)</span></span> <span><time datetime="2021-12-02T11:40:02-07:00" title="Thursday, December 2, 2021 - 11:40">Thu, 12/02/2021 - 11:40</time> </span> <div> <div class="imageMediaStyle focal_image_wide"> <img loading="lazy" src="/bme/sites/default/files/styles/focal_image_wide/public/article-thumbnail/tissues_with_diverse_structural_and_mechanical_characteristics.png?h=3013d0de&amp;itok=t5YmtC92" width="1200" height="600" alt="Tissues"> </div> </div> <div role="contentinfo" class="container ucb-article-categories" itemprop="about"> <span class="visually-hidden">Categories:</span> <div class="ucb-article-category-icon" aria-hidden="true"> <i class="fa-solid fa-folder-open"></i> </div> <a href="/bme/taxonomy/term/45"> Graduate 鶹Ժ </a> <a href="/bme/taxonomy/term/9"> Research </a> </div> <div role="contentinfo" class="container ucb-article-tags" itemprop="keywords"> <span class="visually-hidden">Tags:</span> <div class="ucb-article-tag-icon" aria-hidden="true"> <i class="fa-solid fa-tags"></i> </div> <a href="/bme/taxonomy/term/17" hreflang="en">2021</a> <a href="/bme/taxonomy/term/75" hreflang="en">Corey Neu</a> <a href="/bme/taxonomy/term/33" hreflang="en">Fall</a> <a href="/bme/taxonomy/term/63" hreflang="en">Homepage News</a> </div> <span>Rachel Leuthauser</span> <div class="ucb-article-content ucb-striped-content"> <div class="container"> <div class="paragraph paragraph--type--article-content paragraph--view-mode--default"> <div class="ucb-article-content-media ucb-article-content-media-above"> <div> <div class="paragraph paragraph--type--media paragraph--view-mode--default"> <div> <div class="imageMediaStyle large_image_style"> <img loading="lazy" src="/bme/sites/default/files/styles/large_image_style/public/article-image/mouse_embryo.png?itok=jrjsH_Ff" width="1500" height="897" alt="Mouse embryo"> </div> </div> </div> </div> </div> <div class="ucb-article-text d-flex align-items-center" itemprop="articleBody"> <div><div class="ucb-box ucb-box-title-hidden ucb-box-alignment-right ucb-box-style-fill ucb-box-theme-white"> <div class="ucb-box-inner"> <div class="ucb-box-title"></div> <div class="ucb-box-content"><br> Professor Corey Neu and PhD graduate Benjamin Seelbinder.<br> <strong>Header image:</strong>&nbsp;Tissues with diverse structural and mechanical characteristics. </div> </div> </div> <p>Biomedical Engineering <a href="/mechanical/corey-neu" rel="nofollow">Professor Corey Neu</a>&nbsp;and Benjamin Seelbinder (PhDMech’19) wanted to answer two fundamental questions. How do cells adapt to their environment and how does a mechanical environment influence a cell?</p> <p>What they discovered during their more than six years of research has the potential to tackle major health obstacles and advance artificial tissue engineering.&nbsp;</p> <p>Their research, <a href="https://www.nature.com/articles/s41551-021-00823-9" rel="nofollow">published on the cover of&nbsp;<em>Nature Biomedical Engineering</em></a>&nbsp;on Dec. 2&nbsp;and titled "Nuclear Deformation Guides Chromatin Reorganization in Cardiac Development and Disease,"&nbsp;found that mechanical forces guide the development of a cell through the reorganization of its nucleus and could influence future pathologies.</p> <p>“We were interested in the development of healthy cells, and the health of a cell requires that the nucleus senses mechanical forces in a particular way,” Neu said.</p> <p>One of those forces is tension, Neu and Seelbinder explained. Tension stretches the cell in a defined way, resulting in the reorganization of the nucleus. That modification changes the expression of genes, which could indicate certain diseases in patients.</p> <p>This understanding of the cell developmental process also helped Neu and Seelbinder conclude that scientists could influence a cell themselves. Researchers can change the environment by manipulating the tension moving through a cell, which could be used to create more authentic artificial tissues.</p> <h2>The discovery</h2> <div class="ucb-box ucb-box-title-hidden ucb-box-alignment-right ucb-box-style-fill ucb-box-theme-white"> <div class="ucb-box-inner"> <div class="ucb-box-title"></div> <div class="ucb-box-content"><br> <strong>Left:&nbsp;</strong>Mouse embryo. <strong>Middle:</strong>&nbsp;Close-up of embryonic heart. <strong>Right:&nbsp;</strong>Close-up of embryonic cardiomyocyte nucleus. </div> </div> </div> <p>Seelbinder, who is now a postdoctoral associate at the <a href="http://mpi-cbg.de/home/" rel="nofollow">Max Planck Institute of Molecular Cell Biology and Genetics</a>, first discovered that mechanical forces shape nuclei while studying the cardiovascular cells of embryotic mice.</p> <p>“The nucleus was a very interesting thing to investigate when looking at force integration in cells because it is big, contains all of the gene information and has mechanical connections to all parts of the cell,” Seelbinder said. “We just started exploring and found there is a clear pattern that should be investigated more closely.”</p> <p>Seelbinder used heart cells because they contract on their own, making them the perfect model to study nuclear deformation. The cells are known to be very sensitive to their mechanical environment.</p> <p>Seelbinder noticed the contractions caused the nucleus to be stiff, rigid and dense in certain areas, he and Neu explained. In other areas, the nucleus appeared to be loosely organized.</p> <p>“There is a certain well-defined structure that the nucleus takes on;&nbsp;it is not just a soft gel,” Neu said. “There are also defined forces that are happening because suddenly the heart cells are contracting during development. The mechanics are fascinating – the forces are not just happening, they are being transferred to the cell substructures.”</p> <p>Neu and Seelbinder concluded the contractions result from mechanical forces and tension moving through cells. Those contractions reorganize each cell’s chromatin, which are some structural elements of the nucleus.</p> <div class="ucb-box ucb-box-title-hidden ucb-box-alignment-right ucb-box-style-fill ucb-box-theme-white"> <div class="ucb-box-inner"> <div class="ucb-box-title"></div> <div class="ucb-box-content"><br> Embryonic cardiomyocytes that contract&nbsp;show&nbsp;a change in nuclear organization, while cardiomyocytes on stiff substrates do&nbsp;not. </div> </div> </div> <p>Neu said the discovery launched a major collaborative effort centered at the College of Engineering and Applied Science. With help from researchers at the University of Colorado’s <a href="/mechanical/" rel="nofollow">Paul M. Rady Department of Mechanical Engineering</a>, the&nbsp;<a href="/mcdb/" rel="nofollow">Department of Molecular, Cellular and Developmental Biology</a>, the <a href="https://www.upenn.edu/" rel="nofollow">University of Pennsylvania</a> and <a href="https://www.purdue.edu/" rel="nofollow">Purdue University</a>, they confirmed that the same patterns occur in humans.</p> <ul> <li>Jump to: <a href="#Co-authors" rel="nofollow">Co-authors based at CU Boulder</a></li> </ul> <h2>Impacts on human health</h2> <p>Understanding how the chromatin in a nucleus is organized is a fundamental subject area. The location of genes within the nucleus is important for their expression and has paramount implications.</p> <p>Neu and Seelbinder also found animals that experienced nuclear reorganization later in life developed pathology with symptoms that an older human with cardiovascular disease or hypertension might experience.</p> <p>When looking at adult mice with induced hypertrophy, they observed the gene expression established during development reorganized again in the adult stage. That lead to the loss of cell identity and cell activity. In the case of heart cells, contractions stopped, leading to cardiac arrest.</p> <p>“It is not just about the development, but the role of the mechanics and the organization of the nucleus is also really important at later stages of life,” Neu said. “When someone develops heart disease, for example.”</p> <div class="ucb-box ucb-box-title-hidden ucb-box-alignment-right ucb-box-style-fill ucb-box-theme-white"> <div class="ucb-box-inner"> <div class="ucb-box-title"></div> <div class="ucb-box-content"><br> <strong>Top:&nbsp;</strong>Human heart samples from patients with no heart failure (NHF).<br> <strong>Bottom:&nbsp;</strong>Human heart samples from patients suffering from non-ischaemic cardiomyopathy (NICM). </div> </div> </div> <p>The researchers studied patients with heart conditions like cardiomyopathy, a disease that makes it harder for the heart to pump blood. Seelbinder explained that the condition was well-suited for their work because cardiomyopathy changes the heart’s mechanical environment.</p> <p>Cardiomyopathy thickens the heart muscle, causing fewer&nbsp;contractions and less nuclear deformation. The chromatin reorganizes and cellular identity declines.</p> <p>“If you use markers like how much blood does the heart pump and correlate it over the reorganization of the nucleus, it was highly predictive,” Seelbinder said. “That means you can take a little bit of the tissue, look at the organization of the nucleus and can tell whether that organ functions well or not.”</p> <p>Seelbinder and Neu said those findings became one of the most impressive things they discovered. It opened the door not just for diagnostic potentials, but for therapeutic possibilities as well.</p> <h2>Artificial tissue engineering</h2> <p>Neu and Seelbinder’s research could help change the landscape for artificial tissue engineering. Their work fills in gaps in understanding of the relationship between mechanical forces and cell development in regenerative medicine.</p> <div class="ucb-box ucb-box-title-hidden ucb-box-alignment-right ucb-box-style-fill ucb-box-theme-white"> <div class="ucb-box-inner"> <div class="ucb-box-title"></div> <div class="ucb-box-content"> <p><a href="www.nature.com/articles/s41551-021-00823-9" rel="nofollow"></a> </p></div> </div> </div> <p>Neu said if researchers know how the heart develops – what triggers the transition from a collection of cells to a fully functional organ or organism – there is the potential to mimic developmental processes.</p> <p>Their research is a blueprint of the developmental path, which could also set the stage for new regenerative technologies and the possibility of organ-on-chip models used in drug discovery.</p> <p>“Pharmaceutical companies may want to screen new kinds of drugs, for example,” Neu said. “If you have a replicated heart tissue with the correct nuclei and function, if you can create a miniaturized model of a person, then it may be possible to screen candidate drugs that might be most effective in humans.”</p> <hr> <p><em><a id="Co-authors" rel="nofollow"></a>Neu and Seelbinder’s paper titled “Nuclear deformation guides chromatin reorganization in cardiac development and disease” is published in Nature Biomedical Engineering, <a href="https://www.nature.com/articles/s41551-021-00823-9" rel="nofollow">available to read here</a>.</em></p> <p><em>Co-authors from CU Boulder’s Department of Mechanical Engineering include former post-doctoral researcher <a href="https://www.engr.colostate.edu/me/faculty/dr-soham-ghosh/" rel="nofollow">Soham Ghosh</a> – who is now a faculty member at Colorado State University – PhD candidates Stephanie Schneider and Adrienne Scott, and <a href="/mechanical/sarah-calve" rel="nofollow">Professor Sarah Calve</a>. </em></p> <p><em>Molecular, Cellular and Developmental Biology post-doctoral associate Eduard Casas, PhD candidate Alison Swearingen and <a href="/mcdb/justin-brumbaugh" rel="nofollow">Professor Justin Brumbaugh</a>&nbsp;co-authored the paper as well.</em><br> &nbsp;</p></div> </div> </div> </div> </div> <div>Biomedical Engineering Professor Corey Neu and Benjamin Seelbinder's (PhDMech’19) work, now published in Nature Biomedical Engineering, looks at how cells adapt to their environment and how a mechanical environment influences a cell. Their research has the potential to tackle major health obstacles.</div> <h2> <div class="paragraph paragraph--type--ucb-related-articles-block paragraph--view-mode--default"> <div>Off</div> </div> </h2> <div>Traditional</div> <div>0</div> <div>On</div> <div>White</div> Thu, 02 Dec 2021 18:40:02 +0000 Anonymous 205 at /bme Groundbreaking biomedical engineering innovators awarded $1.5 million in grants at Lab Venture Challenge finals /bme/2021/11/12/groundbreaking-biomedical-engineering-innovators-awarded-15-million-grants-lab-venture <span>Groundbreaking biomedical engineering innovators awarded $1.5 million in grants at Lab Venture Challenge finals</span> <span><span>Anonymous (not verified)</span></span> <span><time datetime="2021-11-12T12:11:33-07:00" title="Friday, November 12, 2021 - 12:11">Fri, 11/12/2021 - 12:11</time> </span> <div> <div class="imageMediaStyle focal_image_wide"> <img loading="lazy" src="/bme/sites/default/files/styles/focal_image_wide/public/article-thumbnail/untitled-1.png?h=bcda7fc6&amp;itok=UUytX8xg" width="1200" height="600" alt="Bottenus and Neu"> </div> </div> <div role="contentinfo" class="container ucb-article-categories" itemprop="about"> <span class="visually-hidden">Categories:</span> <div class="ucb-article-category-icon" aria-hidden="true"> <i class="fa-solid fa-folder-open"></i> </div> <a href="/bme/taxonomy/term/5"> Entrepreneurship </a> </div> <div role="contentinfo" class="container ucb-article-tags" itemprop="keywords"> <span class="visually-hidden">Tags:</span> <div class="ucb-article-tag-icon" aria-hidden="true"> <i class="fa-solid fa-tags"></i> </div> <a href="/bme/taxonomy/term/17" hreflang="en">2021</a> <a href="/bme/taxonomy/term/75" hreflang="en">Corey Neu</a> <a href="/bme/taxonomy/term/33" hreflang="en">Fall</a> <a href="/bme/taxonomy/term/77" hreflang="en">Nick Bottenus</a> </div> <div class="ucb-article-content ucb-striped-content"> <div class="container"> <div class="paragraph paragraph--type--article-content paragraph--view-mode--default"> <div class="ucb-article-content-media ucb-article-content-media-above"> <div> <div class="paragraph paragraph--type--media paragraph--view-mode--default"> </div> </div> </div> <div class="ucb-article-text d-flex align-items-center" itemprop="articleBody"> </div> </div> </div> </div> <div>Biomedical Engineering Professors Nick Bottenus and Corey Neu each won the Lab Venture Challenge 2021 Award in Biosciences.</div> <script> window.location.href = `/venturepartners/2021/11/08/groundbreaking-cu-boulder-innovators-awarded-15-million-grants-lab-venture-challenge`; </script> <h2> <div class="paragraph paragraph--type--ucb-related-articles-block paragraph--view-mode--default"> <div>Off</div> </div> </h2> <div>Traditional</div> <div>0</div> <div>On</div> <div>White</div> Fri, 12 Nov 2021 19:11:33 +0000 Anonymous 193 at /bme