亚洲国产成人精品久久久国产成人一区二区三区综合区精品久久久中文字幕一区,国产a一级无码毛片一区二区三区,久久久无码,国产成人无码精品久免费,精品欧美国产一区二区三区不卡,国产成人一区二区三区影院,国产精品久久久久久,欧美日韩精品一区二区三区,欧美日韩在线精品一区二区三区激情福利综合,在线观看亚洲精品福利片,亚洲欧美日韩久久精品,亚洲欧美日韩国产成人精品,亚洲国产欧美日韩精品一区二区三区,欧美日韩国产成人高清视频

熱門搜索:A549    293T 金黃色葡萄球菌 大腸桿菌 AKK菌
購物車 1 種商品 - 共0元
當(dāng)前位置: 首頁 > 行業(yè)資訊 > Scientists recreate blood-brain barrier defect outside the b

Scientists recreate blood-brain barrier defect outside the b

 Date:

June 6, 2019
Source:
Cedars-Sinai Medical Center
Summary:

Scientists have recreated a critical brain component, the blood-brain barrier, that functioned as it would in the individual who provided the cells to make it. Their achievement provides a new way to make discoveries about brain disorders and, potentially, predict which drugs will work best for an individual patient.

Scientists can't make a living copy of your brain outside your body. That's the stuff of science fiction. But in a new study, they recreated a critical brain component, the blood-brain barrier, that functioned as it would in the individual who provided the cells to make it. Their achievement -- detailed in a study published today in the peer-reviewed journal Cell Stem Cell -- provides a new way to make discoveries about brain disorders and, potentially, predict which drugs will work best for an individual patient.

The blood-brain barrier acts as a gatekeeper by blocking toxins and other foreign substances in the bloodstream from entering brain tissue and damaging it. It also can prevent potential therapeutic drugs from reaching the brain. Neurological disorders such as amyotrophic lateral sclerosis (Lou Gehrig's disease), Parkinson's disease and Huntington's disease, which collectively affect millions of people, have been linked to defective blood-brain barriers that keep out biomolecules needed for healthy brain activity.

For their study, a team led by Cedars-Sinai investigators generated stem cells known as induced pluripotent stem cells, which can produce any type of cell, using an individual adult's blood samples. They used these special cells to make neurons, blood-vessel linings and support cells that together make up the blood-brain barrier. The team then placed the various types of cells inside Organ-Chips, which recreated the body's microenvironment with the natural physiology and mechanical forces that cells experience within the human body.

The living cells soon formed a functioning unit of a blood-brain barrier that functions as it does in the body, including blocking entry of certain drugs. Significantly, when this blood-brain barrier was derived from cells of patients with Huntington's disease or Allan-Herndon-Dudley syndrome, a rare congenital neurological disorder, the barrier malfunctioned in the same way that it does in patients with these diseases.

While scientists have created blood-brain barriers outside the body before, this study further advanced the science by using induced pluripotent stem cells to generate a functioning blood-brain barrier, inside an Organ-Chip, that displayed a characteristic defect of the individual patient's disease.

The study's findings open a promising pathway for precision medicine, said Clive Svendsen, PhD, director of the Cedars-Sinai Board of Governors Regenerative Medicine Institute. "The possibility of using a patient-specific, multicellular model of a blood-brain barrier on a chip represents a new standard for developing predictive, personalized medicine," he said. Svendsen, professor of Medicine and Biomedical Sciences, was the senior author of the study.

The research combined the innovative stem cell science from investigators at Cedars-Sinai in Los Angeles with the advanced Organs-on-Chips technology of Emulate, Inc. in Boston. Emulate's Human Emulation System recreates the microenvironment that cells require to exhibit an unprecedented level of biological function and to behave like they do in the human body. The system consists of instrumentation, software apps, and Organ-Chips, about the size of AA batteries, with tiny fluidic channels lined with tens of thousands of living human cells.

The co-first authors of the study are Gad Vatine, PhD, from Ben-Gurion University of the Negev in Beer Sheva, Israel, a former postdoctoral scientist at Cedars-Sinai; Riccardo Barrile, PhD, of Emulate, a former postdoctoral fellow at Cedars-Sinai; and Michael Workman, a PhD student in the Cedars-Sinai Graduate School of Biomedical Sciences.

The research is one of several collaborative projects involving Cedars-Sinai and Emulate, Inc., which In February 2018 announced a joint Patient-on-a-Chip program to help predict which disease treatments would be most effective based on a patient's genetic makeup and disease variant. The program is an initiative of Cedars-Sinai Precision Health, whose goal is to drive the development of the newest technology and best research, coupled with the finest clinical practice, to rapidly enable a new era of personalized health.

Disclosure: Cedars-Sinai owns a minority stock interest in Emulate, Inc. An officer of Cedars-Sinai serves on Emulate's board of directors. Emulate provided no financial support for this research. Six of the study's authors are employees and shareholders of Emulate.

Funding: Research reported in this publication was supported by the National Institute of Neurological Disorders and Stroke and the National Center for Advancing Translational Sciences of the National Institutes of Health under award number 1UG3NS105703, the California Institute for Regenerative Medicine, The ALS Association, the Sherman Family Foundation and the Israel Science Foundation.

Story Source:

Materials provided by Cedars-Sinai Medical CenterNote: Content may be edited for style and length.


Journal Reference:

  1. Gad D. Vatine, Riccardo Barrile, Michael J. Workman, Samuel Sances, Bianca K. Barriga, Matthew Rahnama, Sonalee Barthakur, Magdalena Kasendra, Carolina Lucchesi, Jordan Kerns, Norman Wen, Weston R. Spivia, Zhaohui Chen, Jennifer Van Eyk, Clive N. Svendsen. Human iPSC-Derived Blood-Brain Barrier Chips Enable Disease Modeling and Personalized Medicine ApplicationsCell Stem Cell, 2019; 24 (6): 995 DOI: 10.1016/j.stem.2019.05.011
  2.  
南开区| 延吉市| 湘乡市| 上杭县| 射洪县| 金沙县| 高唐县| 大田县| 定南县| 昆明市| 安化县| 远安县| 库车县| 南安市| 万盛区| 梁河县| 西和县| 榆中县| 富源县| 太白县| 乾安县| 诸暨市| 沅江市| 夹江县| 普兰县| 新民市| 巴里| 乃东县| 和龙市| 阿城市| 武汉市| 叙永县| 卫辉市| 民和| 辛集市| 华容县| 芒康县| 新津县| 石城县| 青河县| 绥德县|