猪器官制成的“生物纸”未来可再生人类心脏

目前科学家最新发明生物活性“生物纸”（图中所示），其原料来自于猪和牛器官，每片生物纸保持着器官所具有的特殊细胞属性。　　

据国外媒体报道，“生物纸”薄而柔韧，可以折叠成鸟等动物形状，并能用于再生受损器官。

从当地屠宰场获取废弃的猪和牛器官，科学家制造了这种具有生物活性的纸张，它能再生人类卵巢、子宫、肾脏、肝脏、肌肉或者心脏蛋白质。同时，卵巢生物纸能够恢复女性癌症患者或者更年期女性的正常激素分泌。

同时，生物纸还将刺激那些遭受创伤或者先天缺陷患者的肌肉细胞生长，据悉，这项研究是意外发现的。

美国西北大学科学家提取能够形成器官和组织的细胞，将它们制造成柔韧的生物纸。研究人员是通过猪和牛的器官制造生物纸，并使用洗涤剂移除这些细胞，该过程将产生叫做“细胞外基质”的天然结构蛋白，之后细胞外基质干燥成粉末，然后加工成生物纸。

每种类型的生物纸都包含原始有机器官剩余的生物化学物质和蛋白质结构，它们能够刺激细胞以某种方式表现。这篇研究报告能够支持成人干细胞的生长，并能帮助身体再生特殊器官。

美国西北大学科学家从牲畜器官中提取细胞，可用于制造轻薄柔韧的生物纸。

带有卵泡的卵巢生物纸植入手臂下方，可用于恢复女性癌症患者甚至更年期女性的正常激素分泌。　　

研究报告作者、西北大学费恩伯格医学院外科手术教授拉米勒·沙阿（Ramille Shah）说：“当它干燥时，就像是普通的办公用纸，这是一种新类型生物材料，具有组织工程和再生医学的潜力，以及用于药物发现和治疗学，它具有通用功能和手术兼容性。”　　据了解，一次事故性溢漏引发这项独特的发明，研究报告作者亚当·亚库斯（Adam Jakus）试图制造一种 3D 打印卵巢墨水，类似于之前用于修复和再生骨骼、肌肉和神经组织的其它 3D 打印材料，当他擦干事故溢漏物质时，卵巢墨水已形成一个干燥的薄片。

亚库斯博士说：“当我试着拿起这张薄片时，它变得非常结实，此时我脑洞大开，意味着它可用于制造其它器官，它们很容易像纸一样，进行存储、折叠、滚动、缝合和切割。”

生物纸的扁平柔韧属性非常重要，尤其当医生希望在手术中对其进行塑形和操控。亚库斯说：“生物纸就像一个内部绷带一样，带有卵泡的卵巢生物纸可植入手臂下方，用于恢复癌症患者或者更年期女性的正常激素分泌。”

研究报告合著作者、泰萨·伍德拉夫（Tessa Woodruff）说：“这可能提供另一个机会恢复年轻癌症患者的正常激素功能，他们经常在化疗和放射性治疗过程损失激素功能。令人惊讶的是，像肾脏、肝脏、心脏和子宫的动物副产物，能够转化为像纸一样的生物材料。”

BIOACTIVE “TISSUE PAPERS” INVENTED BY SHAH TEAM LAB PUBLISHED IN ADVANCED FUNCTIONAL MATERIALS    https://news.northwestern.edu/stories/2017/august/origami-organs-can-potentially-regenerate-tissues/

（来源：新浪科技 2017-08-15）

BIOACTIVE “TISSUE PAPERS” INVENTED BY SHAH TEAM LAB PUBLISHED IN ADVANCED FUNCTIONAL MATERIALS

 http://shahlab.northwestern.edu/

‘Origami organs’ can potentially regenerate tissues

Bioactive tissue paper made from organs is pliable enough to fold into origami structures

August 07, 2017 | By Marla Paul

CHICAGO - Northwestern Medicine scientists and engineers have invented a range of bioactive “tissue papers” made of materials derived from organs that are thin and flexible enough to even fold into an origami bird. The new biomaterials can potentially be used to support natural hormone production in young cancer patients and aid wound healing.   

The tissue papers are made from structural proteins excreted by cells that give organs their form and structure. The proteins are combined with a polymer to make the material pliable.    

In the study, individual types of tissue papers were made from ovarian, uterine, kidney, liver, muscle or heart proteins obtained by processing pig and cow organs. Each tissue paper had specific cellular properties of the organ from which it was made.

The article describing the tissue paper and its function was published Aug. 7 in the journal Advanced Functional Materials.

“This new class of biomaterials has potential for tissue engineering and regenerative medicine as well as drug discovery and therapeutics,” corresponding author Ramille Shah said. “It’s versatile and surgically friendly.”

Shah is an assistant professor of surgery at the Feinberg School of Medicine and an assistant professor of materials science and engineering at McCormick School of Engineering. She also is a member of the Simpson Querrey Institute for BioNanotechnology.

For wound healing, Shah thinks the tissue paper could provide support and the cell signaling needed to help regenerate tissue to prevent scarring and accelerate healing.

The tissue papers are made from natural organs or tissues. The cells are removed, leaving the natural structural proteins – known as the extracellular matrix – that then are dried into a powder and processed into the tissue papers. Each type of paper contains residual biochemicals and protein architecture from its original organ that can stimulate cells to behave in a certain way.    

In the lab of reproductive scientist Teresa Woodruff, the tissue paper made from a bovine ovary was used to grow ovarian follicles when they were cultured in vitro. The follicles (eggs and hormone-producing cells) grown on the tissue paper produced hormones necessary for proper function and maturation.

“This could provide another option to restore normal hormone function to young cancer patients who often lose their hormone function as a result of chemotherapy and radiation,” Woodruff, a study coauthor, said. 

A strip of the ovarian paper with the follicles could be implanted under the arm to restore hormone production for cancer patients or even women in menopause.

Woodruff is the director of the Oncofertility Consortium and the Thomas J. Watkins Memorial Professor of Obstetrics and Gynecology at Feinberg.

In addition, the tissue paper made from various organs separately supported the growth of adult human stem cells. Scientists placed human bone marrow stem cells on the tissue paper, and all the stem cells attached and multiplied over four weeks.

"That’s a good sign that the paper supports human stem cell growth,” said first author Adam Jakus, who developed the tissue papers. “It’s an indicator that once we start using tissue paper in animal models it will be biocompatible.” 

The tissue papers feel and behave much like standard office paper when they are dry, Jakus said. Jakus simply stacks them in a refrigerator or a freezer. He even playfully folded them into an origami bird.

“Even when wet, the tissue papers maintain their mechanical properties and can be rolled, folded, cut and sutured to tissue,” he said.

Jakus was a Hartwell postdoctoral fellow in Shah’s lab for the study and is now chief technology officer and cofounder of the startup company Dimension Inx, LLC, which was also cofounded by Shah. The company will develop, produce and sell 3-D printable materials primarily for medical applications. The Intellectual Property is owned by Northwestern University and will be licensed to Dimension Inx.

An Accidental Spill Sparked Invention

An accidental spill of 3-D printing ink in Shah’s lab by Jakus sparked the invention of the tissue paper. Jakus was attempting to make a 3-D printable ovary ink similar to the other 3-D printable materials he previously developed to repair and regenerate bone, muscle and nerve tissue. When he went to wipe up the spill, the ovary ink had already formed a dry sheet.

“When I tried to pick it up, it felt strong,” Jakus said. “I knew right then I could make large amounts of bioactive materials from other organs. The light bulb went on in my head. I could do this with other organs.” 

“It is really amazing that meat and animal by-products like a kidney, liver, heart and uterus can be transformed into paper-like biomaterials that can potentially regenerate and restore function to tissues and organs,” Jakus said. “I’ll never look at a steak or pork tenderloin the same way again.” 

Monica Laronda, who was a postdoctoral fellow in Woodruff’s lab during the study, also is a coauthor. She is now an assistant professor of pediatrics at Feinberg and a researcher at the Stanley Manne Children’s Research Institute, Ann & Robert H Lurie Children's Hospital of Chicago. Laronda and Woodruff also are members of the Robert H. Lurie Comprehensive Cancer Center of Northwestern University. 

The research was supported by grant P50 HD076188-02 from the Center for Reproductive Health After Disease of the National Centers for Translational Research in Reproduction and Infertility, Google and the Hartwell Foundation. 

Topics: Engineering, Feinberg School of Medicine, Grants, Innovation, McCormick School of Engineering, Northwestern Medicine, Research, Video

https://news.northwestern.edu/stories/2017/august/origami-organs-can-potentially-regenerate-tissues/