纳米技术检测骨愈合干细胞
研究人员开发了一种使用纳米材料来识别和丰富骨干干细胞的新方法 - 发现最终可能导致主要骨折的新治疗方法。
研究人员表明,植入年轻羊羔的实验室创建的心脏瓣膜能够在接收方内增长。
Using 3D printing, researchers replicated an aneurysm in vitro and performed an endovascular repair procedure on the printed aneurysm.
Bioprinted 3D cardiac patches could reverse scar formation and promote myocardial regeneration after heart attacks.
Researchers have found a way to enhance radiation therapy using novel iodine nanoparticles.
研究人员建造了一种纳米级硼酸盐生物活性玻璃,可有效降低硼酸盐生物制剂的生物毒性,并改善了玻璃的生物相容性。
研究人员设计了一种装置,可以在进行开放心脏手术的区域内安全和准确地喷洒水凝胶。
Researchers have developed biocompatible hydrogel materials can rapidly recover from mechanical stress.
研究人员开发了一种装置,该装置提供了一种使用通过微创球囊导管施加的电激活的胶水贴片来密封血管中的撕裂和孔的侵入方式。
松动髋植入植入物可能对骨骼产生重大损害,并且简单的更换在运动期间不足以承载负荷。研究人员已经转向生物印刷,以解决这个问题。
Researchers have repaired traumatic injuries to the skin and bones in a rat model using bioprinting during surgery.
A researcher has designed a robotic surgical platform that steers surgical catheters through electromagnetic fields.
Scientists have developed an injectable gel that can attach to various kinds of soft internal tissues and repair tears resulting from an accident or trauma.
研究人员创造了生命形式,自组装来自单细胞的身体,不需要肌肉细胞移动。它们更快,寿命更长,现在可以记录信息。
Researchers have developed an injectable hydrogel that could help repair and prevent further damage to the heart muscle after a heart attack.
The patch, which can be folded around surgical tools, may someday be used in robotic surgery to repair tissues and organs.
Researchers have achieved promising results with a new cancer therapy using focused ultrasound (FUS) and ionizing radiation.
外科医生将很快拥有一个强大的新工具,用于创造第一个全尺寸的人类心灵的全尺寸3D生物制版模型。
Researchers have developed a groundbreaking process for multi-material 3D printing of lifelike models of the heart's aortic valve and the surrounding structures.
Researchers have developed a surgical robot that improves precision and control of teleoperated surgical procedures.
科学家表明,对小鼠的皮肤施加“时间压力”可以创造一种提供药物的新方法。
Researchers have developed a tiny, 3D-printed technology that can be assembled like Lego blocks and help repair broken bones and soft tissue.
Surgeons have implanted a patient suffering from a congenital defect with a novel, absorbable soft tissue reconstruction scaffold.
使用微创技术被称为“滚筒3D Bioplinting”,在小鼠中成功创建了新的肌肉。
研究人员在患者中迈出了3D印刷生物组织,因为它们开发了专门制定的生物新利18官方墨水,专为直接印刷在体内。
普渡大学团队提出3D身体映射技术,以帮助治疗癌症和其他医疗问题损坏的器官和细胞。
Bioengineers have developed a prototype patch that does the same job as crucial aspects of heart tissue.
Researchers have developed a novel methodology to provide non-invasive analysis of meniscal implants.
研究人员创造了生物传感器技术,可能有助于导致治疗帕金森病的安全干细胞疗法。
Scientists are using 3D technology to help rebuild the faces of cancer patients, those hurt in accidents and people born with complex facial deformities.
A new 3D printing platform is able to fabricate multi-component scaffolds that “steal from nature” to engineer tissues organized like native tissues.
A new technique called SWIFT (sacrificial writing into functional tissue) allows 3D printing of large, vascularized human organ building blocks.
Researchers have developed an extremely fast optical method for sculpting complex shapes in stem-cell-laden hydrogels and then vascularizing the resulting tissue.
Researchers have developed a technique to 3D bioprint collagen, allowing them to fabricate fully functional components of the human heart.
脊髓损伤:在大鼠模型中,新型脚手架模仿自然解剖学和增强干细胞的治疗;该方法可扩展到人类。
Not all broken bones heal. But one scientist at the University of Arizona hopes to remedy that problem using a combination of 3D printing and adult stem cells.
Research project is aimed at improving therapeutic options for both rare and common diseases, including supporting methods to improve editing the human genome.
在一个世界首映式中,一支研究人员团队开发了一种磁性3D印刷的微观机器人,可以将电池携带到活动物的精确位置。
Swinburne研究有助于使用最新技术在干细胞科学中修复软骨损伤的新解决方案。