URL: <http://3dprint.com/58602/3d-printed-heart-organoid/>
They call them “organoids,” and they’re 3D printed, beating cardiac cells which are sure to inspire scientists and biologists while raising ethical concerns among critics intent on stopping the progress of the technology.
The groundbreaking research program aimed at creating human organs is the result of a project at the Wake Forest Baptist Medical Center Institute for Regenerative Medicine, and it features heart cells which are made functional and shaped using a highly-specialized 3D printer.
"“The heart organoid beats because it contains specialized cardiac cells and because those cells are receiving the correct environmental cues,” said Ivy Mead, a Wake Forest graduate student and member of the research team, in an interview. “We give them a special medium and keep them at the same temperature as the human body, and that makes them beat. We can also stimulate the miniature organ with electrical or chemical cues to alter the beating patterns. Also, when we grow them in three-dimensions it allows for them to interact with each other more easily, as they would in the human body.”
Current research there is using an adapted version of ink-jet printing technology to “print” skin for soldiers with life-threatening burns in which skin cells are placed directly into a cartridge along with essential support material and then directly applied to a soldier’s wound. The Wake Forest team have also developed a unique 3D printer to produce organ and tissue prototypes.
In a pair of other projects, the Wake Forest team has created functional heart cells which relied on both stem cells and “engineered artificial heart tissue.”
The project is ‘bleeding edge’ stuff which takes existing human heart cells and then “animates” them in the lab.
Anthony Atala, M.D., is the Director of the Wake Forest Institute for Regenerative Medicine. He’s also W.H. Boyce Professor and Chair of the Department of Urology there, and he’s a practicing surgeon and a researcher in regenerative medicine. While his current work focuses on growing new human cells, tissues, and organs, Dr. Atala and his team say the fact that they’ve created life-size human organs — including bladders and vaginas which have remained fully functional years after being implanted — has no plans to create a full-sized, functional human heart.
The team are also responsible for the “body-on-a-chip” program, a miniaturized human system which will ultimately be used to model the response of the human body to contagions like the Ebola virus or deadly warfare gases such as sarin and ricin. Funding for that program came from the Space and Naval Warfare Systems Center and the US Defense Threat Reduction Agency.
“Miniature lab-engineered, organ-like hearts, lungs, livers, and blood vessels — linked together with a circulating blood substitute — will be used both to predict the effects of chemical and biologic agents and to test the effectiveness of potential treatments,” Atala adds.
They call them “organoids,” and they’re 3D printed, beating cardiac cells which are sure to inspire scientists and biologists while raising ethical concerns among critics intent on stopping the progress of the technology.
The groundbreaking research program aimed at creating human organs is the result of a project at the Wake Forest Baptist Medical Center Institute for Regenerative Medicine, and it features heart cells which are made functional and shaped using a highly-specialized 3D printer.
"“The heart organoid beats because it contains specialized cardiac cells and because those cells are receiving the correct environmental cues,” said Ivy Mead, a Wake Forest graduate student and member of the research team, in an interview. “We give them a special medium and keep them at the same temperature as the human body, and that makes them beat. We can also stimulate the miniature organ with electrical or chemical cues to alter the beating patterns. Also, when we grow them in three-dimensions it allows for them to interact with each other more easily, as they would in the human body.”
Current research there is using an adapted version of ink-jet printing technology to “print” skin for soldiers with life-threatening burns in which skin cells are placed directly into a cartridge along with essential support material and then directly applied to a soldier’s wound. The Wake Forest team have also developed a unique 3D printer to produce organ and tissue prototypes.
In a pair of other projects, the Wake Forest team has created functional heart cells which relied on both stem cells and “engineered artificial heart tissue.”
The project is ‘bleeding edge’ stuff which takes existing human heart cells and then “animates” them in the lab.
Anthony Atala, M.D., is the Director of the Wake Forest Institute for Regenerative Medicine. He’s also W.H. Boyce Professor and Chair of the Department of Urology there, and he’s a practicing surgeon and a researcher in regenerative medicine. While his current work focuses on growing new human cells, tissues, and organs, Dr. Atala and his team say the fact that they’ve created life-size human organs — including bladders and vaginas which have remained fully functional years after being implanted — has no plans to create a full-sized, functional human heart.
The team are also responsible for the “body-on-a-chip” program, a miniaturized human system which will ultimately be used to model the response of the human body to contagions like the Ebola virus or deadly warfare gases such as sarin and ricin. Funding for that program came from the Space and Naval Warfare Systems Center and the US Defense Threat Reduction Agency.
“Miniature lab-engineered, organ-like hearts, lungs, livers, and blood vessels — linked together with a circulating blood substitute — will be used both to predict the effects of chemical and biologic agents and to test the effectiveness of potential treatments,” Atala adds.