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Bioartificial Organ Manufacturing Technologies.

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Summary
This summary is machine-generated.

Advanced bioartificial organ manufacturing technologies, including automated 3D printing, are reviewed. These innovations promise to create custom organ substitutes, enhancing human health and lifespan.

Keywords:
bioartificial organ manufacturingbiomaterialsrapid prototyping (RP)stem cellsthree-dimensional (3D) printing

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Area of Science:

  • Biotechnology and Biomedical Engineering
  • Regenerative Medicine
  • Biofabrication

Background:

  • Bioartificial organ manufacturing utilizes bionic principles to create human organ substitutes.
  • Significant advancements in organ manufacturing technologies have occurred over the past decade.
  • Existing technologies range from fully automated to handmade approaches, each with unique benefits and drawbacks.

Purpose of the Study:

  • To provide the first comprehensive review of advanced bioartificial organ manufacturing technologies.
  • To categorize organ manufacturing technologies based on their level of automation.
  • To highlight promising future directions in the field.

Main Methods:

  • Classification of organ manufacturing technologies into three automation levels: fully automated, semi-automated, and handworked.
  • Review of combined multi-nozzle three-dimensional printing as a key automated technique.
  • Analysis of the assembly of personal cells and biomaterials for organoid construction.

Main Results:

  • Identification of three distinct categories of organ manufacturing technologies based on automation.
  • Demonstration of three-dimensional printing's potential for automated, personalized organ substitute fabrication.
  • Recognition of the advantages and disadvantages inherent in each automation level.

Conclusions:

  • Advanced bioartificial organ manufacturing technologies, particularly automated 3D printing, represent a significant leap forward.
  • These technologies offer the potential for creating bespoke organ substitutes for patients with organ failure.
  • The reviewed technologies are poised to substantially improve public health and increase average human lifespan.