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Medical 3-D Printing.

Bryant Furlow

    Radiologic Technology
    |May 14, 2017
    PubMed
    Summary
    This summary is machine-generated.

    Three-dimensional printing is revolutionizing medicine by enabling personalized devices like prosthetics and surgical tools. This technology, aided by diagnostic imaging, allows for precise, patient-specific medical applications, including flexible implants.

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    Area of Science:

    • Biomedical Engineering
    • Medical Technology
    • Materials Science

    Background:

    • Three-dimensional printing (3-D printing) is a transformative technology with broad applications.
    • Its integration into healthcare spans research, drug production, clinical practice, and dentistry.
    • 3-D printing holds significant potential for advancing precision and personalized medicine.

    Purpose of the Study:

    • To highlight the role and impact of 3-D printing in various medical fields.
    • To emphasize the development of patient-specific medical devices and applications.
    • To underscore the synergy between diagnostic imaging and 3-D model creation.

    Main Methods:

    • Utilizing diagnostic imaging modalities to generate data for 3-D printing.
    • Employing 3-D printing techniques to fabricate patient-specific medical devices.
    • Exploring the production of both rigid and flexible materials for prosthetics.

    Main Results:

    • 3-D printing is advancing the creation of customized prosthetics, stents, splints, and fixation devices.
    • The technology is significantly impacting medical education, surgical planning, and treatment decision-making.
    • Successful production of flexible, soft-tissue-like prosthetics is achievable.

    Conclusions:

    • Three-dimensional printing is a key enabler of personalized medicine.
    • The technology facilitates the development of tailored solutions for diverse clinical needs.
    • Continued advancements promise further integration and innovation in healthcare.