Computer-Aided Design (CAD) and Computer-Aided Manufacturing (CAM) in Prosthetics and Orthotics: Difference between revisions
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== Introduction == | == Introduction == | ||
The field of prosthetics and orthotics (P&O) utilises a wide variety of methods to provide custom devices to patients. Similar to how thermoplastics revolutionised a field mostly grounded in wood carving, leatherwork, and metal bending[cite], digitisation introduced a new strategy for fabricating P&O devices. | |||
Computer-aided design and computer-aided manufacturing (CAD/CAM) is an umbrella term for many technologies that use computer software to design and manufacture both prototypes and definitive devices. In P&O, CAD/CAM technologies include: | |||
== | * 3D scanners | ||
* 3D visualisation softwares | |||
* CAD software | |||
** Can be specifically designed to perform prosthetic/orthotic modifications | |||
** Can include finite element analysis (FEA) | |||
* 3D carvers | |||
** subtractive manufacturing | |||
* 3D printers | |||
** additive manufacturing | |||
== History == | |||
CAD/CAM was introduced to P&O over three decades ago. One of the first reports of CAD/CAM, published in 1985, described a “software package” for the manufacture of transtibial sockets[cite]. The second author of this publication went on to develop Vorum, the first and longest-standing CAD/CAM company dedicated to O&P. Vorum was initially focused on 3D carvers, which uses a milling machine to carve a foam block based on a CAD drawing[cite]. | |||
The first attempts of 3D printing in a P&O-specific application were reported in the early 1990s, about a decade after the first published patent of any 3D printing technology. These studies described the fabrication of transtibial socket using stereolithography (SLA)[cite] and fused deposition modelling (FDM) with the Squirt-Shape(™) printer [cite]. | |||
The prevalence of CAD/CAM technologies in P&O has grown over the past decades with the advent of new scanners, modification softwares, 3D carvers, 3D printers, and printing materials. Many saw 3D scanning and printing as a way to reduce costs and increase access to P&O devices. However, with increasing complexity of softwares and technologies, CAD/CAM is not always synonymous with lower cost [cite]. | |||
Current literature indicates a steady increase in adoption of CAD/CAM technologies, but not to the point of overtaking traditional methods. A 2021 study indicates increased interest in CAD/CAM from both developed and developing countries. However, developing countries have faced challenges in adoption such as accessibility, resources, qualified practitioners, and gaps in knowledge[cite]. In the United States, the 2022 Practice Analysis indicates that 30% of prostheses incorporate CAD/CAM, increasing from 23% in the 2015 study [cite]. | |||
== Current Applications == | |||
Currently, CAD/CAM technologies are used in the fabrication of all kinds of diagnostic and definitive devices, including: | |||
* Lower limb prostheses | |||
* Upper limb prostheses | |||
* Custom prosthetic covers | |||
* Lower limb orthoses | |||
* Upper limb orthoses | |||
* Scoliosis braces | |||
* Other spinal orthoses | |||
* Cranial remolding orthoses (CROs) | |||
* Other | |||
== Current Applications == | |||
== Current Applications == | |||
== Current Applications == | |||
== Current Applications == | |||
== Current Applications == | |||
== Current Applications == | |||
== Current Applications == | |||
== Resources == | == Resources == |
Revision as of 17:42, 20 October 2022
Original Editor - User Name
Top Contributors - Nicolette Chamberlain-Simon
Introduction[edit | edit source]
The field of prosthetics and orthotics (P&O) utilises a wide variety of methods to provide custom devices to patients. Similar to how thermoplastics revolutionised a field mostly grounded in wood carving, leatherwork, and metal bending[cite], digitisation introduced a new strategy for fabricating P&O devices.
Computer-aided design and computer-aided manufacturing (CAD/CAM) is an umbrella term for many technologies that use computer software to design and manufacture both prototypes and definitive devices. In P&O, CAD/CAM technologies include:
- 3D scanners
- 3D visualisation softwares
- CAD software
- Can be specifically designed to perform prosthetic/orthotic modifications
- Can include finite element analysis (FEA)
- 3D carvers
- subtractive manufacturing
- 3D printers
- additive manufacturing
History[edit | edit source]
CAD/CAM was introduced to P&O over three decades ago. One of the first reports of CAD/CAM, published in 1985, described a “software package” for the manufacture of transtibial sockets[cite]. The second author of this publication went on to develop Vorum, the first and longest-standing CAD/CAM company dedicated to O&P. Vorum was initially focused on 3D carvers, which uses a milling machine to carve a foam block based on a CAD drawing[cite].
The first attempts of 3D printing in a P&O-specific application were reported in the early 1990s, about a decade after the first published patent of any 3D printing technology. These studies described the fabrication of transtibial socket using stereolithography (SLA)[cite] and fused deposition modelling (FDM) with the Squirt-Shape(™) printer [cite].
The prevalence of CAD/CAM technologies in P&O has grown over the past decades with the advent of new scanners, modification softwares, 3D carvers, 3D printers, and printing materials. Many saw 3D scanning and printing as a way to reduce costs and increase access to P&O devices. However, with increasing complexity of softwares and technologies, CAD/CAM is not always synonymous with lower cost [cite].
Current literature indicates a steady increase in adoption of CAD/CAM technologies, but not to the point of overtaking traditional methods. A 2021 study indicates increased interest in CAD/CAM from both developed and developing countries. However, developing countries have faced challenges in adoption such as accessibility, resources, qualified practitioners, and gaps in knowledge[cite]. In the United States, the 2022 Practice Analysis indicates that 30% of prostheses incorporate CAD/CAM, increasing from 23% in the 2015 study [cite].
Current Applications[edit | edit source]
Currently, CAD/CAM technologies are used in the fabrication of all kinds of diagnostic and definitive devices, including:
- Lower limb prostheses
- Upper limb prostheses
- Custom prosthetic covers
- Lower limb orthoses
- Upper limb orthoses
- Scoliosis braces
- Other spinal orthoses
- Cranial remolding orthoses (CROs)
- Other
Current Applications[edit | edit source]
Current Applications[edit | edit source]
Current Applications[edit | edit source]
Current Applications[edit | edit source]
Current Applications[edit | edit source]
Current Applications[edit | edit source]
Current Applications[edit | edit source]
Resources[edit | edit source]
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