Access 89 Pages of Medical Manufacturing Resources for Free
Free guides, design standards, and case studies built for engineers, QA teams, and medical innovators.
In this all-encompassing guide, you'll delve into:
- ● FDA and ISO compliance checklists
- ● Step-by-step design parameters for SLS and SLA printing.
- ● Case studies from real medical device teams.
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Free resource library with guides, compliance checklists, and case studies built for engineers and QA teams.
Get 89 Pages of Medical Manufacturing Expertise!
Stay ahead in medical product design with practical knowledge from engineers and compliance specialists. The CADimensions Medical Resource Library gives you 89 pages of proven information. Inside you will find design standards, QC workflows, and case studies that help reduce risk, shorten development cycles, and support safer products.
Compliance Confidence
Reference FDA and ISO requirements with detailed checklists.
Design Efficiency
Use SLS and SLA design parameters to save time and limit rework.
Real Results
See how medical device teams improved workflows through case studies.
How can 3D printed anatomical models improve surgical planning?
This guide explains how to transform CT and MRI scans into accurate 3D printed models for patient-specific care. It shows how anatomical models improve preoperative planning, reduce operating room time, and lower patient risk. The guide also highlights how physical models support better patient consent and understanding, with applications across specialties including orthopedics, cardiology, and oncology.
Fill Out The Form To AccessHow do healthcare innovators manage SLA quality control?
This guide provides a step-by-step quality control framework for healthcare teams using SLA 3D printing. It covers workflow checks, calibration schedules, and validation protocols to meet regulatory expectations. You’ll also find methods to ensure dimensional accuracy, patient safety, and reproducibility, along with troubleshooting strategies and documentation practices that support compliance.
Fill Out The Form To AccessHow can common processes improve innovation and compliance in medical manufacturing?
This case study shows how a Fortune 100 medical device manufacturer improved both compliance and innovation by adopting Dassault Systèmes PLM solutions. By standardizing processes across global teams, the company reduced costs, eliminated silos, and created a single source of truth for product data. The results include faster speed to market, better decision-making, and improved quality management that meets global regulatory requirements.
Fill Out The Form To AccessHow do you design successful parts for Fuse Series SLS printing?
This guide provides the essential design rules for selective laser sintering on Fuse Series printers. It covers minimum dimensions for walls, holes, pins, and assemblies to ensure accuracy and durability, along with recommendations for embossed and engraved features. You’ll also find best practices for part orientation, powder removal, and material-specific considerations for Nylon, TPU, and Polypropylene powders. The result is a complete reference for engineers aiming to optimize medical-grade parts for SLS production.
Fill Out The Form To AccessHow are 3D scanners transforming medical applications?
This guide introduces SMARTTECH3D med, a structured-light 3D scanning system designed for safe, accurate digitization of the human body. It explains how clinicians use scanning to plan surgeries, design prosthetics, analyze wounds, and monitor healing with precision down to 0.01 mm. The material also highlights broader applications, from patient comfort and repeatable measurements to security, identification, and even computer graphics.
Fill Out The Form To AccessHow is PA11 helping deliver custom orthotics at scale?
This case study explains how GO Orthotics adopted Stratasys H350 printers and High Yield PA11 material to produce patient-specific foot orthotics with greater efficiency. It shows how 3D printing reduced cost per part, increased throughput, and allowed intricate design features that improve both comfort and durability. The guide also highlights PA11’s renewable origin and high-performance properties, helping clinicians meet therapeutic needs while advancing more sustainable manufacturing.
Fill Out The Form To AccessHow is stereolithography enabling serial production for medical devices?
This case study explores how Hirsh Prototypes uses the Stratasys Neo450s printer with Somos BioClear material to produce medical device components at scale. It explains how SLA technology delivers fine detail, dimensional accuracy, and biocompatibility for applications such as endoscopes and catheters. The study also highlights how Neo printers provide consistent, reliable output that meets strict quality requirements, allowing production of 20,000 parts with repeatability, efficiency, and profitability.
Fill Out The Form To AccessHow are 3D printed parts improving sleep disorder treatment?
This case study highlights the Somnosync sleep mask, developed by DQBD and GEMTEC, which uses Stratasys H350 3D printed components. The device provides contactless REM phase detection, helping diagnose and treat sleep disorders while enabling therapies like lucid dreaming. With a slim, ergonomic design, customizable fit, and durable PA11 snap-fit parts, the mask demonstrates how additive manufacturing can deliver user comfort, regulatory-ready durability, and innovative healthcare solutions.
Fill Out The Form To AccessHow do 3D printed insoles perform compared to traditional methods?
This white paper evaluates the mechanical properties of rigid insole shells made with Formlabs Fuse 1+ Nylon 11, HP Multi Jet Fusion PA11, and traditionally machined polypropylene. Through static and dynamic 3-point bend tests, Ross flex tests, and hand-flex trials, the study shows how SLS-printed insoles withstand millions of flex cycles, resist humidity, and maintain durability under real-world conditions. The results confirm that 3D printed insoles deliver comparable or superior performance to traditional methods while enabling customization and efficient production.
Fill Out The Form To AccessGet access to our FREE medical library today!
Stay ahead in medical product design with practical knowledge from engineers and compliance specialists. The CADimensions Medical Resource Library gives you 89 pages of proven information. Inside you will find design standards, QC workflows, and case studies that help reduce risk, shorten development cycles, and support safer products.