The typical properties of our made to order 3Dresyns are tested with the following standards:

Testing standards

The properties of our made to order 3Dresyns are tested with the following standards:

  • Tensile strength at yield and ultimate ISO 527-2
  • Young´s modulus ISO 527-2
  • % Elongation at yield and ultimate ISO 527-2
  • Flexural strength at yield and ultimate ISO 178
  • Shore hardness ISO 868
  • Deflection Temperature HDT@45 ISO 75

Our biocompatible 3D resins for biomedical, orthodontic and dental applications have been developed, evaluated and passed the quality requirements of ISO 10993-1, ISO 7405 and ISO 18562-1-4 after have been properly printed and postprocessed with the appropriate printer and postprocessing units, instrumentation, processes and protocols. Nevertheless, medical device manufacturers are responsible of certifying their medical devices since the quality and biocompatibility of a medical device depends significantly of the printing and postprocessing specifications, which are beyond the control and responsibility of any 3D resin supplier. For more info read: About Certification of biomedical devices and food packaging

Biocompatible 3D resin testings

  • Ultimate flexural strength ISO 20795-1
  • Young´s or Flexural modulus ISO 20795-1
  • Sorption  ISO 20795-1
  • Solubility ISO 20795-1
  • Residual monomer ISO 20795-1
  • Biocompatibility: cytotoxicity ISO 10993-1
  • Biocompatibility: mutagenicity ISO 10993-1
  • Biocompatibility: erythema or edema reactions ISO 10993-1
  • Biocompatibility: sensitizer ISO 10993-1
  • Biocompatibility: systemic toxicity ISO 10993-1

    About biocompatibility and mechanical properties 

    Photopolymer 3D resins are photoreactive resin systems, which depending on their design, the functional additives used, the degree of cure (% conversion from monomer to polymer), the postcuring and cleaning process used for removing residuals and byproducts, can have increased or decreased biocompatibility and mechanical properties.

    Their overall results can vary significantly because depend on the final 3D resin tuning or customisation to different printing, postcuring and post processing specifications, which affect the overall biocompatibility and performance properties of printed materials. 

    Photopolymer 3D resins cannot be considered finished materials, such as conventional plastics or polymers, because their biocompatibility and functionality "performance" depend on their tuning, adjustment, or customisation to the specifications of the chosen printing setup. The degree of cure and cleansing of any residuals and reaction byproducts, depend significantly on the printer power, the postcuring, cleansing and overall post processing specifications and protocols.

    Different printers have different specifications, such as light wavelength (365, 385 and the most commonly used 405 nm) and light power across the resin tank, which can range from 0.3 to 50 mW/cm2, or even higher depending on the chosen SLA, DLP, LCD or Inkjet printer. 

    Our made to order 3D resins require the use of different dosage of our photo accelerant Fine Tuners FT for printing them with printers having different light wavelengths and power. Depending on the dosage of photo acelerant and other functional additives and colors,  higher or lower printing speed, resolution, mechanical properties and biocompatiblity can be achieved.

    Due to the different printing specifications, or setups variability, 3D resin customisation for each printer setup is required for maximum biocompatibility and overall performance.

    As example, our made to order multifunctional 3Dresyns for different printers may have different rheology / viscosity and mechanical properties for each particular product reference (not for different lots of the same final SKU). This is the reason for not disclosing all the properties specifications as fixed values, such as the viscosity of some 3D resins because the final dosages of our Fine Tuners and functional additives can affect the viscosity as well as other properties, such as light fastness (yellowing), biocompatibility and mechanical properties.

    About the "typical" properties of 3D resins

    The physical properties of our 3Dresyns are not absolute because depend on few variables. Properties are either shown in value ranges, or with values above ">" or below "<" certain x units since our published data reflects typical properties which can obtained with different SLA, DLP and LCD printers, postcuring  and postprocessing conditions, such as:

    • low power printers, such as LCD printers, yield:
      •  superior mechanical properties (lower brittleness), higher elongation, tensile and flexural strength, and lower rigidity "Young´s modulus" and HDT than higher power printers, such as laser printers.
    • very high power printers, such as strong laser printers eg Formlabs Form 2 & 3, yield:
      • inferior mechanical properties (brittleness), lower elongation, tensile and flexural strength, and higher rigidity "Young´s modulus" and HDT than lower power printers, such as LCD printers.
    • Discover some of our consulting services for choosing the best printer setup for your specific needs
    • for any 3D resin, cleansing, postcuring and postprocessing conditions affect the resulting overall performance properties. Read our Instructions For Use IFU 

    About biocompatibility and mechanical performance variability

    Overall biocompatibility and mechanical results can be significantly affected by the sum of known variables, as well as by unknown, or not easily identifiable variables:

    • Printing power
      • too fast kinetics increase shrinkage, brittleness, tensile and flexural strength, rigidity "Young´s modulus" and HDT significantly. Read: Tg and HDT of 3D resins
    • Printing orientation
      • vertical, horizontal, and different angle printing of dog bones and bars for testing eg elongation, tensile and flexural strengths provide significantly different quantitative values due to anisotropy since 3D printed materials are typically printed layer by layer exhibiting lower or higher interlayer weakness and mechanical properties in the X, Y and Z directions
    • Cleaning chemicals
    • Postcuring
      • wavelength, power, dry or by dipping, with or without O2, postcuring time affect, etc affect the degree of cure and the biocompatibility 
      • a too short postcuring can decrease biocompatibility
      • an excessive postcuring cycle causes yellowing and brittleness 
    • Other

      We have the following analytical services which can be contracted for helping you to design the right material for your specifications.

      If you need support for designing your optimum printer setup discover our full 3D printing system consulting services