Flexdym Pellet Polymer for Mass Production
The Flexdym pellets are ideal for experienced users who have developed a marketable product using this technology and wish to begin mass production or 3D printing. The pellets are sold at different prices based on weight ranges: 1-10 kg, 11-1,000 kg, and 1,001-10,000 kg.
General
Features & Benefits
Microfluidics needs biocompatible and scalable materials for mass production. Academics use PDMS for prototyping, but it lacks scalability, and industry experts prefer thermoplastics, but they are expensive and require harsh bonding treatments. Flexdym pellets solve all of those problems, it is a biocompatible material for microfluidic biomedical devices that is scalable and compatible with injection molding and 3D printing. Flexdym is transparent, has low molecular sorption, and is ideal for cell culture and diagnostic applications. It simplifies commercialization by enabling the use of the same material for prototyping and mass production.
Flexdym is:
- Biocompatible (ISO 10993 parts 4, 5, 6, 10, 11 and UPS Class VI)
- Self-sealing at ambient temperature
- Cost-effective
- Compatible with optical assays: low fluorescence, optically clear
- No absorption, permeable to gas and not to liquid
- Resistant to tearing: unlike PDMS, it will not tear apart when you manipulate it.
Flexdym Pellets benefits:
- Low-cost option for mass production
- Available per kilo
- Ideal for commonly used injection molding or 3D printing
- Can be molded at small scales, suing our Sublym or a hot press, and at large scales using injection molding or 3D printing
- The injection molding process allows Flexdym devices to be mass produced
General benefits of Flexdym polymer:
Flexdym:
- is an alternative to any other chip material in the classical applications of microfluidic chips
- Combines the best properties of elastomers
- Acts as a pressure sensitive adhesive
- Can be recycled and reused
- Has tunable bonding strength
This polymer is particularly interesting in life sciences: its biocompatibility makes it simple to design any experiment. The self-sealing technology is not destructive, unlike plasma, vacuum, or high temperature used to seal other chips. It ensures that biological agents remain viable and functional in your device. Flexdym enables the integration of cells, proteins, enzymes, or any bio-reagents before assembly.
Optical or fluorescence measurements in a chip require using materials that show a high level of transparency (almost 90% transmittance), primarily in the UV and visible range. Flexdym fulfills these conditions. Indeed, it reaches the limit of 50% transmittance (which we considered an acceptable transparency limit) at a wavelength of 295 nm. Flexdym features similar properties to the most transparent materials. This transparency window is sufficiently wide for many fluorophores, particularly the most popular fluorescent Cy3 and Cy5 dyes, which have excitation wavelengths at 550 and 650 nm and emission wavelengths at 570 and 670 nm, respectively.
Top Flexdym Applications
- Cell culture: Flexdym has lower sorption properties and gas permeability
- Reversible Seals: Flexdym can bond reversibly to a variety of substrates, acting as an excellent seal on devices
- Valves: Flexdym has an elongation of 700%
- Skin-interfacing: Flexdym is a pressure-sensitive adhesive that naturally sticks to the skin
Content
1x 1 kg Flexdym pellet
Specifications
Mechanical properties
| Hardness Shore A |
35 |
| Specific Gravity |
0.9 g/ cm3 |
| Tear Strength | 15 kN/m |
| Tensile Strength | 7.6 MPa |
| Elongation | 720 % |
| Molding Temperature | 115 °C - 185 °C |
| Molding Pressure | 35 Torr |
Resistance to solvants
| Chemicals | Resistance |
|
Acids |
R |
| Bases | R |
| Fluorinated Oils | R |
| Methanol/Ethanol | R |
| Carboxilic Acid | Swell |
| Hydrocarbons | NR |
| Oil | Swell |
Surface properties
| Advancing Contact Angle | 105° ± 4° |
| Receding Contact Angle |
88° ± 4° |
| Contact Angle after Plasma Treatment |
< 38° |
Room temperature bonding
| Materials | Time (hours) | Burst Pressure |
| Flexdym-Flexdym | 1h | 600 mbar |
| Flexdym-Glass | 1h | 400 mbar |
Heat-assisted bonding
| Substrate | Bonding Temperature (°C) | Time (min) | Bonding Strength (burst pressure) |
| Flexdym | 80-85 | 30 | Excellent (5.5 bar) |
| PS, COC | 95 | 60 | Excellent |
| PC, PMMA | 95 | 60 | Moderate |
| Glass | 95 | 60-120 | Moderate, non-permanent (720 mbar) |
Documentation
Application Notes Flexdym Bonding
Application Notes Flexdym Connecting
Application Notes Flexdym Molding
References
- Lachaux et al., Lab on a Chip 2016, L2017 Jul 25;17(15):2581-2594. doi: 10.1039/c7lc00488e
- Perrault et al. Insights on Polymers for Microfluidics Applied to Biomedical Applications
- Overview of Materials for Microfluidic Applications, IntechOpen 2016
- Roy et al., Lab on a Chip 2015, Lab Chip, 2015,15, 406-416, doi:10.1039/C4LC00947A
FAQ
-
Do I need a heat press for Flexdym?
Yes, most heat presses or hot embossers should work. A press that can mold at a pressure of at least 7 psi / 0.5 bar or above is ideal (a vacuum-assisted press is not required). You may have to make minor adjustments to optimize molding your chips. We offer a user-friendly compact microfabrication kit with a plug-and-play system: Sublym.
- What size range is reliably micro-molded with Flexdym?
The minimal microchannel width is 50 nm, and the depth range is 50 nm - 1 mm. However, microchannels between 1 µm and 1 mm are recommended with an aspect ratio (height to width) of 3:1 or less. Some customers have also achieved submicron structures and higher aspect ratios.
- Which mold does Flexdym work best with?
Common molds used in the field of microfluidics work well. These include fragile molds, such as photoresists (e.g., SU‒8), and etched glass and silicon molds. Temperature-resistant epoxy and traditional metallic molds (aluminum, nickel, brass) also work. Silicones such as PDMS also work; however, choose a stiff silicone grade of at least 20 Shore A durometers above Flexdym. We offer EPMO epoxy material to fabricate robust mold suited (up to 6’’ size) for Flexdym molding without the need to treat it with an anti-sticking agent: Epoxym.
- How do I clean Flexdym?
Isopropyl alcohol, methanol, or distilled water may be used. Flexdym has to be dry (air or oven-dried) before molding to avoid bubbling or splays (cloudiness). Tape is also recommended to remove dust particles. We recommend working with Flexdym in a clean room or under a laminar hood to minimize particle contamination.
- Is the Flexdym appropriate for my fluorescence applications?
Flexdym material is transparent and has a transmittance of 50% at 295 nm and > 90% in the visible region.
- How do I mold Flexdym as transparent as possible?
We recommend molding Flexdym using a very smooth mold. Metallic molds should have a mirror finish. Glass or other transparent molds, such as epoxy or other silicones, will ensure a more transparent result.
- Why do I keep getting tiny bubbles in the plastic when I mold Flexdym?
Your setup is likely too hot, or Flexdym needs to be completely dry. Lower the temperature, decrease molding time, air/oven dry Flexdym, or perform molding in a low humidity condition to minimize bubbling. It may take some trials to optimize micro molding with Flexdym on your setup.
- What is the most effective way to sterilize Flexdym?
Ethylene oxide, gamma irradiation, or autoclave will work.
- Are Flexdym microfluidic chips used for cell culture?
While Flexdym is less permeable than PDMS, it still has sufficient air permeability to sustain cell cultures. Flexdym grades have been successfully used for neurons, hepatocytes, endothelial, dermal, stem-cells, and IPSCs cell cultures. Flexdym is UPS Class VI and ISO 10993-5 biocompatible certified material (PVC, Latex, and other phthalates free).
- How do I seal Flexdym microchannels to a substrate?
Flexdym is a self-sealing material that can bond with usual microfluidics thermoplastics materials (such as PC, POC, PS, PP), glass, and Si. The bonding process does not require any plasma-assisted or UV adhesive processes. It can be bonded at room temperature. To reduce the time of bonding and/or to improve the bonding strength, a thermal bonding process can be used (maximum 95°C). Customers have successfully sealed Flexdym by binding it to a substrate and storing the chip in an oven overnight.
- How do I control the hydrophilicity of Flexdym surfaces?
In its pristine state, Flexdym is slightly hydrophobic. Strategies used on hard plastics to achieve stable hydrophilic surfaces can also be applied to Flexdym surfaces. These strategies include plasma treatment or coatings with hydrophilic materials, such as poly (vinyl alcohol), polyurethane, polyacrylate, (hydroxypropyl) methyl cellulose, polyvinylpyrrolidone, or hyaluronic acid. Multiple vendors offer hydrophilic coatings through licensing models or outsourcing. Key points to consider are the cost structure, the type of coating, the coating application (e.g., dip, spray, spin, film coats), any curing step (e.g., UV or heat), and any post-processing steps (e.g., sterilization, cleaning, or storage conditions) that may affect your final chip.
- How do I create inlet and outlet holes for my microfluidic channels?
Traditional biopsy punches used with silicones will not work here. Using a rotary/hand punch or a laser cutter is recommended. Self-sealing connection pads have been developed to ensure easy and leak-free connections with any tubing.
- How do I prevent nonspecific binding?
Methods traditionally used to treat hard plastics generally work with Flexdym as well. For example, coating the surfaces with animal caseins or BSA (bovine serum albumin) has been successfully used.
RELATED PRODUCTS
The Flexdym pellets are ideal for experienced users who have developed a marketable product using this technology and wish to begin mass production or 3D printing. The pellets are sold at different prices based on weight ranges: 1-10 kg, 11-1,000 kg, and 1,001-10,000 kg.
General
Features & Benefits
Microfluidics needs biocompatible and scalable materials for mass production. Academics use PDMS for prototyping, but it lacks scalability, and industry experts prefer thermoplastics, but they are expensive and require harsh bonding treatments. Flexdym pellets solve all of those problems, it is a biocompatible material for microfluidic biomedical devices that is scalable and compatible with injection molding and 3D printing. Flexdym is transparent, has low molecular sorption, and is ideal for cell culture and diagnostic applications. It simplifies commercialization by enabling the use of the same material for prototyping and mass production.
Flexdym is:
- Biocompatible (ISO 10993 parts 4, 5, 6, 10, 11 and UPS Class VI)
- Self-sealing at ambient temperature
- Cost-effective
- Compatible with optical assays: low fluorescence, optically clear
- No absorption, permeable to gas and not to liquid
- Resistant to tearing: unlike PDMS, it will not tear apart when you manipulate it.
Flexdym Pellets benefits:
- Low-cost option for mass production
- Available per kilo
- Ideal for commonly used injection molding or 3D printing
- Can be molded at small scales, suing our Sublym or a hot press, and at large scales using injection molding or 3D printing
- The injection molding process allows Flexdym devices to be mass produced
General benefits of Flexdym polymer:
Flexdym:
- is an alternative to any other chip material in the classical applications of microfluidic chips
- Combines the best properties of elastomers
- Acts as a pressure sensitive adhesive
- Can be recycled and reused
- Has tunable bonding strength
This polymer is particularly interesting in life sciences: its biocompatibility makes it simple to design any experiment. The self-sealing technology is not destructive, unlike plasma, vacuum, or high temperature used to seal other chips. It ensures that biological agents remain viable and functional in your device. Flexdym enables the integration of cells, proteins, enzymes, or any bio-reagents before assembly.
Optical or fluorescence measurements in a chip require using materials that show a high level of transparency (almost 90% transmittance), primarily in the UV and visible range. Flexdym fulfills these conditions. Indeed, it reaches the limit of 50% transmittance (which we considered an acceptable transparency limit) at a wavelength of 295 nm. Flexdym features similar properties to the most transparent materials. This transparency window is sufficiently wide for many fluorophores, particularly the most popular fluorescent Cy3 and Cy5 dyes, which have excitation wavelengths at 550 and 650 nm and emission wavelengths at 570 and 670 nm, respectively.
Top Flexdym Applications
- Cell culture: Flexdym has lower sorption properties and gas permeability
- Reversible Seals: Flexdym can bond reversibly to a variety of substrates, acting as an excellent seal on devices
- Valves: Flexdym has an elongation of 700%
- Skin-interfacing: Flexdym is a pressure-sensitive adhesive that naturally sticks to the skin
Content
1x 1 kg Flexdym pellet
Specifications
Mechanical properties
| Hardness Shore A |
35 |
| Specific Gravity |
0.9 g/ cm3 |
| Tear Strength | 15 kN/m |
| Tensile Strength | 7.6 MPa |
| Elongation | 720 % |
| Molding Temperature | 115 °C - 185 °C |
| Molding Pressure | 35 Torr |
Resistance to solvants
| Chemicals | Resistance |
|
Acids |
R |
| Bases | R |
| Fluorinated Oils | R |
| Methanol/Ethanol | R |
| Carboxilic Acid | Swell |
| Hydrocarbons | NR |
| Oil | Swell |
Surface properties
| Advancing Contact Angle | 105° ± 4° |
| Receding Contact Angle |
88° ± 4° |
| Contact Angle after Plasma Treatment |
< 38° |
Room temperature bonding
| Materials | Time (hours) | Burst Pressure |
| Flexdym-Flexdym | 1h | 600 mbar |
| Flexdym-Glass | 1h | 400 mbar |
Heat-assisted bonding
| Substrate | Bonding Temperature (°C) | Time (min) | Bonding Strength (burst pressure) |
| Flexdym | 80-85 | 30 | Excellent (5.5 bar) |
| PS, COC | 95 | 60 | Excellent |
| PC, PMMA | 95 | 60 | Moderate |
| Glass | 95 | 60-120 | Moderate, non-permanent (720 mbar) |
Documentation
Application Notes Flexdym Bonding
Application Notes Flexdym Connecting
Application Notes Flexdym Molding
References
- Lachaux et al., Lab on a Chip 2016, L2017 Jul 25;17(15):2581-2594. doi: 10.1039/c7lc00488e
- Perrault et al. Insights on Polymers for Microfluidics Applied to Biomedical Applications
- Overview of Materials for Microfluidic Applications, IntechOpen 2016
- Roy et al., Lab on a Chip 2015, Lab Chip, 2015,15, 406-416, doi:10.1039/C4LC00947A
FAQ
-
Do I need a heat press for Flexdym?
Yes, most heat presses or hot embossers should work. A press that can mold at a pressure of at least 7 psi / 0.5 bar or above is ideal (a vacuum-assisted press is not required). You may have to make minor adjustments to optimize molding your chips. We offer a user-friendly compact microfabrication kit with a plug-and-play system: Sublym.
- What size range is reliably micro-molded with Flexdym?
The minimal microchannel width is 50 nm, and the depth range is 50 nm - 1 mm. However, microchannels between 1 µm and 1 mm are recommended with an aspect ratio (height to width) of 3:1 or less. Some customers have also achieved submicron structures and higher aspect ratios.
- Which mold does Flexdym work best with?
Common molds used in the field of microfluidics work well. These include fragile molds, such as photoresists (e.g., SU‒8), and etched glass and silicon molds. Temperature-resistant epoxy and traditional metallic molds (aluminum, nickel, brass) also work. Silicones such as PDMS also work; however, choose a stiff silicone grade of at least 20 Shore A durometers above Flexdym. We offer EPMO epoxy material to fabricate robust mold suited (up to 6’’ size) for Flexdym molding without the need to treat it with an anti-sticking agent: Epoxym.
- How do I clean Flexdym?
Isopropyl alcohol, methanol, or distilled water may be used. Flexdym has to be dry (air or oven-dried) before molding to avoid bubbling or splays (cloudiness). Tape is also recommended to remove dust particles. We recommend working with Flexdym in a clean room or under a laminar hood to minimize particle contamination.
- Is the Flexdym appropriate for my fluorescence applications?
Flexdym material is transparent and has a transmittance of 50% at 295 nm and > 90% in the visible region.
- How do I mold Flexdym as transparent as possible?
We recommend molding Flexdym using a very smooth mold. Metallic molds should have a mirror finish. Glass or other transparent molds, such as epoxy or other silicones, will ensure a more transparent result.
- Why do I keep getting tiny bubbles in the plastic when I mold Flexdym?
Your setup is likely too hot, or Flexdym needs to be completely dry. Lower the temperature, decrease molding time, air/oven dry Flexdym, or perform molding in a low humidity condition to minimize bubbling. It may take some trials to optimize micro molding with Flexdym on your setup.
- What is the most effective way to sterilize Flexdym?
Ethylene oxide, gamma irradiation, or autoclave will work.
- Are Flexdym microfluidic chips used for cell culture?
While Flexdym is less permeable than PDMS, it still has sufficient air permeability to sustain cell cultures. Flexdym grades have been successfully used for neurons, hepatocytes, endothelial, dermal, stem-cells, and IPSCs cell cultures. Flexdym is UPS Class VI and ISO 10993-5 biocompatible certified material (PVC, Latex, and other phthalates free).
- How do I seal Flexdym microchannels to a substrate?
Flexdym is a self-sealing material that can bond with usual microfluidics thermoplastics materials (such as PC, POC, PS, PP), glass, and Si. The bonding process does not require any plasma-assisted or UV adhesive processes. It can be bonded at room temperature. To reduce the time of bonding and/or to improve the bonding strength, a thermal bonding process can be used (maximum 95°C). Customers have successfully sealed Flexdym by binding it to a substrate and storing the chip in an oven overnight.
- How do I control the hydrophilicity of Flexdym surfaces?
In its pristine state, Flexdym is slightly hydrophobic. Strategies used on hard plastics to achieve stable hydrophilic surfaces can also be applied to Flexdym surfaces. These strategies include plasma treatment or coatings with hydrophilic materials, such as poly (vinyl alcohol), polyurethane, polyacrylate, (hydroxypropyl) methyl cellulose, polyvinylpyrrolidone, or hyaluronic acid. Multiple vendors offer hydrophilic coatings through licensing models or outsourcing. Key points to consider are the cost structure, the type of coating, the coating application (e.g., dip, spray, spin, film coats), any curing step (e.g., UV or heat), and any post-processing steps (e.g., sterilization, cleaning, or storage conditions) that may affect your final chip.
- How do I create inlet and outlet holes for my microfluidic channels?
Traditional biopsy punches used with silicones will not work here. Using a rotary/hand punch or a laser cutter is recommended. Self-sealing connection pads have been developed to ensure easy and leak-free connections with any tubing.
- How do I prevent nonspecific binding?
Methods traditionally used to treat hard plastics generally work with Flexdym as well. For example, coating the surfaces with animal caseins or BSA (bovine serum albumin) has been successfully used.