Polylactic Acid
Polylactic Acid
Sample Material: Polylactic Acid
Considered to be a sustainable alternative to petrochemical products, Polylactic acid is also thermoplastic biocompatible polyester. PLA nanofibers are useful in medical applications such as drug delivery, tissue engineering and would dressings. PLA has been both solution and melt-spun with Forcespinning® technology.
Use the tabs below for more information:
Data Results
This material reported to FibeRio® by customer. Optimized data and results do not belong to FibeRio. Please review upcoming and previous literature.
Fiberlab L1000 Settings
Please contact FibeRio Customer Service for material process settings.
Forcespinning Technology utilizes centrifugal force rather than electrostatic force! Without electrostatic force, there is no need for dielectric solutions. This opens up an entire new realm of possibilities. Even metals and conductive polymers can be processed simply and safely.
Fiberlab L1000-MS
Results Achieved With Fiberlab L1000-MS
- 20,000 RPM Drive system
- Material heating system up to 450°C
- Easy material prep and cleaning
- Small benchtop footprint
- Spinneret options for low or high volume runs
Polylactic Acid
Polylactic Acid
Sample Material: Polylactic Acid
Considered to be a sustainable alternative to petrochemical products, Polylactic acid is also thermoplastic biocompatible polyester. PLA nanofibers are useful in medical applications such as drug delivery, tissue engineering and would dressings. PLA has been both solution and melt-spun with Forcespinning® technology.
Use the tabs below for more information:
Data Results
This material reported to FibeRio® by customer. Optimized data and results do not belong to FibeRio. Please review upcoming and previous literature.
Fiberlab L1000 Settings
Please contact FibeRio Customer Service for material process settings.
Forcespinning Technology utilizes centrifugal force rather than electrostatic force! Without electrostatic force, there is no need for dielectric solutions. This opens up an entire new realm of possibilities. Even metals and conductive polymers can be processed simply and safely.
Fiberlab L1000-MS
Results Achieved With Fiberlab L1000-MS
- 20,000 RPM Drive system
- Material heating system up to 450°C
- Easy material prep and cleaning
- Small benchtop footprint
- Spinneret options for low or high volume runs
Polycaprolactone
Polycaprolactone
Sample Material: Polycaprolactone
Polycaprolactone is a bioresorbable polyester that is widely being incorporated into tissue scaffolding research and other biomedical applications. PCL has been approved by the FDA for use in drug delivery devices, suture and
Polycaprolactone was spun utilizing Forcespinning® technology. The resulting sample coated a cellulosic substrate with a randomly oriented nonwoven nanofiber web consisting of a mean fiber diameter of 190. Measurements were taken from 5 randomly selected portions of the media. 266 Randomly selected fibers were measured to provide a statistically significant sample. Normal distribution was observed and is provided below.
Use the tabs below for more information:
Data Results
This material reported to FibeRio® by customer. Optimized data and results do not belong to FibeRio. Please review upcoming and previous literature.
Fiberlab L1000 Settings
Forcespinning Technology utilizes centrifugal force rather than electrostatic force! Without electrostatic force, there is no need for dielectric solutions. This opens up an entire new realm of possibilities. Even metals and conductive polymers can be processed simply and safely.
Fiberlab L1000-MS
Results Achieved With Fiberlab L1000-MS
- 20,000 RPM Drive system
- Material heating system up to 450°C
- Easy material prep and cleaning
- Small benchtop footprint
- Spinneret options for low or high volume runs
Polycaprolactone
Polycaprolactone
Sample Material: Polycaprolactone
Polycaprolactone is a bioresorbable polyester that is widely being incorporated into tissue scaffolding research and other biomedical applications. PCL has been approved by the FDA for use in drug delivery devices, suture and more. Randomly oriented nanofiber mats tend to mimic the Extra-cellular matrix and can be seeded with tissue.
Polycaprolactone was spun utilizing Forcespinning® technology. The resulting sample coated a cellulosic substrate with a randomly oriented nonwoven nanofiber web consisting of a mean fiber diameter of 190. Measurements were taken from 5 randomly selected portions of the media. 266 Randomly selected fibers were measured to provide a statistically significant sample. Normal distribution was observed and is provided below.
Use the tabs below for more information:
Data Results
This material reported to FibeRio® by customer. Optimized data and results do not belong to FibeRio. Please review upcoming and previous literature.
Fiberlab L1000 Settings
Forcespinning Technology utilizes centrifugal force rather than electrostatic force! Without electrostatic force, there is no need for dielectric solutions. This opens up an entire new realm of possibilities. Even metals and conductive polymers can be processed simply and safely.
Fiberlab L1000-MS
Results Achieved With Fiberlab L1000-MS
- 20,000 RPM Drive system
- Material heating system up to 450°C
- Easy material prep and cleaning
- Small benchtop footprint
- Spinneret options for low or high volume runs
Polylactic Acid
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Sample Material: Polylactic Acid
Considered to be a sustainable alternative to petrochemical products, Polylactic acid is also thermoplastic biocompatible polyester. PLA nanofibers are useful in medical applications such as drug delivery, tissue engineering and would dressings. PLA has been both solution and melt-spun with Forcespinning® technology.
Use the tabs below for more information:
Data Results
This material reported to FibeRio® by customer. Optimized data and results do not belong to FibeRio. Please review upcoming and previous literature.
Fiberlab L1000 Settings
Forcespinning Technology utilizes centrifugal force rather than electrostatic force! Without electrostatic force, there is no need for dielectric solutions. This opens up an entire new realm of possibilities. Even metals and conductive polymers can be processed simply and safely.
Fiberlab L1000-MS
Results Achieved With Fiberlab L1000-MS
- 20,000 RPM Drive system
- Material heating system up to 450°C
- Easy material prep and cleaning
- Small benchtop footprint
- Spinneret options for low or high volume runs
Polybutylene Terepthalate
Polybutylene Terepthalate
Sample Material: Polybutylene Terepthalate
Polybutylene Terephthalate is a thermoplastic polyester that is resistant to chemical degradation, mechanically strong and heat resistant. These characteristics make it highly useful in industrial applications such as fuel and liquid filtration as well as being used in the electronics industry as an insulator. PBT’s resistance to solvents makes it difficult to process into nanofiber with other processes. Forcespinning® technology has been used to melt-spin this material.
Use the tabs below for more information:
Data Results
This material reported to FibeRio® by customer. Optimized data and results do not belong to FibeRio. Please review upcoming and previous literature.
Fiberlab L1000 Settings
Please contact FibeRio Customer Service for material process settings
Forcespinning Technology utilizes centrifugal force rather than electrostatic force! Without electrostatic force, there is no need for dielectric solutions. This opens up an entire new realm of possibilities. Even metals and conductive polymers can be processed simply and safely.
Fiberlab L1000-MS
Results Achieved With Fiberlab L1000-MS
- 20,000 RPM Drive system
- Material heating system up to 450°C
- Easy material prep and cleaning
- Small benchtop footprint
- Spinneret options for low or high volume runs
