Nanoscribe
@nanoscribe.com
The world technology and market leader in 3D printing on the nano-, micro-, and mesoscale.
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🌐 https://www.nanoscribe.com/en/
https://www.nanoscribe.com/en/legal-notice/
https://www.nanoscribe.com/en/privacy-policy/
🎆 Hello, 2026.
Here’s to clear priorities, good collaboration, and time for the work that matters in 3D nano- and microfabrication.
All the best for the new year from all of us at Nanoscribe 👋
Here’s to clear priorities, good collaboration, and time for the work that matters in 3D nano- and microfabrication.
All the best for the new year from all of us at Nanoscribe 👋
January 1, 2026 at 12:01 PM
🎆 Hello, 2026.
Here’s to clear priorities, good collaboration, and time for the work that matters in 3D nano- and microfabrication.
All the best for the new year from all of us at Nanoscribe 👋
Here’s to clear priorities, good collaboration, and time for the work that matters in 3D nano- and microfabrication.
All the best for the new year from all of us at Nanoscribe 👋
Unimolecular stimuli-responsive nanomaterials
Stable, biocompatible, & optically self-reporting nanomaterials printed in microstructures using a Nanoscribe two-photon system.
Kudos to the @sydney.edu.au & @uniheidelberg.bsky.social teams!
More: pubs.rsc.org/en/content/a...
Stable, biocompatible, & optically self-reporting nanomaterials printed in microstructures using a Nanoscribe two-photon system.
Kudos to the @sydney.edu.au & @uniheidelberg.bsky.social teams!
More: pubs.rsc.org/en/content/a...
A printable, unimolecular, core–shell polymer bottlebrush-based signal transducer using solvatochromatic reporting - Chemical Science (RSC Publishing) DOI:10.1039/D5SC07029E
Chenyou Zhang a, Samantha O. Catt b, Tom Hawtrey cde, Ping Zeng a, Haoxiang Zeng a, Simran D. Kerai a, Yen Theng Cheng a, Moritz P. Hopp b, Qinqin Yang a, Elizabeth J. New cde, Eva Blasco *b and…
pubs.rsc.org
December 29, 2025 at 12:01 PM
Unimolecular stimuli-responsive nanomaterials
Stable, biocompatible, & optically self-reporting nanomaterials printed in microstructures using a Nanoscribe two-photon system.
Kudos to the @sydney.edu.au & @uniheidelberg.bsky.social teams!
More: pubs.rsc.org/en/content/a...
Stable, biocompatible, & optically self-reporting nanomaterials printed in microstructures using a Nanoscribe two-photon system.
Kudos to the @sydney.edu.au & @uniheidelberg.bsky.social teams!
More: pubs.rsc.org/en/content/a...
🤝 Wishing you a warm and restful season.
Thank you for trusting us, sharing ideas and driving new projects in 3D nano- and microfabrication.
Enjoy spending time with your loved ones and start the new year off right 😊
Thank you for trusting us, sharing ideas and driving new projects in 3D nano- and microfabrication.
Enjoy spending time with your loved ones and start the new year off right 😊
December 25, 2025 at 12:02 PM
🤝 Wishing you a warm and restful season.
Thank you for trusting us, sharing ideas and driving new projects in 3D nano- and microfabrication.
Enjoy spending time with your loved ones and start the new year off right 😊
Thank you for trusting us, sharing ideas and driving new projects in 3D nano- and microfabrication.
Enjoy spending time with your loved ones and start the new year off right 😊
14 days of high-quality wearable ECG – using microneedle electrodes.
Inha University researchers validated ECG monitoring with a wireless system, using Nanoscribe’s 2PP for printing the microneedle master.
Congrats to the team!
More: advanced.onlinelibrary.wiley.com/doi/10.1002/...
Inha University researchers validated ECG monitoring with a wireless system, using Nanoscribe’s 2PP for printing the microneedle master.
Congrats to the team!
More: advanced.onlinelibrary.wiley.com/doi/10.1002/...
Antifouling All-Polymeric Microneedle Array for Long-Term Wearable ECG Monitoring
advanced.onlinelibrary.wiley.com
December 23, 2025 at 12:01 PM
14 days of high-quality wearable ECG – using microneedle electrodes.
Inha University researchers validated ECG monitoring with a wireless system, using Nanoscribe’s 2PP for printing the microneedle master.
Congrats to the team!
More: advanced.onlinelibrary.wiley.com/doi/10.1002/...
Inha University researchers validated ECG monitoring with a wireless system, using Nanoscribe’s 2PP for printing the microneedle master.
Congrats to the team!
More: advanced.onlinelibrary.wiley.com/doi/10.1002/...
⏳ Year-end highlights in 3D nano- and microfabrication
Company milestones, customer results, and a tiny advent arrangement aligned onto an optical fiber, with nanoscale precision🔬
Discover what shaped our 2025 and how we made it
tinyurl.com/2mefv2ym
Company milestones, customer results, and a tiny advent arrangement aligned onto an optical fiber, with nanoscale precision🔬
Discover what shaped our 2025 and how we made it
tinyurl.com/2mefv2ym
December 19, 2025 at 10:00 AM
⏳ Year-end highlights in 3D nano- and microfabrication
Company milestones, customer results, and a tiny advent arrangement aligned onto an optical fiber, with nanoscale precision🔬
Discover what shaped our 2025 and how we made it
tinyurl.com/2mefv2ym
Company milestones, customer results, and a tiny advent arrangement aligned onto an optical fiber, with nanoscale precision🔬
Discover what shaped our 2025 and how we made it
tinyurl.com/2mefv2ym
How do you speed up laser fusion target development?
With Nanoscribe’s 3D printing by 2GL®: single-step fabrication of ultrasmooth shells (Ra < 10 nm) and nanoporous foam lattices with repeatable and precise results for rapid iteration.
Discover more:
👉 tinyurl.com/49kcdwbm
With Nanoscribe’s 3D printing by 2GL®: single-step fabrication of ultrasmooth shells (Ra < 10 nm) and nanoporous foam lattices with repeatable and precise results for rapid iteration.
Discover more:
👉 tinyurl.com/49kcdwbm
December 16, 2025 at 12:00 PM
How do you speed up laser fusion target development?
With Nanoscribe’s 3D printing by 2GL®: single-step fabrication of ultrasmooth shells (Ra < 10 nm) and nanoporous foam lattices with repeatable and precise results for rapid iteration.
Discover more:
👉 tinyurl.com/49kcdwbm
With Nanoscribe’s 3D printing by 2GL®: single-step fabrication of ultrasmooth shells (Ra < 10 nm) and nanoporous foam lattices with repeatable and precise results for rapid iteration.
Discover more:
👉 tinyurl.com/49kcdwbm
🎄 A touch of Christmas spirit and year-end spirit at Nanoscribe.
A team get-together with gifts, hot drinks, pastries and good conversations brought a warm pause to a busy year.
And Nanoscribe turned 18 this week, so there was anniversary cake too 🎂
A team get-together with gifts, hot drinks, pastries and good conversations brought a warm pause to a busy year.
And Nanoscribe turned 18 this week, so there was anniversary cake too 🎂
December 12, 2025 at 12:02 PM
🎄 A touch of Christmas spirit and year-end spirit at Nanoscribe.
A team get-together with gifts, hot drinks, pastries and good conversations brought a warm pause to a busy year.
And Nanoscribe turned 18 this week, so there was anniversary cake too 🎂
A team get-together with gifts, hot drinks, pastries and good conversations brought a warm pause to a busy year.
And Nanoscribe turned 18 this week, so there was anniversary cake too 🎂
🎥 200+ double-sided aspherical lenses, 3D printed (not molded) with highest shape accuracy.
That’s 3D printing by 2GL® on Quantum X: throughput + top-tier print quality, no trade-off.
👉 Explore the most versatile Quantum X shape 3D printer: tinyurl.com/yrvhxytb
That’s 3D printing by 2GL® on Quantum X: throughput + top-tier print quality, no trade-off.
👉 Explore the most versatile Quantum X shape 3D printer: tinyurl.com/yrvhxytb
December 10, 2025 at 12:00 PM
🎥 200+ double-sided aspherical lenses, 3D printed (not molded) with highest shape accuracy.
That’s 3D printing by 2GL® on Quantum X: throughput + top-tier print quality, no trade-off.
👉 Explore the most versatile Quantum X shape 3D printer: tinyurl.com/yrvhxytb
That’s 3D printing by 2GL® on Quantum X: throughput + top-tier print quality, no trade-off.
👉 Explore the most versatile Quantum X shape 3D printer: tinyurl.com/yrvhxytb
Micro-optics manufacturing – now as a service with Printoptix
Together with Printoptix, we support you from optical design to integration-ready micro-optical systems – powered by Nanoscribe tech and Quantum X align.
Explore more: tinyurl.com/5n6hzw3k
Together with Printoptix, we support you from optical design to integration-ready micro-optical systems – powered by Nanoscribe tech and Quantum X align.
Explore more: tinyurl.com/5n6hzw3k
December 9, 2025 at 12:00 PM
Micro-optics manufacturing – now as a service with Printoptix
Together with Printoptix, we support you from optical design to integration-ready micro-optical systems – powered by Nanoscribe tech and Quantum X align.
Explore more: tinyurl.com/5n6hzw3k
Together with Printoptix, we support you from optical design to integration-ready micro-optical systems – powered by Nanoscribe tech and Quantum X align.
Explore more: tinyurl.com/5n6hzw3k
Fluorescence monitoring in 3D microtissues – on just 1 mm²
Nanoscribe’s high-resolution 3D printer is used to fabricate a low-autofluorescence light guide. Kudos to KTH & partners. 👏
📖 Read the paper here: doi.org/10.1038/s413...
Nanoscribe’s high-resolution 3D printer is used to fabricate a low-autofluorescence light guide. Kudos to KTH & partners. 👏
📖 Read the paper here: doi.org/10.1038/s413...
Integrated microoptical system for continuous fluorescence monitoring of microtissues - Microsystems & Nanoengineering
Microsystems & Nanoengineering - Integrated microoptical system for continuous fluorescence monitoring of microtissues
doi.org
December 8, 2025 at 12:00 PM
Fluorescence monitoring in 3D microtissues – on just 1 mm²
Nanoscribe’s high-resolution 3D printer is used to fabricate a low-autofluorescence light guide. Kudos to KTH & partners. 👏
📖 Read the paper here: doi.org/10.1038/s413...
Nanoscribe’s high-resolution 3D printer is used to fabricate a low-autofluorescence light guide. Kudos to KTH & partners. 👏
📖 Read the paper here: doi.org/10.1038/s413...
Finding the right resin for your project got easier!
Explore our resins grouped by application areas:
➡️ High-resolution 3D printing
➡️ High-resolution 3D biofabrication
➡️ Optics manufacturing
➡️ Maskless lithography
👉 Explore the new resin overview: tinyurl.com/4f3ut6a2
Explore our resins grouped by application areas:
➡️ High-resolution 3D printing
➡️ High-resolution 3D biofabrication
➡️ Optics manufacturing
➡️ Maskless lithography
👉 Explore the new resin overview: tinyurl.com/4f3ut6a2
December 4, 2025 at 12:35 PM
Finding the right resin for your project got easier!
Explore our resins grouped by application areas:
➡️ High-resolution 3D printing
➡️ High-resolution 3D biofabrication
➡️ Optics manufacturing
➡️ Maskless lithography
👉 Explore the new resin overview: tinyurl.com/4f3ut6a2
Explore our resins grouped by application areas:
➡️ High-resolution 3D printing
➡️ High-resolution 3D biofabrication
➡️ Optics manufacturing
➡️ Maskless lithography
👉 Explore the new resin overview: tinyurl.com/4f3ut6a2
🔬 Meet us at #MRSFall 2025 in Boston!
Visit our colleagues at Booth 818 until Dec 4 and explore high-precision 3D microfabrication with the Quantum X printer line and 2GL®.
If you're at MRS Fall, stop by 🗣️
More upcoming events: tinyurl.com/3jrpzvbc
Visit our colleagues at Booth 818 until Dec 4 and explore high-precision 3D microfabrication with the Quantum X printer line and 2GL®.
If you're at MRS Fall, stop by 🗣️
More upcoming events: tinyurl.com/3jrpzvbc
December 3, 2025 at 12:00 PM
🔬 Meet us at #MRSFall 2025 in Boston!
Visit our colleagues at Booth 818 until Dec 4 and explore high-precision 3D microfabrication with the Quantum X printer line and 2GL®.
If you're at MRS Fall, stop by 🗣️
More upcoming events: tinyurl.com/3jrpzvbc
Visit our colleagues at Booth 818 until Dec 4 and explore high-precision 3D microfabrication with the Quantum X printer line and 2GL®.
If you're at MRS Fall, stop by 🗣️
More upcoming events: tinyurl.com/3jrpzvbc
3D-printed microfluidic designs enable in vitro engineering of human neuronal networks
Using Nanoscribe’s 3D printing, researchers fabricated a mold of the microfluidic design for the final PDMS-based microfluidic chip.
Read the open access publication:
doi.org/10.1021/acsn...
Using Nanoscribe’s 3D printing, researchers fabricated a mold of the microfluidic design for the final PDMS-based microfluidic chip.
Read the open access publication:
doi.org/10.1021/acsn...
Reproducible Human Neural Circuits Printed with Single-Cell Precision Reveal the Functional Roles of Ephaptic Coupling
Although in vitro neuronal models are accessible and versatile systems for functional electrophysiological studies, the spontaneous and random formation of neural circuits often compromises the…
doi.org
December 2, 2025 at 12:04 PM
3D-printed microfluidic designs enable in vitro engineering of human neuronal networks
Using Nanoscribe’s 3D printing, researchers fabricated a mold of the microfluidic design for the final PDMS-based microfluidic chip.
Read the open access publication:
doi.org/10.1021/acsn...
Using Nanoscribe’s 3D printing, researchers fabricated a mold of the microfluidic design for the final PDMS-based microfluidic chip.
Read the open access publication:
doi.org/10.1021/acsn...
How to create functional materials for next generation microdevices?
With #2PP and the Quantum X platform, you can explore new custom resin formulations faster and more systematically.
Discover how researchers accelerate functional resin innovation:
tinyurl.com/36f5enfy
With #2PP and the Quantum X platform, you can explore new custom resin formulations faster and more systematically.
Discover how researchers accelerate functional resin innovation:
tinyurl.com/36f5enfy
November 27, 2025 at 12:00 PM
How to create functional materials for next generation microdevices?
With #2PP and the Quantum X platform, you can explore new custom resin formulations faster and more systematically.
Discover how researchers accelerate functional resin innovation:
tinyurl.com/36f5enfy
With #2PP and the Quantum X platform, you can explore new custom resin formulations faster and more systematically.
Discover how researchers accelerate functional resin innovation:
tinyurl.com/36f5enfy
Exciting insights into microneedle design optimization!
Recent study on microneedle arrays presents a systematic comparison of more than 75 distinct microneedle designs fabricated using Nanoscribe’s high-resolution 3D printing.
➡️ Read the publication:
doi.org/10.1007/s110...
Recent study on microneedle arrays presents a systematic comparison of more than 75 distinct microneedle designs fabricated using Nanoscribe’s high-resolution 3D printing.
➡️ Read the publication:
doi.org/10.1007/s110...
A Comprehensive Design-to-skin Pipeline to Fabricate Polymeric Microneedles Using Ultrahigh-resolution 3D Printing - Pharmaceutical Research
Objective Microneedle technologies have emerged as a promising approach to improve intradermal drug delivery. This study presents a comprehensive workflow for fabricating polymeric microneedle arrays…
doi.org
November 26, 2025 at 12:02 PM
Exciting insights into microneedle design optimization!
Recent study on microneedle arrays presents a systematic comparison of more than 75 distinct microneedle designs fabricated using Nanoscribe’s high-resolution 3D printing.
➡️ Read the publication:
doi.org/10.1007/s110...
Recent study on microneedle arrays presents a systematic comparison of more than 75 distinct microneedle designs fabricated using Nanoscribe’s high-resolution 3D printing.
➡️ Read the publication:
doi.org/10.1007/s110...
Plug-and-play meets photonics:
Researchers at Heidelberg University demonstrate a fiber-to-chip connector with sub-dB losses and < 3 min packaging time per port – powered by Quantum X align’s precision 3D nanoprinting.
👉 More info: 🔗 tinyurl.com/yr7p9ftd
Researchers at Heidelberg University demonstrate a fiber-to-chip connector with sub-dB losses and < 3 min packaging time per port – powered by Quantum X align’s precision 3D nanoprinting.
👉 More info: 🔗 tinyurl.com/yr7p9ftd
November 25, 2025 at 12:00 PM
Plug-and-play meets photonics:
Researchers at Heidelberg University demonstrate a fiber-to-chip connector with sub-dB losses and < 3 min packaging time per port – powered by Quantum X align’s precision 3D nanoprinting.
👉 More info: 🔗 tinyurl.com/yr7p9ftd
Researchers at Heidelberg University demonstrate a fiber-to-chip connector with sub-dB losses and < 3 min packaging time per port – powered by Quantum X align’s precision 3D nanoprinting.
👉 More info: 🔗 tinyurl.com/yr7p9ftd
Ultrasonic sensing redefined.
Researchers created a fiber-tip sensor with an integrated optical resonator and photonic wire bonding, 3D-printed via Two-Photon Polymerization.
Compact, highly sensitive, for imaging and nondestructive testing.
Read more:
doi.org/10.1021/acsp...
Researchers created a fiber-tip sensor with an integrated optical resonator and photonic wire bonding, 3D-printed via Two-Photon Polymerization.
Compact, highly sensitive, for imaging and nondestructive testing.
Read more:
doi.org/10.1021/acsp...
November 17, 2025 at 3:04 PM
Ultrasonic sensing redefined.
Researchers created a fiber-tip sensor with an integrated optical resonator and photonic wire bonding, 3D-printed via Two-Photon Polymerization.
Compact, highly sensitive, for imaging and nondestructive testing.
Read more:
doi.org/10.1021/acsp...
Researchers created a fiber-tip sensor with an integrated optical resonator and photonic wire bonding, 3D-printed via Two-Photon Polymerization.
Compact, highly sensitive, for imaging and nondestructive testing.
Read more:
doi.org/10.1021/acsp...
Origami-inspired micromachines – 3D-printed with Nanoscribe’s Two-Photon Polymerization.
Combining rigid and soft materials at the microscale enables microbuilding blocks with torsional properties for smart microrobots in medicine and diagnostics.
Read more
➡️ doi.org/10.1002/adfm...
Combining rigid and soft materials at the microscale enables microbuilding blocks with torsional properties for smart microrobots in medicine and diagnostics.
Read more
➡️ doi.org/10.1002/adfm...
Origami Twist‐Inspired Microbuilding Blocks for Multifunctional Shape‐Morphing Micromachines
The development of intelligent micromachines, which require advanced capabilities, is hindered by material and fabrication limits. This work presents origami-inspired rigid–soft microbuilding blocks ...
doi.org
November 14, 2025 at 12:01 PM
Origami-inspired micromachines – 3D-printed with Nanoscribe’s Two-Photon Polymerization.
Combining rigid and soft materials at the microscale enables microbuilding blocks with torsional properties for smart microrobots in medicine and diagnostics.
Read more
➡️ doi.org/10.1002/adfm...
Combining rigid and soft materials at the microscale enables microbuilding blocks with torsional properties for smart microrobots in medicine and diagnostics.
Read more
➡️ doi.org/10.1002/adfm...
Meet Frank, Customer Success Expert at Nanoscribe👋
Frank supports customers with demos, training and feasibility studies.
Beyond work, he enjoys music, sports and family time.
Discover how our experts support your success
➡️ tinyurl.com/6v9k77dr
Frank supports customers with demos, training and feasibility studies.
Beyond work, he enjoys music, sports and family time.
Discover how our experts support your success
➡️ tinyurl.com/6v9k77dr
November 13, 2025 at 12:00 PM
Meet Frank, Customer Success Expert at Nanoscribe👋
Frank supports customers with demos, training and feasibility studies.
Beyond work, he enjoys music, sports and family time.
Discover how our experts support your success
➡️ tinyurl.com/6v9k77dr
Frank supports customers with demos, training and feasibility studies.
Beyond work, he enjoys music, sports and family time.
Discover how our experts support your success
➡️ tinyurl.com/6v9k77dr
New fiber laser design for telecom & imaging:
A monolithic, wavelength-tunable pulsed laser with a 2D metafiber & a 3D-printed Fabry–Perot cavity on a fiber tip, enabled by Nanoscribe’s 3D printing.
Open-access publication:
tinyurl.com/ykk5ks3z
A monolithic, wavelength-tunable pulsed laser with a 2D metafiber & a 3D-printed Fabry–Perot cavity on a fiber tip, enabled by Nanoscribe’s 3D printing.
Open-access publication:
tinyurl.com/ykk5ks3z
November 12, 2025 at 12:01 PM
New fiber laser design for telecom & imaging:
A monolithic, wavelength-tunable pulsed laser with a 2D metafiber & a 3D-printed Fabry–Perot cavity on a fiber tip, enabled by Nanoscribe’s 3D printing.
Open-access publication:
tinyurl.com/ykk5ks3z
A monolithic, wavelength-tunable pulsed laser with a 2D metafiber & a 3D-printed Fabry–Perot cavity on a fiber tip, enabled by Nanoscribe’s 3D printing.
Open-access publication:
tinyurl.com/ykk5ks3z
🔬 Yesterday at #SmartMaterialsSummit 2025, we hosted a live lab demo at the ZEISS Innovation Hub @ KIT in Karlsruhe.
Visitors explored how mechanical metamaterials can be 3D printed with our Quantum X systems for tailored mechanical properties. 👏
👉 tinyurl.com/2pxa998y
Visitors explored how mechanical metamaterials can be 3D printed with our Quantum X systems for tailored mechanical properties. 👏
👉 tinyurl.com/2pxa998y
November 7, 2025 at 12:00 PM
🔬 Yesterday at #SmartMaterialsSummit 2025, we hosted a live lab demo at the ZEISS Innovation Hub @ KIT in Karlsruhe.
Visitors explored how mechanical metamaterials can be 3D printed with our Quantum X systems for tailored mechanical properties. 👏
👉 tinyurl.com/2pxa998y
Visitors explored how mechanical metamaterials can be 3D printed with our Quantum X systems for tailored mechanical properties. 👏
👉 tinyurl.com/2pxa998y
Exciting new publication: 3D-printed microneedles for real-time health monitoring.
Powered by Nanoscribe’s Two-Photon Polymerization, this biosensing platform is designed for detecting biomarkers right from the skin. Kudos to the research team!
Powered by Nanoscribe’s Two-Photon Polymerization, this biosensing platform is designed for detecting biomarkers right from the skin. Kudos to the research team!
Microneedles + conductive ink = sturdier on-skin sensing
INM co-authors show a fenestrated shell that protects the sensing layer for transdermal pH readout.
Out now in Advanced Functional Materials - doi.org/10.1002/adfm...
@nicovoelcker.bsky.social
@wiley.com
#academicsky
INM co-authors show a fenestrated shell that protects the sensing layer for transdermal pH readout.
Out now in Advanced Functional Materials - doi.org/10.1002/adfm...
@nicovoelcker.bsky.social
@wiley.com
#academicsky
November 6, 2025 at 12:18 PM
Exciting new publication: 3D-printed microneedles for real-time health monitoring.
Powered by Nanoscribe’s Two-Photon Polymerization, this biosensing platform is designed for detecting biomarkers right from the skin. Kudos to the research team!
Powered by Nanoscribe’s Two-Photon Polymerization, this biosensing platform is designed for detecting biomarkers right from the skin. Kudos to the research team!
🔬 Nanoscribe, LAB14, and Nanosurf now share one office at 400 TradeCenter Dr, Woburn, MA 01801, USA.
Together as part of the LAB14 Group, we’re building a strong hub for nanoscale precision technologies in North America.
Talk to our US sales experts: tinyurl.com/5t4ktwdz
Together as part of the LAB14 Group, we’re building a strong hub for nanoscale precision technologies in North America.
Talk to our US sales experts: tinyurl.com/5t4ktwdz
November 5, 2025 at 12:01 PM
🔬 Nanoscribe, LAB14, and Nanosurf now share one office at 400 TradeCenter Dr, Woburn, MA 01801, USA.
Together as part of the LAB14 Group, we’re building a strong hub for nanoscale precision technologies in North America.
Talk to our US sales experts: tinyurl.com/5t4ktwdz
Together as part of the LAB14 Group, we’re building a strong hub for nanoscale precision technologies in North America.
Talk to our US sales experts: tinyurl.com/5t4ktwdz
What looks organic is actually 3D-printed with Two-Photon Grayscale Lithography (2GL®) – a biomimetic mesh with capillary-like channels for tissue vascularization.
Discover the Quantum X bio, the highest resolution 3D bioprinter:
tinyurl.com/3w74yuat
Discover the Quantum X bio, the highest resolution 3D bioprinter:
tinyurl.com/3w74yuat
November 4, 2025 at 12:00 PM
What looks organic is actually 3D-printed with Two-Photon Grayscale Lithography (2GL®) – a biomimetic mesh with capillary-like channels for tissue vascularization.
Discover the Quantum X bio, the highest resolution 3D bioprinter:
tinyurl.com/3w74yuat
Discover the Quantum X bio, the highest resolution 3D bioprinter:
tinyurl.com/3w74yuat
Toward 3D, adaptive, and reconfigurable optics
A new study bridges 3D nanofabrication and liquid crystal (LC) photonics, moving from flat LC devices toward truly 3D integrated photonic structures. Kudos to the scientists at Jožef Stefan Institute.
Read the paper here:
pubs.acs.org/doi/10.1021/...
A new study bridges 3D nanofabrication and liquid crystal (LC) photonics, moving from flat LC devices toward truly 3D integrated photonic structures. Kudos to the scientists at Jožef Stefan Institute.
Read the paper here:
pubs.acs.org/doi/10.1021/...
Three-Dimensional Planar Alignment of Nematic Liquid Crystal by Direct Laser Writing of Nanogratings
We demonstrate a new method of aligning liquid crystals along polymer surfaces that are printed vertical to the focal plane using direct laser writing. The method is based on nanogrooves that are…
pubs.acs.org
November 3, 2025 at 12:01 PM
Toward 3D, adaptive, and reconfigurable optics
A new study bridges 3D nanofabrication and liquid crystal (LC) photonics, moving from flat LC devices toward truly 3D integrated photonic structures. Kudos to the scientists at Jožef Stefan Institute.
Read the paper here:
pubs.acs.org/doi/10.1021/...
A new study bridges 3D nanofabrication and liquid crystal (LC) photonics, moving from flat LC devices toward truly 3D integrated photonic structures. Kudos to the scientists at Jožef Stefan Institute.
Read the paper here:
pubs.acs.org/doi/10.1021/...