Two‐Photon Polymerized Shape Memory Microfibers: A New Mechanical Characterization Method in Liquid

Minnick, Grayson; Safa, Bahareh Tajvidi; Rosenbohm, Jordan; Lavrik, Nickolay; Brooks, Justin; Esfahani, Amir Monemian; Samaniego, Alberto; Meng, Fanben; Richter, Benjamin; Gao, Wei; Yang, Ruiguo

doi:10.1002/adfm.202206739

Cited by 7 publications

(3 citation statements)

References 49 publications

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“…Due to such capabilities, this field is often referred to as 4D printing and is rapidly emerging for the generation of microactuators, microsensors, microrobots, smart tissue engineering, and more, as recently highlighted in review articles by Mainik et al [99] and Jian at el. [100] Responses to external stimuli can be achieved through materials incorporating additives like liquid crystals, [101] shape memory fibers, [102] iron nanoparticles (Figure 3E). [81] Additionally, the use of alkoxyamine chemistry has enabled the creation of covalent adaptable microstructures with adjustable mechanical properties (Figure 3F, i).…”

Section: Advancements In Photosensitive Materialsmentioning

confidence: 99%

Frontiers of Laser‐Based 3D Printing: A Perspective on Multi‐Photon Lithography

Zyla,

Farsari

2024

Laser & Photonics Reviews

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Lasers are instrumental in enabling precise processing and fostering the development of new technologies. Particularly, ultrafast lasers, due to their unique interaction with matter, can achieve not only exceptional spatial precision but also meticulously determine the degree of modification. A prime example of this is laser‐based 3D printing through multi‐photon lithography (MPL). This approach remarkably enables the printing of true 3D structures at the micro‐ and nanoscale, without the need for masks or cumbersome tools, simply by using computer‐aided designs. Owing to these unique capabilities, MPL has emerged as a powerful manufacturing technique across various multidisciplinary fields. The ongoing growth in MPL's utilization has led to notable advancements in printing highly complex structures on different substrates, as well as improvements in resolution and throughput, and the development of novel photosensitive materials, which impressively facilitated MPL's expansion into broader fields over the last few years. In this perspective article, the aim is to highlight these advancements and recent trends in MPL. The current challenges of MPL will be explored, which need to be addressed to ensure its further integration into advanced Additive Manufacturing at the micro‐ and nanoscale. The future perspectives and opportunities of MPL as a laser‐based 3D printing approach will also be discussed.

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Section: Advancements In Photosensitive Materialsmentioning

confidence: 99%

Frontiers of Laser‐Based 3D Printing: A Perspective on Multi‐Photon Lithography

Zyla,

Farsari

2024

Laser & Photonics Reviews

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“…Based on beam deflection, the stress and strain in the cell pair can be calculated (see Methods). Importantly, the stiffness of the beams is set such that δ is much smaller than D, and therefore the deformation of the cell pair is assumed to be determined by D alone 11 . Therefore, by controlling the rate at which D is applied, we can control the rate at which the cell pair is deformed (Fig.…”

Section: Cells Increase Their Tension In Response To a High Strain Ra...mentioning

confidence: 99%

Sustained Strain Applied at High Rates Drives Dynamic Tensioning in Epithelial Cells

Yang,

Safa,

Rosenbohm

et al. 2024

Preprint

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Epithelial cells experience long lasting loads of different magnitudes and rates. How they adapt to these loads strongly impacts tissue health. Yet, much remains unknown about their stress evolution under sustained strain. Here, by subjecting cell pairs to sustained strain, we report a bimodal stress response, where in addition to the typically observed stress relaxation, a subset of cells exhibits a dynamic tensioning process with significant elevation in stress within 100s, resembling active pulling-back in muscle fibers. Strikingly, the fraction of cells exhibiting tensioning increases with increasing strain rate. The tensioning response is accompanied by actin remodeling, and perturbation to actin abrogates it, supporting cell contractility’s role in the response. Collectively, our data show that epithelial cells adjust their tensional states over short timescales in a strain-rate dependent manner to adapt to sustained strains, demonstrating that the active pulling-back behavior could be a common protective mechanism against environmental stress.

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“…[60] In very recent work, Minnick et al prepared sensor-like actuators employing the shape memory effect of integrated IP-Visio (Nanoscribe GmbH) microfibers for force measurement in a liquid medium. [61]…”

Section: D Microactuatorsmentioning

confidence: 99%

Recent Advances in Multi‐Photon 3D Laser Printing: Active Materials and Applications

Mainik,

Spiegel,

Blasco

2023

Advanced Materials

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Since the pioneering work of Kawata and colleagues in 1997, multi‐photon 3D laser printing, also known as direct laser writing, has made significant advancements in a wide range of fields. Moreover, the development and commercialization of photocurable inks for this technique have expanded rapidly. One of the current trends is the transition from static to active printable materials, often referred to as 4D microprinting, which enables a new degree of control in the printed systems. This review focuses on four primary application areas: microrobotics, optics and photonics, microfluidics, and life sciences, highlighting recent progress and the crucial role of active materials, including liquid crystalline elastomers, hydrogels, shape memory polymers, and composites, among others. It also addresses ongoing challenges and provides insights into the future prospects in the different fields.

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Two‐Photon Polymerized Shape Memory Microfibers: A New Mechanical Characterization Method in Liquid

Cited by 7 publications

References 49 publications

Frontiers of Laser‐Based 3D Printing: A Perspective on Multi‐Photon Lithography

Frontiers of Laser‐Based 3D Printing: A Perspective on Multi‐Photon Lithography

Sustained Strain Applied at High Rates Drives Dynamic Tensioning in Epithelial Cells

Recent Advances in Multi‐Photon 3D Laser Printing: Active Materials and Applications

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