Microfluidic Controlled Mass-Transfer and Buckling for Easy Fabrication of Polymeric Helical Fibers

Zhu, Aidi; Guo, Mingyu

doi:10.1002/marc.201500632

Cited by 25 publications

(20 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For simplicity, here, the inner phase was either 4.0 wt% CCS or 8.0 wt% PVA in water, or 8.0 wt% PUU3‐12 in N , N ‐dimethylformamide (DMF) or 8.0 wt% EVOH in dimethyl sulfoxide (DMSO). Similar to our previous report, other concentrations of these polymer solutions can also be used to get helical fibers . Liquid poly(ethylene glycol) 400 (PEG400) or 80 wt% PEG800 or 70 wt% PEG1000 (the number denotes the molecular weight of PEG) in H 2 O with similar viscosities (Figure S1, Supporting Information) was used as the outer phase, to exclude the viscosity influence on the morphology of the fibers (Figure g–i).…”

mentioning

confidence: 94%

“…When it entered into a wider collection tube II (d 2 > d 1 , Figure a), solid polymeric helical fibers automatically formed (Figure a,c). We attributed this to the synergy effect of the mass‐transfer between the dispersed inner and the continuous outer phase and the widening of collection tube II . First, once the inner polymeric solution met with the continuous outer phase in tube I, the solvent in the jet (water or DMF or DMSO) began to diffuse into the outer phase because of osmotic pressure, while the polymer still remained in the jet, due to its immiscibility with the outer phase.…”

mentioning

confidence: 99%

“…First, once the inner polymeric solution met with the continuous outer phase in tube I, the solvent in the jet (water or DMF or DMSO) began to diffuse into the outer phase because of osmotic pressure, while the polymer still remained in the jet, due to its immiscibility with the outer phase. Thus shrinkage of the jet occurred, leading to the accumulation of elastic energy and the buildup of stress, which could be released via folding of the straight jet . Second, the suddenly widening of tube II created a velocity difference between the straight inner jet and the outer continuous phase, imposing viscous drag on and folding of the jet .…”

mentioning

confidence: 99%

“…Similar to our previous report, other concentrations of these polymer solutions can also be used to get helical fibers. [34] Liquid poly(ethylene glycol) 400 (PEG400) or 80 wt% PEG800 or 70 wt% PEG1000 (the number denotes the molecular weight of PEG) in H 2 O with similar viscosities (Figure S1, Supporting Information) was used as the outer phase, to exclude the viscosity influence on the morphology of the fibers (Figure 3g-i). These two liquids were pumped separately into the inner and outer channels, a straight jet of the inner polymeric solution formed in tube I.…”

mentioning

confidence: 99%

See 3 more Smart Citations

Bioinspired Polymeric Helical and Superhelical Microfibers via Microfluidic Spinning

Yang

Guo

2019

Macromol. Rapid Commun.

Self Cite

View full text Add to dashboard Cite

The helix and superhelix play critical roles in the achievement of tissue functions. These fascinating structures have attracted increasing interest due to their potential biomimicking applications. However, continuous and controlled fabrication of these structures, especially the superhelical structures, from various polymers for different practical applications still remains a big challenge. Here, a novel and versatile microfluidic spinning strategy is presented for generation of both helical and superhelical microfibers from either hydrophilic, hydrophobic, or amphiphilic polymers. The diameter (d ), wavelength (λ), and amplitude (A) of these microfibers could be highly controlled. The helical microfibers show outstanding elongations and potential applications in magnetic responsive elastic microactuators. It is envisioned that these results will greatly enrich the possibility of generating new multiple‐ordered structures from various polymers for applications in different areas.

show abstract

mentioning

confidence: 94%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Bioinspired Polymeric Helical and Superhelical Microfibers via Microfluidic Spinning

Yang

Guo

2019

Macromol. Rapid Commun.

Self Cite

View full text Add to dashboard Cite

show abstract

“…[6,7] Compared with spherical microparticles, microstructured materials with other different shapes can show unique properties in various fields for advanced applications such as targeting www.advancedsciencenews.com www.mrc-journal.de 3D helical shapes. Although microfluidic technique can produce helical microfibers from coiled jet templates, [37,38] fabrication of particulated microstructured materials with helical shapes still remains difficult. Such helical microstructured materials can be typically produced by 3D direct laser writing, [14] bending of multilayer metals that deposited or grown on a sacrificed substrate, [39] and depositing metal coatings on diced xylem vessels of plants; [40] however, these techniques usually suffer from troublesome fabrication process and limited materials choice.…”

Section: Introductionmentioning

confidence: 99%

Controllable Microfluidic Fabrication of Microstructured Materials from Nonspherical Particles to Helices

Wang

Zhang

et al. 2017

Macromol. Rapid Commun.

View full text Add to dashboard Cite

delivery, [1] drug release, [8] assembling, [9,10] packing, [11,12] and magnetic-driven motion. [13,14] For example, cylindrical microstructured materials self-assembled from copolymers can persist in the blood circulation of rodents ten times longer than their spherical counterparts. [2] Helical microstructured materials can convert rotational motion into translational motion in liquid media, such as water and blood, under remote control of a rotated magnetic field, showing great potential for many applications. [13,15] With such unique motion behaviors, helical microstructured materials can be utilized for uses such as picking and placing of microcargo, [14] mixing and pumping of fluid, [16] remote sensing of pH, [17] drilling of bovine tissues, [18] and cancer hyperthermia. [19] Thus, creation of uniform microstructured materials with versatile nonspherical and helical shapes is crucial for achieving advanced functions.Generally, microstructured materials with nonspherical and helical shapes can be produced by methods such as film-based extension of spherical microparticles, [20][21][22] mold-based template synthesis, [23,24] microfluidic-based template synthesis, [8,[25][26][27] and polymerization induced by 3D direct laser writing. [14] For example, incorporation of polystyrene-based microparticles in polymeric film, followed with 1D or 2D film extension, can produce various nonspherical microparticles. [20][21][22] By confining precursor solutions in differently shaped microwells of molds, nonspherical microparticles with flexible shapes can also be produced. [23,24] With excellent manipulation of microflows, [28][29][30] microfluidic technique provides a powerful platform for fabricating nonspherical microparticles with versatile structures and compositions. [26,31,32] Mask-assisted selective polymerization of photo-curable solution in microchannel can fabricate nonspherical microparticles with flexible shapes depending on their mask, [25,33] and the flow configuration. [34,35] Alternatively, monodisperse emulsion droplets from microfluidics, with versatile shapes, provide excellent templates for engineering uniform nonspherical microparticles. Deformed droplets confined by microchannel with different dimensions, [26,27] Janus droplets with one curable hemisphere, [31,36] and evolved acorn-shaped droplets from double emulsions, [32] can be generated from microfluidics for fabricating nonspherical microparticles with different shapes. However, for the above-mentioned methods, it is difficult to produce microstructured materials with complex Microstructured MaterialsThis work reports on a facile and flexible strategy based on the deformation of encapsulated droplets in fiber-like polymeric matrices for template synthesis of controllable microstructured materials from nonspherical microparticles to complex 3D helices. Monodisperse droplets generated from microfluidics are encapsulated into crosslinked polymeric networks via an interfacial crosslinking reaction in microchannel to in situ produce the droplet-...

show abstract

Microfluidic Fabrication of Biomimetic Helical Hydrogel Microfibers for Blood‐Vessel‐on‐a‐Chip Applications

Jia

Han

Yang

et al. 2019

Adv Healthcare Materials

Self Cite

View full text Add to dashboard Cite

Soft tissue injuries (STIs) affect patients of all age groups and represent a common worldwide clinical problem, resulting from conditions including trauma, infection, cancer and burns. Within the spectrum of STIs a mixture of tissues can be injured, ranging from skin to underlying nerves, blood vessels, tendons and cartilaginous tissues. However, significant limitations affect current treatment options and clinical demand for soft tissue and cartilage regenerative therapies continues to rise.Improving the regeneration of soft tissues has therefore become a key area of focus within tissue engineering. As an emerging technology, 3D bioprinting can be used to build complex soft tissue constructs "from the bottom up," by depositing cells, growth factors, extracellular matrices and other biomaterials in a layer-by-layer fashion. In this way, regeneration of cartilage, skin, vasculature, nerves, tendons and other bodily tissues can be performed in a patient specific manner. This review will focus on recent use of 3D bioprinting and other biofabrication strategies in soft tissue repair and regeneration. Biofabrication of a variety of soft tissue types will be reviewed following an overview of available cell sources, bioinks and bioprinting techniques.

show abstract

Microfluidic Controlled Mass-Transfer and Buckling for Easy Fabrication of Polymeric Helical Fibers

Cited by 25 publications

References 38 publications

Bioinspired Polymeric Helical and Superhelical Microfibers via Microfluidic Spinning

Bioinspired Polymeric Helical and Superhelical Microfibers via Microfluidic Spinning

Controllable Microfluidic Fabrication of Microstructured Materials from Nonspherical Particles to Helices

Microfluidic Fabrication of Biomimetic Helical Hydrogel Microfibers for Blood‐Vessel‐on‐a‐Chip Applications

Contact Info

Product

Resources

About