Ice Templating Soft Matter: Fundamental Principles and Fabrication Approaches to Tailor Pore Structure and Morphology and Their Biomedical Applications

Joukhdar, Habib; Seifert, Annika; Jüngst, Tomasz; Groll, Jürgen; Lord, Megan S.; Rnjak‐Kovacina, Jelena

doi:10.1002/adma.202100091

Cited by 140 publications

(109 citation statements)

References 158 publications

(264 reference statements)

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“…Faster freezing rate leads to smaller pore size, which is matched with the conclusion from previous work. [ 22 ] The fast solidification process of two different molecules, namely water and isopropanol, leads to multidirectional freezing and forms various spatial shapes as shown in Figure 2c; meanwhile the slow solidification process leads to unidirectional freezing and forms a ladder‐like pore shape as shown in Figure 2g. Several gullies are observed on the surface of the membrane (−20 °C), which is due to the formation of amorphous regions between solvent crystal zones.…”

Section: Resultsmentioning

confidence: 99%

“…[ 19,20 ] Among numerous porous aerogels for adsorbents, chitosan (CS) aerogel with high porosity, large specific surface area, and biocompatibility is particularly suitable for the adsorption of biomolecules in comparison to synthetic materials. [ 21 ] By controlling the condition of the gelation process (freezing temperature and solution viscosity), pore size and morphology of chitosan aerogel can be intentionally tailored, [ 22–24 ] in which the large surface area of aerogels is modified with different functional groups such as imide, [ 25 ] amine, [ 21,24 ] methyl, [ 26 ] and carbamate [ 27 ] for various applications of molecular adsorption. Therein, the cellulose‐based chitosan aerogel has widely been studied in the field of purification and separation of proteins, [ 28,29 ] whereas cellulose‐based chitosan adsorbents have to be modified with ligands in a relatively low adsorption efficiency and capacity, which have hindered large‐scale application in biomolecule adsorption.…”

Section: Introductionmentioning

confidence: 99%

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High‐Yield of Nucleic Acid Adsorption via Poly(Vinyl Alcohol‐co‐Ethylene) Nanofiber‐Based Anion‐Exchange Chitosan Aerogel Membrane with Controllable Porosity

Wang

Wan

et al. 2022

Adv Materials Inter

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Due to the fast degradation time and low storage temperature of nucleic acid, a simple, fast, and highly efficient adsorption process is imperious for the extraction of nucleic acid molecules. In this article, a poly(vinyl alcohol‐co‐ethylene) (EVOH) nanofiber‐based and polyethyleneimine (PEI)‐modified chitosan (ENPC) aerogel with high static adsorption capacity of RNA and DNA molecules (812 and 867 mg g−1, respectively) is proved for enormous potential in adsorption capacity for nucleic acid extraction. A relation between adsorption capacity and the physical morphology of ENPC aerogel membrane is demonstrated with the controllable factors such as chemical components, freeze‐drying temperature, pH value of the nucleic acid solution, and membrane density. The mechanism of the anion‐exchange adsorption process of nucleic acid is analyzed and fitted well with the pseudo‐second‐order kinetic model and Langmuir isotherm (monolayer adsorption). The as‐obtained ENPC aerogel in the form of a membrane with self‐cleaning and flexible properties can be easily tailored and widely utilized in a convenient and efficient extraction process of nucleic acids in both industrial and experimental levels.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High‐Yield of Nucleic Acid Adsorption via Poly(Vinyl Alcohol‐co‐Ethylene) Nanofiber‐Based Anion‐Exchange Chitosan Aerogel Membrane with Controllable Porosity

Wang

Wan

et al. 2022

Adv Materials Inter

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“…Moreover, these scaffolds exhibited a thin sheet-like lamellae network, where increasing the silk concentration resulted in thicker lamellae. This is expected as more ice crystals form within the negative cast of the pores during the fabrication process, thus displacing the silk dissolved in the solution and creating a concentrated silk layer surrounding the fully formed crystal (Joukhdar et al 2021). Hence, the increased lamellae thickness of the 5 wt% scaffold can be attributed to an increased quantity of silk available to concentrate around the ice crystals during fabrication.…”

Section: Discussionmentioning

confidence: 99%

Bone tissue engineering using 3D silk scaffolds and human dental pulp stromal cells epigenetic reprogrammed with the selective histone deacetylase inhibitor MI192

et al. 2022

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Epigenetics plays a critical role in regulating mesenchymal stem cells’ (MSCs) fate for tissue repair and regeneration. There is increasing evidence that the inhibition of histone deacetylase (HDAC) isoform 3 can enhance MSC osteogenesis. This study investigated the potential of using a selective HDAC2 and 3 inhibitor, MI192, to promote human dental pulp stromal cells (hDPSCs) bone-like tissue formation in vitro and in vivo within porous Bombyx Mori silk scaffolds. Both 2 and 5 wt% silk scaffolds were fabricated and characterised. The 5 wt% scaffolds possess thicker internal lamellae, reduced scaffold swelling and degradation rates, whilst increased compressive modulus in comparison to the 2 wt% silk scaffold. MI192 pre-treatment of hDPSCs on 5 wt% silk scaffold significantly enhanced hDPSCs alkaline phosphatase activity (ALP). The expression of osteoblast-related genes (RUNX2, ALP, Col1a, OCN) was significantly upregulated in the MI192 pre-treated cells. Histological analysis confirmed that the MI192 pre-treated hDPSCs-silk scaffold constructs promoted bone extracellular matrix (ALP, Col1a, OCN) deposition and mineralisation compared to the untreated group. Following 6 weeks of subcutaneous implantation in nude mice, the MI192 pre-treated hDPSCs-silk scaffold constructs enhanced the vascularisation and extracellular matrix mineralisation compared to untreated control. In conclusion, these findings demonstrate the potential of using epigenetic reprogramming and silk scaffolds to promote hDPSCs bone formation efficacy, which provides evidence for clinical translation of this technology for bone augmentation. Graphical abstract

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“…[10,11] In particular, ice-templating, one of the most widely utilized techniques for the fabrication of materials with anisotropic microchannels, allows control over pore morphologies by controlling directional ice formation in a suspension of solute(s). [12][13][14][15] During the freezing process, ice crystals form and propagate through a set direction within the biomaterial solution. When the construct cross-links and thaws, the melted ice crystals form interconnected anisotropic microchannels within the scaffold.…”

mentioning

confidence: 99%

Vertical Extrusion Cryo(bio)printing for Anisotropic Tissue Manufacturing

et al. 2022

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extrusion bioprinting is mainly used for constructing volumetric structures in a layer-wise manner. [5] Although the layerby-layer bioprinting method is functional in majority of the cases, [6] there are limitations associated with creating anisotropic tissues, such as muscle fibers [7,8] and nerve fibers [9] that heavily rely on cellular alignment for their physiologies. Therefore, developing a versatile strategy that allows convenient 3D bioprinting synergized with simultaneous generation of structural anisotropy is essential for these applications.Numerous studies have shown that porous hydrogel scaffolds can potentially enhance cell spreading and proliferation. [10,11] In particular, ice-templating, one of the most widely utilized techniques for the fabrication of materials with anisotropic microchannels, allows control over pore morphologies by controlling directional ice formation in a suspension of solute(s). [12][13][14][15] During the freezing process, ice crystals form and propagate through a set direction within the biomaterial solution. When the construct cross-links and thaws, the melted ice crystals form interconnected anisotropic microchannels within the scaffold. Importantly, previous studies have clearly demonstrated that the presence of anisotropic microchannels enhances Due to the poor mechanical properties of many hydrogel bioinks, conventional 3D extrusion bioprinting is usually conducted based on the X-Y plane, where the deposited layers are stacked in the Z-direction with or without the support of prior layers. Herein, a technique is reported, taking advantage of a cryoprotective bioink to enable direct extrusion bioprinting in the vertical direction in the presence of cells, using a freezing plate with precise temperature control. Of interest, vertical 3D cryo-bioprinting concurrently allows the user to create freestanding filamentous constructs containing interconnected, anisotropic microchannels featuring gradient sizes aligned in the vertical direction, also associated with enhanced mechanical performances. Skeletal myoblasts within the 3D-cryo-bioprinted hydrogel constructs show enhanced cell viability, spreading, and alignment, compared to the same cells in the standard hydrogel constructs. This method is further extended to a multimaterial format, finding potential applications in interface tissue engineering, such as creation of the muscle-tendon unit and the muscle-microvascular unit. The unique vertical 3D cryo-bioprinting technique presented here suggests improvements in robustness and versatility to engineer certain tissue types especially those anisotropic in nature, and may extend broad utilities in tissue engineering, regenerative medicine, drug discovery, and personalized therapeutics.

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Ice Templating Soft Matter: Fundamental Principles and Fabrication Approaches to Tailor Pore Structure and Morphology and Their Biomedical Applications

Cited by 140 publications

References 158 publications

High‐Yield of Nucleic Acid Adsorption via Poly(Vinyl Alcohol‐co‐Ethylene) Nanofiber‐Based Anion‐Exchange Chitosan Aerogel Membrane with Controllable Porosity

High‐Yield of Nucleic Acid Adsorption via Poly(Vinyl Alcohol‐co‐Ethylene) Nanofiber‐Based Anion‐Exchange Chitosan Aerogel Membrane with Controllable Porosity

Bone tissue engineering using 3D silk scaffolds and human dental pulp stromal cells epigenetic reprogrammed with the selective histone deacetylase inhibitor MI192

Vertical Extrusion Cryo(bio)printing for Anisotropic Tissue Manufacturing

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