Renal Epithelial Cell Responses to Supramolecular Thermoplastic Elastomeric Concave and Convex Structures

Gaal, Ronald C. van; Miltenburg, Rogier P. R. S.; Kurniawan, Nicholas A.; Bouten, Cvc Carlijn; Dankers, Patricia Y. W.

doi:10.1002/admi.202001490

Cited by 6 publications

(2 citation statements)

References 39 publications

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“…Inconsistencies between this and a previous study can be attributed to the 3D models applied, that is, microPES type TF10 hollow fiber capillary membrane versus hybrid hydrogel material in this study, but also the distribution of the cells within the structures, i.e. convex versus concave surfaces, with ciPTEC exhibiting a preference for concave over convex surfaces [26,41,42].…”

Section: Discussionmentioning

confidence: 50%

Co-axial printing of convoluted proximal tubule for kidney disease modeling

et al. 2022

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Despite the increasing incidence of kidney-related diseases, we are still far from understanding the underlying mechanisms of these diseases and their progression. This lack of understanding is partly because of a poor replication of the diseases in vitro, limited to planar culture. Advancing towards three-dimensional models, hereby we propose coaxial printing to obtain microfibers containing a helical hollow microchannel. These recapitulate the architecture of the proximal tubule (PT), an important nephron segment often affected in kidney disorders. A stable gelatin/alginate-based ink was formulated to allow printability while maintaining structural properties. Fine tuning of the composition, printing temperature and extrusion rate allowed for optimal ink viscosity that led to coiling of the microfiber’s inner channel. The printed microfibers exhibited prolonged structural stability (42 days) and cytocompatibility in culture. Healthy conditionally immortalized PT epithelial cells and a knockout cell model for cystinosis (CTNS -/- ) were seeded to mimic two genotypes of PT. Upon culturing for 14 days, engineered PT showed homogenous cytoskeleton organization as indicated by staining for filamentous actin, barrier-formation and polarization with apical marker α-tubulin and basolateral marker Na+/K+-ATPase. Cell viability was slightly decreased upon prolonged culturing for 14 days, which was more pronounced in CTNS -/- microfibers. Finally, cystinosis cells showed reduced apical transport activity in the microfibers compared to healthy PT epithelial cells when looking at breast cancer resistance protein and multidrug resistance-associated protein 4. Engineered PT incorporated in a custom-designed microfluidic chip allowed to assess leak-tightness of the epithelium, which appeared less tight in cystinosis PT compared to healthy PT, in agreement with its in vivo phenotype. While we are still on the verge of patient-oriented medicine, this system holds great promise for further research in establishing advanced in vitro disease models.

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Section: Discussionmentioning

confidence: 50%

Co-axial printing of convoluted proximal tubule for kidney disease modeling

et al. 2022

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“…[ 105 ] In addition to more representative mechanical properties, the presence of these concave and convex scaffold regions has demonstrated significant effects on in vitro behavior. Tissue formation has been observed preferentially on concave but not on convex surfaces [ 106–109 ] leading to a hypothesis of pore closure by cellular contraction [ 110 ] and curvature‐driven growth [ 111–114 ] with the same behavior observed on constructs fabricated via MEW. Mirani et al.…”

Section: Mew Scaffold Architecture Informs Cell Behaviormentioning

confidence: 99%

Materials Design Innovations in Optimizing Cellular Behavior on Melt Electrowritten (MEW) Scaffolds

Devlin,

Allenby,

Ren

et al. 2024

Adv Funct Materials

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The field of melt electrowriting (MEW) has seen significant progress, bringing innovative advancements to the fabrication of biomaterial scaffolds, and creating new possibilities for applications in tissue engineering and beyond. Multidisciplinary collaboration across materials science, computational modeling, AI, bioprinting, microfluidics, and dynamic culture systems offers promising new opportunities to gain deeper insights into complex biological systems. As the focus shifts towards personalized medicine and reduced reliance on animal models, the multidisciplinary approach becomes indispensable. This review provides a concise overview of current strategies and innovations in controlling and optimizing cellular responses to MEW scaffolds, highlighting the potential of scaffold material, MEW architecture, and computational modeling tools to accelerate the development of efficient biomimetic systems. Innovations in material science and the incorporation of biologics into MEW scaffolds have shown great potential in adding biomimetic complexity to engineered biological systems. These techniques pave the way for exciting possibilities for tissue modeling and regeneration, personalized drug screening, and cell therapies.

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Thermoforming for Small Feature Replication in Melt Electrowritten Membranes to Model Kidney Proximal Tubule

G Valverde,

Stampa Zamorano,

Kožinec

et al. 2024

Adv Healthcare Materials

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A novel approach merging melt electrowriting (MEW) with matched die thermoforming to achieve scaffolds with micron‐sized curvatures (200 – 800 µm versus 1000 µm of mandrel printing) for in vitro modeling of the kidney proximal tubule (PT) is proposed. Recent advances in this field emphasize the relevance of accurately replicating the intricate tissue microenvironment, particularly the curvature of the nephrons’ tubular segments. While MEW offers promising capabilities for fabricating highly and porous precise 3D structures mimicking the PT, challenges persist in approximating the diameter of tubular scaffolds to match the actual PT. The thermoformed MEW membranes retain the initial MEW printing design parameters (rhombus geometry, porosity > 45%) while accurately following the imprinted curvature (ratios between 0.67‐0.95). PT epithelial cells cultured on these membranes demonstrate the ability to fill in the large pores of the membrane by secreting their own collagen IV‐rich extracellular matrix and form an organized, functional, and tight monolayer expressing characteristic PT markers. Besides approximating PT architecture, this setup maximizes the usable surface area for cell culture and molecular readouts. By closely mimicking the structural intricacies of native tissue architecture, this approach enhances the biomimetic fidelity of engineered scaffolds, offering potential applications beyond kidney tissue engineering.

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Renal Epithelial Cell Responses to Supramolecular Thermoplastic Elastomeric Concave and Convex Structures

Cited by 6 publications

References 39 publications

Co-axial printing of convoluted proximal tubule for kidney disease modeling

Co-axial printing of convoluted proximal tubule for kidney disease modeling

Materials Design Innovations in Optimizing Cellular Behavior on Melt Electrowritten (MEW) Scaffolds

Thermoforming for Small Feature Replication in Melt Electrowritten Membranes to Model Kidney Proximal Tubule

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