TY  - INPR
A1  - Schaefer, Natascha
A1  - Janzen, Dieter
A1  - Bakirci, Ezgi
A1  - Hrynevich, Andrei
A1  - Dalton, Paul D.
A1  - Villmann, Carmen
T1  - 3D Electrophysiological Measurements on Cells Embedded within Fiber-Reinforced Matrigel
T2  - Advanced Healthcare Materials
N2  - 2D electrophysiology is often used to determine the electrical properties of neurons, while in the brain, neurons form extensive 3D networks. Thus, performing electrophysiology in a 3D environment provides a closer situation to the physiological condition and serves as a useful tool for various applications in the field of neuroscience. In this study, we established 3D electrophysiology within a fiber-reinforced matrix to enable fast readouts from transfected cells, which are often used as model systems for 2D electrophysiology. Using melt electrowriting (MEW) of scaffolds to reinforce Matrigel, we performed 3D electrophysiology on a glycine receptor-transfected Ltk-11 mouse fibroblast cell line. The glycine receptor is an inhibitory ion channel associated when mutated with impaired neuromotor behaviour. The average thickness of the MEW scaffold was 141.4 ± 5.7µm, using 9.7 ± 0.2µm diameter fibers, and square pore spacings of 100 µm, 200 µm and 400 µm. We demonstrate, for the first time, the electrophysiological characterization of glycine receptor-transfected cells with respect to agonist efficacy and potency in a 3D matrix. With the MEW scaffold reinforcement not interfering with the electrophysiology measurement, this approach can now be further adapted and developed for different kinds of neuronal cultures to study and understand pathological mechanisms under disease conditions.
KW  - 3D cultures
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-244194
ER  - 
TY  - JOUR
A1  - Thibaudeau, Laure
A1  - Taubenberger, Anna V.
A1  - Holzapfel, Boris M.
A1  - Quent, Verena M.
A1  - Fuehrmann, Tobias
A1  - Hesami, Parisa
A1  - Brown, Toby D.
A1  - Dalton, Paul D.
A1  - Power, Carl A.
A1  - Hollier, Brett G.
A1  - Hutmacher, Dietmar W.
T1  - A tissue-engineered humanized xenograft model of human breast cancer metastasis to bone
JF  - Disease Models & Mechanisms
N2  - The skeleton is a preferred homing site for breast cancer metastasis. To date, treatment options for patients with bone metastases are mostly palliative and the disease is still incurable. Indeed, key mechanisms involved in breast cancer osteotropism are still only partially understood due to the lack of suitable animal models to mimic metastasis of human tumor cells to a human bone microenvironment. In the presented study, we investigate the use of a human tissue-engineered bone construct to develop a humanized xenograft model of breast cancer-induced bone metastasis in a murine host. Primary human osteoblastic cell-seeded melt electrospun scaffolds in combination with recombinant human bone morphogenetic protein 7 were implanted subcutaneously in non-obese diabetic/severe combined immunodeficient mice. The tissue-engineered constructs led to the formation of a morphologically intact 'organ' bone incorporating a high amount of mineralized tissue, live osteocytes and bone marrow spaces. The newly formed bone was largely humanized, as indicated by the incorporation of human bone cells and human-derived matrix proteins. After intracardiac injection, the dissemination of luciferase-expressing human breast cancer cell lines to the humanized bone ossicles was detected by bioluminescent imaging. Histological analysis revealed the presence of metastases with clear osteolysis in the newly formed bone. Thus, human tissue-engineered bone constructs can be applied efficiently as a target tissue for human breast cancer cells injected into the blood circulation and replicate the osteolytic phenotype associated with breast cancer-induced bone lesions. In conclusion, we have developed an appropriate model for investigation of species-specific mechanisms of human breast cancer-related bone metastasis in vivo.
KW  - breast cancer
KW  - bone metastasis
KW  - humanized xenograft model
KW  - melt electrospinning
KW  - tissue engineering
KW  - osteotropism
KW  - in vivo
KW  - stem-cell niche
KW  - human prostate-cancer
KW  - morphogenetic protein
KW  - osteoprogenitor cells
KW  - endochondral ossification
KW  - mouse model
KW  - trabecular bone
KW  - calcium phosphate
KW  - skeletal metastases
Y1  - 2014
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-117466
VL  - 7
IS  - 2
ER  - 
TY  - JOUR
A1  - Wieland, Annalena
A1  - Strissel, Pamela L.
A1  - Schorle, Hannah
A1  - Bakirci, Ezgi
A1  - Janzen, Dieter
A1  - Beckmann, Matthias W.
A1  - Eckstein, Markus
A1  - Dalton, Paul D.
A1  - Strick, Reiner
T1  - Brain and breast cancer cells with PTEN loss of function reveal enhanced durotaxis and RHOB dependent amoeboid migration utilizing 3D scaffolds and aligned microfiber tracts
JF  - Cancers
N2  - Background: Glioblastoma multiforme (GBM) and metastatic triple-negative breast cancer (TNBC) with PTEN mutations often lead to brain dissemination with poor patient outcome, thus new therapeutic targets are needed. To understand signaling, controlling the dynamics and mechanics of brain tumor cell migration, we implemented GBM and TNBC cell lines and designed 3D aligned microfibers and scaffolds mimicking brain structures. Methods: 3D microfibers and scaffolds were printed using melt electrowriting. GBM and TNBC cell lines with opposing PTEN genotypes were analyzed with RHO-ROCK-PTEN inhibitors and PTEN rescue using live-cell imaging. RNA-sequencing and qPCR of tumor cells in 3D with microfibers were performed, while scanning electron microscopy and confocal microscopy addressed cell morphology. Results: In contrast to the PTEN wildtype, GBM and TNBC cells with PTEN loss of function yielded enhanced durotaxis, topotaxis, adhesion, amoeboid migration on 3D microfibers and significant high RHOB expression. Functional studies concerning RHOB-ROCK-PTEN signaling confirmed the essential role for the above cellular processes. Conclusions: This study demonstrates a significant role of the PTEN genotype and RHOB expression for durotaxis, adhesion and migration dependent on 3D. GBM and TNBC cells with PTEN loss of function have an affinity for stiff brain structures promoting metastasis. 3D microfibers represent an important tool to model brain metastasizing tumor cells, where RHO-inhibitors could play an essential role for improved therapy.
KW  - 3D tumor model
KW  - 3D microfiber
KW  - amoeboid cell migration
KW  - brain cancer
KW  - breast cancer
KW  - PTEN
KW  - RHO
KW  - ROCK
KW  - durotaxis
KW  - topotaxis
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-248443
SN  - 2072-6694
VL  - 13
IS  - 20
ER  - 
TY  - JOUR
A1  - Mieszczanek, Pawel
A1  - Robinson, Thomas M.
A1  - Dalton, Paul D.
A1  - Hutmacher, Dietmar W.
T1  - Convergence of Machine Vision and Melt Electrowriting
JF  - Advanced Materials
N2  - Melt electrowriting (MEW) is a high-resolution additive manufacturing technology that balances multiple parametric variables to arrive at a stable fabrication process. The better understanding of this balance is underscored here using high-resolution camera vision of jet stability profiles in different electrical fields. Complementing this visual information are fiber-diameter measurements obtained at precise points, allowing the correlation to electrified jet properties. Two process signatures—the jet angle and for the first time, the Taylor cone area—are monitored and analyzed with a machine vision system, while SEM imaging for diameter measurement correlates real-time information. This information, in turn, allows the detection and correction of fiber pulsing for accurate jet placement on the collector, and the in-process assessment of the fiber diameter. Improved process control is used to successfully fabricate collapsible MEW tubes; structures that require exceptional accuracy and printing stability. Using a precise winding angle of 60° and 300 layers, the resulting 12 mm-thick tubular structures have elastic snap-through instabilities associated with mechanical metamaterials. This study provides a detailed analysis of the fiber pulsing occurrence in MEW and highlights the importance of real-time monitoring of the Taylor cone volume to better understand, control, and predict printing instabilities.
KW  - polycaprolactone
KW  - 3D printing
KW  - digitization
KW  - electrohydrodynamic
KW  - melt electrospinning writing
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-256365
VL  - 33
IS  - 29
ER  - 
TY  - JOUR
A1  - Janzen, Dieter
A1  - Bakirci, Ezgi
A1  - Wieland, Annalena
A1  - Martin, Corinna
A1  - Dalton, Paul D.
A1  - Villmann, Carmen
T1  - Cortical Neurons form a Functional Neuronal Network in a 3D Printed Reinforced Matrix
JF  - Advanced Healthcare Materials
N2  - Impairments in neuronal circuits underly multiple neurodevelopmental and neurodegenerative disorders. 3D cell culture models enhance the complexity of in vitro systems and provide a microenvironment closer to the native situation than with 2D cultures. Such novel model systems will allow the assessment of neuronal network formation and their dysfunction under disease conditions. Here, mouse cortical neurons are cultured from embryonic day E17 within in a fiber‐reinforced matrix. A soft Matrigel with a shear modulus of 31 ± 5.6 Pa is reinforced with scaffolds created by melt electrowriting, improving its mechanical properties and facilitating the handling. Cortical neurons display enhance cell viability and the neuronal network maturation in 3D, estimated by staining of dendrites and synapses over 21 days in vitro, is faster in 3D compared to 2D cultures. Using functional readouts with electrophysiological recordings, different firing patterns of action potentials are observed, which are absent in the presence of the sodium channel blocker, tetrodotoxin. Voltage‐gated sodium currents display a current–voltage relationship with a maximum peak current at −25 mV. With its high customizability in terms of scaffold reinforcement and soft matrix formulation, this approach represents a new tool to study neuronal networks in 3D under normal and, potentially, disease conditions.
KW  - 3D electrophysiology
KW  - 3D neuronal networks
KW  - cortical neurons
KW  - melt electrowriting
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-215400
VL  - 9
IS  - 9
ER  - 
TY  - JOUR
A1  - Hrynevich, Andrei
A1  - Achenbach, Pascal
A1  - Jungst, Tomasz
A1  - Brook, Gary A.
A1  - Dalton, Paul D.
T1  - Design of Suspended Melt Electrowritten Fiber Arrays for Schwann Cell Migration and Neurite Outgrowth
JF  - Macromolecular Bioscience
N2  - In this study, well-defined, 3D arrays of air-suspended melt electrowritten fibers are made from medical grade poly(ɛ-caprolactone) (PCL). Low processing temperatures, lower voltages, lower ambient temperature, increased collector distance, and high collector speeds all aid to direct-write suspended fibers that can span gaps of several millimeters between support structures. Such processing parameters are quantitatively determined using a “wedge-design” melt electrowritten test frame to identify the conditions that increase the suspension probability of long-distance fibers. All the measured parameters impact the probability that a fiber is suspended over multimillimeter distances. The height of the suspended fibers can be controlled by a concurrently fabricated fiber wall and the 3D suspended PCL fiber arrays investigated with early post-natal mouse dorsal root ganglion explants. The resulting Schwann cell and neurite outgrowth extends substantial distances by 21 d, following the orientation of the suspended fibers and the supporting walls, often generating circular whorls of high density Schwann cells between the suspended fibers. This research provides a design perspective and the fundamental parametric basis for suspending individual melt electrowritten fibers into a form that facilitates cell culture.
KW  - cell migration
KW  - electrospinning
KW  - fibers
KW  - neurite growth
KW  - polycaprolactone
KW  - tissue engineering
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-257535
VL  - 21
IS  - 7
ER  - 
TY  - JOUR
A1  - Liashenko, Ievgenii
A1  - Hrynevich, Andrei
A1  - Dalton, Paul D.
T1  - Designing Outside the Box: Unlocking the Geometric Freedom of Melt Electrowriting using Microscale Layer Shifting
JF  - Advanced Materials
N2  - Melt electrowriting, a high‐resolution additive manufacturing technology, has so far been developed with vertical stacking of fiber layers, with a printing trajectory that is constant for each layer. In this work, microscale layer shifting is introduced through deliberately offsetting the printing trajectory for each printed layer. Inaccuracies during the printing of sinusoidal walls are corrected via layer shifting, resulting in accurate control of their geometry and mechanical properties. Furthermore, more substantial layer shifting allows stacking of fiber layers in a horizontal manner, overcoming the electrostatic autofocusing effect that favors vertical layer stacking. Novel nonlinear geometries, such as overhangs, wall texturing and branching, and smooth and abrupt changes in printing trajectory are presented, demonstrating the flexibility of the layer shifting approach beyond the state‐of‐the‐art. The practice of microscale layer shifting for melt electrowriting enables more complex geometries that promise to have a profound impact on the development of products in a broad range of applications.
KW  - 3D printing
KW  - additive manufacturing
KW  - biomaterials
KW  - electrohydrodynamics
KW  - melt electrospinning writing
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-217974
VL  - 32
IS  - 28
ER  - 
TY  - JOUR
A1  - Kotz, Frederik
A1  - Risch, Patrick
A1  - Arnold, Karl
A1  - Sevim, Semih
A1  - Puigmartí-Luis, Josep
A1  - Quick, Alexander
A1  - Thiel, Michael
A1  - Hrynevich, Andrei
A1  - Dalton, Paul D.
A1  - Helmer, Dorothea
A1  - Rapp, Bastian E.
T1  - Fabrication of arbitrary three-dimensional suspended hollow microstructures in transparent fused silica glass
JF  - Nature Communications
N2  - Fused silica glass is the preferred material for applications which require long-term chemical and mechanical stability as well as excellent optical properties. The manufacturing of complex hollow microstructures within transparent fused silica glass is of particular interest for, among others, the miniaturization of chemical synthesis towards more versatile, configurable and environmentally friendly flow-through chemistry as well as high-quality optical waveguides or capillaries. However, microstructuring of such complex three-dimensional structures in glass has proven evasive due to its high thermal and chemical stability as well as mechanical hardness. Here we present an approach for the generation of hollow microstructures in fused silica glass with high precision and freedom of three-dimensional designs. The process combines the concept of sacrificial template replication with a room-temperature molding process for fused silica glass. The fabricated glass chips are versatile tools for, among other, the advance of miniaturization in chemical synthesis on chip.
KW  - chemical engineering
KW  - fluidics
KW  - materials for optics
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-224787
VL  - 10
ER  - 
TY  - JOUR
A1  - Wang, Shuang
A1  - Sarwat, Mariah
A1  - Wang, Peng
A1  - Surrao, Denver C.
A1  - Harkin, Damien G.
A1  - St John, James A.
A1  - Bolle, Eleonore C. L.
A1  - Forget, Aurelien
A1  - Dalton, Paul D.
A1  - Dargaville, Tim R.
T1  - Hydrogels with Cell Adhesion Peptide‐Decorated Channel Walls for Cell Guidance
JF  - Macromolecular Rapid Communications
N2  - A method is reported for making hollow channels within hydrogels decorated with cell‐adhesion peptides exclusively at the channel surface. Sacrificial fibers of different diameters are used to introduce channels within poly(ethylene glycol) hydrogels crosslinked with maleimide‐thiol chemistry, which are backfilled with a cysteine‐containing peptide solution which is conjugated to the lumen with good spatial efficiency. This allows for peptide patterning in only the areas of the hydrogel where they are needed when used as cell‐guides, reducing the amount of required peptide 20‐fold when compared to bulk functionalization. The power of this approach is highlighted by successfully using these patterned hydrogels without active perfusion to guide fibroblasts and olfactory ensheathing cells—the latter having unique potential in neural repair therapies.
KW  - 3D printing
KW  - cell guidance
KW  - cell transplantation
KW  - melt electrowriting
KW  - synthetic hydrogels
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-218031
VL  - 41
IS  - 15
ER  - 
TY  - JOUR
A1  - Mechau, Jannik
A1  - Frank, Andreas
A1  - Bakirci, Ezgi
A1  - Gumbel, Simon
A1  - Jungst, Tomasz
A1  - Giesa, Reiner
A1  - Groll, Jürgen
A1  - Dalton, Paul D.
A1  - Schmidt, Hans‐Werner
T1  - Hydrophilic (AB)\(_{n}\) Segmented Copolymers for Melt Extrusion‐Based Additive Manufacturing
JF  - Macromolecular Chemistry and Physics
N2  - Several manufacturing technologies beneficially involve processing from the melt, including extrusion‐based printing, electrospinning, and electrohydrodynamic jetting. In this study, (AB)\(_{n}\) segmented copolymers are tailored for melt‐processing to form physically crosslinked hydrogels after swelling. The copolymers are composed of hydrophilic poly(ethylene glycol)‐based segments and hydrophobic bisurea segments, which form physical crosslinks via hydrogen bonds. The degree of polymerization was adjusted to match the melt viscosity to the different melt‐processing techniques. Using extrusion‐based printing, a width of approximately 260 µm is printed into 3D constructs, with excellent interlayer bonding at fiber junctions, due to hydrogen bonding between the layers. For melt electrospinning, much thinner fibers in the range of about 1–15 µm are obtained and produced in a typical nonwoven morphology. With melt electrowriting, fibers are deposited in a controlled way to well‐defined 3D constructs. In this case, multiple fiber layers fuse together enabling constructs with line width in the range of 70 to 160 µm. If exposed to water the printed constructs swell and form physically crosslinked hydrogels that slowly disintegrate, which is a feature for soluble inks within biofabrication strategies. In this context, cytotoxicity tests confirm the viability of cells and thus demonstrating biocompatibility of this class of copolymers.
KW  - 3D printing
KW  - (AB)\(_{n}\) segmented copolymers
KW  - biocompatibility
KW  - melt electrowriting
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-224513
VL  - 222
IS  - 1
ER  -