Abstract
Human induced pluripotent stem cell-derived neural progenitor cells (hNPCs) are a promising cell source for stem cell transplantation to treat neurological diseases such as stroke and peripheral nerve injuries. However, there have been limited studies investigating how the dimensionality of the physical and electrical microenvironment affects hNPC function. In this study, we report the fabrication of two- and three-dimensional (2D and 3D respectively) constructs composed of a conductive polymer to compare the effect of electrical stimulation of hydrogel-immobilized hNPCs. The physical dimension (2D vs 3D) of stimulating platforms alone changed the hNPCs gene expression related to cell proliferation and metabolic pathways. The addition of electrical stimulation was critical in upregulating gene expression of neurotrophic factors that are important in regulating cell survival, synaptic remodeling, and nerve regeneration. This study demonstrates that the applied electrical field controls hNPC properties depending on the physical nature of stimulating platforms and cellular metabolic states. The ability to control hNPC functions can be beneficial in understanding mechanistic changes related to electrical modulation and devising novel treatment methods for neurological diseases.
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Introduction
Neurological diseases and injuries are devastating, often resulting in high morbidity and long-term disability due to the limited regenerative ability of endogenous cells1,2,3. Stem cell therapy has emerged as a promising treatment approach4,5 because of cells’ ability to proliferate and the potential to differentiate into one or more lineages under appropriate conditions6,7,8. Specifically, human induced pluripotent stem cells (hiPSCs) reprogrammed from somatic cells have been successfully differentiated into human neural progenitor cells (hNPCs)9,10. Transplantation of hNPCs improves functional neurological recovery through increased angiogenesis, dendritic branching and new axonal projections, production of neurotrophic factors, and modulation of the immune system11,12,13,14. However, the success of hNPC transplantation is currently limited by short-term survival of cells and their failure to integrate with the host tissue15,16,17. It is crucial to understand how hNPCs are influenced by the microenvironmental cues to sustain their viability and potentially enhance the therapeutic efficacy for nerve repair.
The native stem cell niche presents a complex physiochemical microenvironment involving physical (i.e. mechanical stress), chemical (i.e. growth factors), and electrical signals that can dictate stem cell fate and behaviors. Particularly, electrical stimulation plays an important role in biological processes including wound healing, tissue repair, embryogenesis, and remodeling and growth of organisms18,19,20,21,22. In the clinical setting, electrical treatment has been applied to revive damaged tissues in the neuromuscular system to accelerate the healing of injured tissues such as nerve, bone, ligament, and articular cartilage23,24,25,26. The influence of electrical stimulation on stem cells has been widely reported on a variety of cell types and exposure conditions with regard to cell proliferation, differentiation, migration, and ion channel densities18,19,27,28,29,30,31,32,33,34,35. For instance, human mesenchymal stem cells showed increased proliferation and multi-lineage differentiation potential under long-term exposure to pulsed electromagnetic fields from weeks to a month27,28,34,35. Electrical stimulation led to longer neurites and greater branching of neural stem cells cultured under differentiation conditions in vitro18,33. Previous studies also demonstrated that the electrical signal not only guides the migration of neural stem cells in vivo32 but also leads to their differentiation ex vivo31. Many studies focused on how the electrical field involved with cell mobilization and long-term differentiation in a voltage or time-dependent manner18,36,37,38,39. However, there is limited understanding on the effects of the dimensionality of electrical stimulation on hNPCs.
Conductive polymers have gained significant interests due to their ability to interface with neural tissues22,40,41,42,43. These conductive biomaterials provide a unique platform to study the stem cells function and behaviors electrically. In this study, we have derived scaffolds made of the conductive polymer, polypyrrole (PPy), to understand the effect of changing the dimensionality of electrical stimulating platforms on hNPCs. Specifically, the 2D and 3D PPy scaffolds were electropolymerized and incorporated with hydrogel-immobilized hNPCs. We investigated the physical effect (2D vs 3D) as well as the effect of electrical stimulation on the gene profile of hNPCs. We showed that 2D and 3D electrically-stimulated hNPCs exhibited significant changes in the expression of neurotrophic factors under a brief electrical stimulation. The change in gene expression could be a result of differences in dimensionality of electrical stimulation and nutrient availability associated with the 2D and 3D scaffolds. Neurotrophic factors are known to be important in regulating cell survival, synaptic remodeling and nerve regeneration44,45,46,47,48. Therefore, the understanding of the interplay between biophysical cues and electrical signals on hNPCs holds great potential for developing promising therapeutic strategies for nerve regeneration in the future.
Results and Discussion
Differentiation of hiPSCs to hNPCs
As described previously, the inhibition by SMAD inhibitors showed effective induction of hiPSCs into hNPCs in the early neuroepithelial progenitor (NEP) phase9,10. Following a 7-day induction procedure, a majority of the cells were organized into “rosettes” where the levels of PAX6, SOX1, SOX2, and Nestin were highly expressed at 97.8 ± 7.5%, 99.8 ± 0.7%, 96.8 ± 1.9%, and 97 ± 2.3%, respectively (Suppl. Fig. 1). PAX6, a neuroectodermal marker49, is expressed in the regions of the forebrain that give rise to the cortex and functions in the patterning of the brain50. A prior study showed that the overexpression of PAX6 favors neural lineage commitment by differentiation into radial glia and subsequently neurons51. SOX1 is also one of the earliest expressed neuroectodermal markers51,52,53, and its level of expression increases when NEPs differentiate towards NPCs54,55. It is a marker for proliferating NPCs with roles in enhancing and maintaining neuroectodermal commitment51,56. Additionally, SOX2 is highly expressed in proliferating NPCs to maintain neural progenitor identity and is downregulated upon further differentiation to neuronal and glial cells57,58. Nestin, an intermediate filament protein, expresses exclusively in uncommitted NPCs both in vitro and in vivo59,60. The downregulation of Nestin results in cell differentiation into neurons or glial cells61,62. Our immunofluorescent data showed a uniform expression of these markers, indicating the successful differentiation of hiPSCs into hNPCs (Suppl. Fig. 1).
2D and 3D hNPCs scaffolds
PPy is one of the most thoroughly investigated conductive polymers for biomedical applications due to its ease for fabrication, high electrical conductivity, and excellent biocompatibility22,41,42,63,64. It is known that electrodeposited polymers that are doped with various agents exhibit altered physical, chemical, and electrical properties41. Textured surfaces and porous structures could be produced by different electroplating conditions (e.g. lower temperatures) previously described for planar and tubular surfaces41,42,63.
In our study, NaDBS-doped PPy was electroplated at room temperature (Fig. 1a) which resulted in a smooth surface with a mechanically rigid structure for both 2D and 3D conductive PPy scaffolds (Fig. 1b–e). Further inspection showed that the 2D PPy films exhibited a smooth surface morphology (Fig. 1b,c). The inside of the 3D PPy tubes was smooth, whereas the outer surface of 3D PPy tubes was slightly uneven microscopically (Fig. 1d,e). The cross-sectional images showed crystalline structures that were mechanically rigid and insoluble (Fig. 1c,e).
Modeling the fields produced by 2D and 3D PPy scaffolds
The 2D and 3D conductive PPy scaffolds were connected with external wires that allowed for direct electrical stimulation (Fig. 2a). Using an electromagnetic field simulation based on the finite element method for modeling, we observed that sites where the external wires were attached showed a greater field strength. The average field strength for 2D and 3D conditions were 53.6 ± 9.5 V/m and 51.1 ± 2.5 V/m, respectively (Fig. 2b,c). The majority of area in both the 2D and 3D conductive PPy scaffolds exhibited longitudinally and horizontally uniform field strength (~40 V/m) despite the difference in the physical shape of stimulating platform (Fig. 2). Cells were subsequently seeded in those regions with uniform electrical field for both conditions. The Maxwell equation used in this computation employs a homogeneous isotropic medium to model the air and gel, thus not capturing the dimensional variation of the gel’s electrical properties. Moreover, despite the similar electric field strengths, the direction and distribution of the electrical fields are different between the 2D films and 3D tubes. Cells encapsulated in 3D tubes could experience a more unidirectional stimulation signal, whereas cells seeding on 2D films encounter a less uniform stimulation signal due to stronger edge effects. Our stimulating platforms provide a comparable magnitude of electrical stimulation (40 V/m or 0.4 V/cm) to the previous literature. For instance, a carbon nanotube-based scaffold that delivered 0.15 V/cm for 2 ms duration at a frequency of 1 Hz for two weeks re-oriented human mesenchymal stem cells and promoted differentiation towards a cardiac genotype65. A graphene-based conductive substrate enhanced the protein synthesis involved in the cell mobility in relation to the cytoskeleton under electrical exposure of 0.045-4.5 V/cm for 32 minutes38. Human fibroblasts remained their orientation under one-hour electrical exposure of 2-4 V/cm, but they re-oriented themselves under a stronger electrical field exposure at 7 V/cm66. Bone marrow-derived rat mesenchymal stem cells showed no signs of re-alignment with the same electrical setup.
Viability of hNPCs on conductive scaffolds
After hiPSCs were successfully differentiated into hNPCs, the alginate-immobilized hNPCs were either deposited onto the 2D PPy films or encapsulated into the 3D PPy tubes (Fig. 2a). The total number of hNPCs (~1 million) and the density of cells in the alginate were identical for both platforms. With 1 hr of electrical stimulation of hNPCs on the 2D and 3D PPy scaffolds with identical electrical field strength, we observed that electrical stimulation alone did not change the viability of the hNPCs based on the lactate dehydrogenase (LDH) and alamar blue assays. The LDH assay showed that the percentage of dead cells was 1.6 ± 0.5% and 3.1 ± 1.2% for hNPCs on 2D PPy films, and 19 ± 4.2% and 16 ± 2.8% for 3D PPy tubes under unstimulated and stimulated conditions, respectively (Fig. 3a). The alamar blue assay showed that the cell viability was 92 ± 1.1% and 90 ± 2.6% for unstimulated and stimulated hNPCs on 2D PPy films, and unstimulated and stimulated hNPCs in 3D PPy tubes were 56 ± 15% and 52 ± 15%, respectively (Fig. 3b). Although no significant difference in cell viability resulted from direct electrical stimulation using 2D and 3D scaffolds, we observed that cells on 2D PPy films were more viable compared to the 3D PPy tubes with LDH (unstimulated 2D and 3D cell death: 1.6 ± 0.5% vs 19 ± 4.2%; stimulated 2D and 3D cell death: 3.1 ± 1.2% vs 16 ± 2.8%) and alamar blue assays (unstimulated 2D vs 3D viability: 92 ± 1.1% vs 56 ± 15%; stimulated 2D vs 3D viability: 90 ± 2.6% vs 52 ± 15%). This is likely due to the impermeability of PPy (Fig. 1b–e), which only allowed the axial diffusion of nutrients and waste in the 3D tubes, resulting in a decreased viability compared to those cultured on 2D films. These results were further supported by the modeling of oxygen and glucose transport67 for hNPCs on the 2D and 3D PPy scaffolds. Without cells, oxygen and glucose concentrations for 2D films and 3D tubes reached equilibrium with the surrounding culture solution (Fig. 3c,d left panels). However, once cells were placed, the 3D scaffolds showed significant nutrient depletion in the tube lumen, whereas the 2D films exhibited minimal changes in oxygen and glucose gradients (Fig. 3c,d right panels). One limitation associated with modeling cell-incorporated scaffolds is that nutrient consumption was kept at a constant rate, which might not be representative to the real-time cell consumption as the cell survival and subsequent nutrient demand could change over the course of experiments. Another reason for the decreased viability readings from alamar blue assay could be the potential adsorption of reagents in the polymer. Further inspection with live/dead staining showed that hNPCs exhibit the same round cell morphology under unstimulated and stimulated conditions for both 2D and 3D scaffolds (Suppl. Fig. 2).
Expression changes of electrically stimulated hNPCs in 2D environments
Previous studies demonstrate electrical stimulation causes preferential neurite growth, directional cell migration, and long-term differentiation changes18,21,33,38,39,68. Indeed electrical exposure is known to also play a role in induced expression of numerous transcription factors that have great implications in self-renewal and survival, synaptic remodeling, and nerve regeneration44,45,46,47,69. We hypothesized that the dimensions of stimulating platforms with identical electrical field would impact these changes in hNPCs. Under the electrical stimulation on 2D PPy films, hNPCs showed an upregulation of gene expression in heparin binding EGF like growth factor (HBEGF), heat shock protein family member 1 (HSPB1), glial cell derived neurotrophic factor (GDNF), brain derived neurotrophic factor (BDNF), and neurotrophin 3 (NTF3) and a downregulation of gene expression in enolase 2 (ENO2). The gene expression of HBEGF, HSPB1, GDNF, BDNF, and NTF3 were 1.8-, 5.7-, 12-, 33-, and 3.2-fold higher in the electrically-stimulated hNPCs compared to the unstimulated group under the identical 2D environment, respectively (Fig. 4).
These altered genes play a role in multiple important pathways. Previously, the application of a low electrical field causes upregulation and asymmetric distribution of the epidermal growth factor receptor (EGFR)70. Low levels of electrical stimulation caused neural cell precursor proliferation and expression of EGF in the brains of rats71. Specifically, HBEGF was shown to stimulate the formation of multipotent glial-derived progenitors in the uninjured Zebrafish retina linking its role in the mediation of the EGFR/MAPK signal transduction pathway72. The activation of heat shock proteins (HSP) has been hypothesized as a result of physiological stress induced by electrical stimulation73. HSPB1 is a member of the HSP family74 with the ability to interact with components of the actin cytoskeleton and protect against cytoskeletal injury during stress75. HSPB1 mutations result in the onset of motor neuropathy present with slowly progressive peroneal muscular atrophy, decreased compound muscle action potentials and sensory nerve action potentials based on electrophysiological evidence76,77,78,79. Neurotrophic factors including GDNF, BDNF, and NTF3 are important regulators in cell fate decisions, axon branching, dendrite pruning, and appropriate patterning of neuronal functions and innervation44. They are crucial for the survival, development, and function in the nervous system44,45,46,47,69. Changes in the expression levels and activities of neurotrophic factors have great implications in many neurodegenerative diseases including Parkinson disease, Alzheimer disease, and Huntington disease69.
Expression changes of electrically stimulated hNPCs in 3D environments
Similarly, the electrically stimulated hNPCs in 3D PPy tubes showed an increase in gene expression of HBEGF, HSPB1, GDNF, BDNF, and NTF3 where they were 3.8-, 5.8-, 19-, 48-, 5.7-fold higher than unstimulated cells, respectively (Fig. 4). Other studies have also demonstrated that electrical stimulation enhanced neurological recovery by modulating the secretion of neurotrophic factors22,64,80,81,82. For example, PPy coated poly(l-lactic acid-co-caprolactone) (PLCL) conduits showed upregulation of genes GDNF, BDNF, and NTF3 on dorsal root ganglia (DRG) cells under electrical stimulation of 100 mV/cm for 4h82. Direct stimulation (50–1000 mV/mm) on rat Schwann cells through PPy and chitosan composite also demonstrated an increase in BDNF level in vitro80. The hollow composite made of PPy and chitosan with electrical stimulation (3 V, 20 Hz, 1 hr) further promoted transected nerve regeneration and functional recovery in rats for 12 weeks81. Our findings show that HBEGF, HSPB1, GDNF, BDNF, and NTF3 were upregulated as a direct result of electrical stimulation regardless the shape of the stimulating platform used. Given the importance of these factors for neurotrophic effects, electrical stimulation on hNPCs through our conductive 2D and 3D scaffolds could provide beneficial therapeutics to potentially treat neurological disorders.
Interestingly, electrically-stimulated hNPCs on 2D PPy films showed that the expression of ENO2 was 0.64-fold lower than the unstimulated group, whereas no changes were observed for ENO2 in the hNPCs seeded in 3D PPy tubes under unstimulated and stimulated conditions (Fig. 4a). No changes in gene expression of VEGF-A were observed for all experimental groups (Fig. 4a). ENO2 is a hallmark of neuronal lineage related gene in neural stem cells (NSCs)83,84. VEGF-A is important for angiogenesis, cell proliferation, and plasticity22,85,86. Our results were different from the previous studies that reported highly expressed ENO2 in neural stem cells (NSCs) after 1 week regardless the use of electrical stimulation (5 mV, 0.5 mA, 25 ms intermittent stimulation) on conducting ropes83 and increased VEGF-A expression of hNPCs on polypyrrole surface (2 V, 1 kHz, 1 h)22. These discrepancies in findings could be due to differences in the experimental materials (e.g. cell source, conductive substrate, scaffold shape) and methods (e.g. stimulating parameters, culture conditions) used in the literature. Neural cell adhesion molecule (NCAM), expressed on the cell surface of various cell types like neurons and glial cells87, was found to express at similar levels in all samples (Fig. 4a), suggesting a potential enhancement in cell-cell adhesion, cell proliferation and directional growth, and synaptic plasticity potential87,88,89,90.
Expression changes of hNPCs in 2D and 3D environments
We further investigated the physical effect of 2D and 3D environment on hNPCs alone. In the long-term (~ 2 weeks), hNCPs stemness varies as function of their surrounding hydrogel stiffness and degradability91. In our study, the alginate-immobilized hNPCs that were seeded on the 2D surface showed significantly higher expression of ENO2 without electrical stimulation (Fig. 4a). Previous literature reported that ENO2 expression increases as a result of 3D culture92 and is a key glycolytic enzyme93,94. Our transport modeling indicated that different dimension of cell encapsulation (2D vs 3D) significantly impacts cell survival (Fig. 3c,d). Therefore, the physical microenvironment, in the short term, could directly affect the metabolic pathway of hNPCs, which would be important to consider when designing cell-seeded conductive scaffolds.
Expression changes of electrically stimulated hNPCs in 2D and 3D environments
More importantly, we examined whether the shape of the stimulating platform (2D vs. 3D) was more effective in promoting certain gene expressions in hNPCs during a short period of electrical stimulation. Shown previously, the long-term electrical modulation can effectively bias the differentiation of stem cells preferentially into a certain lineage (neuronal lineage)95. Our findings showed that 3D electrically-stimulated hNPCs were more effective in enhancing neurotrophic factor expression namely GDNF and BDNF (Fig. 4b), whereas 2D electrically-stimulated cells increased gene expression of ENO2 (Fig. 4a). Interestingly, the 3D field alters GDNF and BDNF to a far greater degree than the 2D field. This finding illustrates that even under the identical field strength for a brief period of time, the shape of stimulating platforms has great implications in eliciting the therapeutic potential of hNPCs. Future work can be conducted to study the long-term effects of the dimensionality of electrical stimulation on changes in hNPCs gene expression and their implications in cell proliferation and differentiation.
In this study, we demonstrated the feasibility of fabricating the conductive 2D and 3D PPy scaffolds as platforms to examine the potential dimensional effect of electrical stimulation on hNPCs. Specifically, the 2D and 3D PPy scaffolds with similar material morphologies were used to electrically stimulate hNPCs under identical field strength. Electrical stimulation applied through 2D and 3D conductive scaffolds shared upregulated expression of some common genes that play important roles in signaling self-renewal and survival, synaptic remodeling, and nerve regeneration despite differences in the physical shapes of the stimulating platform. The physical 2D and 3D culturing conditions alone also affected the NPC gene expression related to cell proliferation and metabolic pathways. Importantly, the 3D electrically-stimulated cells were more effective in promoting expression of neurotrophic factors and the 2D stimulated conditions showed increased gene expression that is important for cell-cell adhesion, neuronal differentiation, and metabolic maintenance. In addition to different stimulating platforms, the nutrient availability associated with 2D and 3D scaffolds was also likely to contribute changes in the expression of neurotrophic factors. Overall, our study demonstrated the significance in manipulating the physical culture conditions with brief electrical stimulation that resulted in profound effects reflected by the gene expression profile of hNPCs. Thus, the dimension of stimulating platforms used to apply electrical stimulation proved to be important for modulating expression changes of hNPCs depending on their metabolic states. This discovery can be important in implementing engineering strategies to manipulate the microenvironment to obtain desired therapeutic effects from stem cells.
Materials and Methods
Fabrication of conductive scaffolds
For 2D PPy conductive films, the electroplating PPy solution was doped with sodium dodecylbenzenesulfonate (NaDBS) which was then electroplated onto prepared indium tin oxide (ITO) slides at 2 mA/cm2 as previously described22,41,64 (Fig. 1a). After removal from the ITO, the electroplated-PPy was washed with DI H2O. It was sandwiched between polydimethylsiloxane (PDMS; Sylgard, Dow) slab and a chamber slide to form cell chambers on top of the 2D PPy film (Lab-Tek, Thermo Fisher) (Fig. 2,a). The PDMS slab was used to flatten out the 2D PPy films and prevent potential leakage from subsequent cell culture experiments. Wires were attached to the 2D PPy (length: 3 cm, width: 1.2 cm, thickness: 0.25 mm) outside of the chambers. The individual chamber dimension was 1.1 cm in length and 0.9 cm in width. For the 3D PPy conductive tubes, PPy was electroplated onto a 14G Nickel-Chromium Alloy wire at 2 mA/cm2 for 2 hrs (Fig. 1a). The 3D PPy tubes were then gently detached from the plating wire with the following dimensions: 1.63 mm inner diameter, 15 mm length, and 0.4 mm in wall thickness. All scaffolds were electroplated with 0.2 M NaDBS and 0.2 M PPy (Sigma Aldrich) at room temperature. To disassociate scaffolds from underlying substrates, −10 V was applied between the substrate and the reference platinum mesh for 2 min via the function generator (E3641A, Agilent) in PBS. All scaffolds were then mechanically removed from the substrates and sterilized under UV light prior to use42. The conductivity was measured to be 57.8 ± 4.2 S/m using the direct current (d.c.) four-point probe method with a Keithley 2400 Source Meter 45 at room temperature. Physical dimensions of scaffolds were measured by a caliper.
Differentiation of hiPSCs to hNPCs
The differentiation of hiPSCs to hNPCs was generated using defined conditions with modifications to previously reported protocols9,10. The NPC differentiation medium was made of 50% DMEM/F12 (Thermo Fisher Scientific), 50% Neurobasal (Thermo Fisher Scientific), 1% N2-Max (R&D Systems), 2% B27 (Thermo Fisher Scientific), 1% non-essential amino acids (NEAA) (Fisher), 1% GlutaMax (Fisher), 0.1 mM Mercaptoethanol (Sigma), and 1% penicillin/streptomycin (P/S) (Fisher) supplemented with SMAD inhibitors (i.e. 1 μM Dorsomorphin and SB431542). The NPC maintenance medium consisted of differentiation medium supplemented with bFGF (20 ng/ml) (Fisher) and EGF (20 ng/ml) (Fisher) without SMAD inhibitors.
On day 0, iPSCs (~80–90% confluency) were washed with PBS without Ca2+ and Mg2+, followed by addition of NPC differentiation medium for 7 days (4 mL per 6-well) under standard culture conditions (37 °C, 5% CO2). Medium was replaced every 24 hr. On day 7, after the induction procedure, hNPCs were washed with PBS, and Accutase (1 ml per well) was added to detach the cells. After 5 min, cells were detached from the plate surface under gentle dislodging. All cells were collected into medium made of DMEM/F12 with the RhoA/ROCK inhibitor and spun down at 1,200 rpm for 5 min at room temperature. The number of cells was determined using a hemocytometer. hNPCs were used between passages 1–3.
Electrically-stimulation of hNPC-seeded conductive scaffolds
Cell density in alginate was kept consistent for both the 2D and 3D conditions. 25,000 cells/ul hNPCs were encapsulated in 1% alginate solution. The solution was dispensed onto the individual chambers of 2D PPy films or encapsulated into the 3D PPy tubes. The thickness of hydrogel on 2D PPy films was 1.5 mm and the radial diameter in 3D PPy tubes was 1.63 mm as measured by a caliper. The hydrogel-immobilized cell solution was also deposited into 48-well plate as controls. The cross-linked solution containing NPC maintenance medium and 1%CaCl2 supplemented by the RhoA/ROCK inhibitor was added to all scaffolds under standard culture conditions. New medium was added to all conditions the next day. The NPC-seeded 2D and 3D conductive scaffolds were electrically stimulated to achieve identical electric field strength (~40 V/m) (Fig. 2). After a 1-hr stimulation, all samples were incubated for 24 hrs before analysis.
Electromagnetic finite element method (FEM) simulation
Electromagnetic field computation was conducted with physical dimensions and electrical properties described in the 2D and 3D PPy scaffolds42 (i.e. electrical resistivity of connection ~0.007 Ωcm and experimental conductivity 57.8 S/m). Electromagnetic simulations were performed on ANSYS HFSS using the finite element method (FEM) solver with the model subdivided into many small subsections in the form of tetrahedra. A solution is found such that the interrelated fields within these tetrahedra satisfy the Maxwell’s Equations across inter-element boundaries. Specifically, the electric field E is solved using the equation \(\nabla \times (\frac{1}{{\mu }_{r}}\nabla \times {\boldsymbol{E}})-{k}_{0}^{\,2}{{\epsilon }}_{r}\,{\boldsymbol{E}}=-j\omega {\mu }_{0}{\vec{{\boldsymbol{J}}}}_{source}\), where \({k}_{0}^{2}=\frac{{\omega }^{2}}{{c}^{2}}\), and \({{\epsilon }}_{r}\), μr are the relative permittivity and permeability respectively. This equation makes no approximation from Maxwell’s Equations, thus accurately capturing the electromagnetic field within the model. At each iterative calculation, the fields and associated S-matrix is generated, with the next iteration minimizing the field errors with an adaptive mesh refinement process. A solution is found when ΔSmax is smaller than the target, which is set to be 0.05% for high precision.
Nutrient molecule transport finite element method (FEM) simulation
Nutrient molecules transport simulations were performed on COMSOL Multiphysics using the finite element method (FEM) solver, with the model subdivided into many small subsections. A solution is found such that the nutrient concentrations within these subsections satisfy the steady-state reaction-diffusion equations. Specifically, concentration Ci is solved using the equation ∇ (Di∇Ci) = Ri, where Di is the diffusion coefficient for the ith nutrient, and Ri is the nutrient consumption rate by the cell culture. Concentration for oxygen and glucose at the hydrogel boundary were set to be the same as in the cell culture medium provided by the manufacture. Diffusion coefficients for oxygen and glucose are set to be 2.5 × 10−9 m2/s and 1 × 10−9 m2/s, respectively67. Cell numbers from experiments and cell consumption rate per cell values (oxygen and glucose) from previous literature67 were used for modeling 2D PPy film sheet and 3D PPy tube.
Cell viability
For the lactate dehydrogenase (LDH) (Pierce, Thermo Fisher Scientific) assay, the positive control was a sample medium collected from cells that were lysed with a buffer reagent provided by the manufacturer. The negative control was medium from cells cultured on a tissue culture plate under standard culture conditions. Supernatant from unstimulated and stimulated cells in 2D and 3D PPy scaffolds were also collected. Supernatant from all conditions was then mixed with the reaction mixture and later added with the stop solution. The LDH activity was measured by the Spectra Max M2 plate reader (Molecular Devices) at an absorbance of 490 nm and 680 nm, based on the manufacturer’s protocol. For the alamar blue assay, the positive control was cells cultured on a tissue culture plate under standard culture conditions, whereas the negative control was lysed cells. A 10% alamar blue reagent (DAL1025, Thermo Fisher Scientific) was added to each culture condition including the unstimulated and stimulated cells in the 2D and 3D PPy scaffolds. The activity from the alamar blue assay was quantified with the plate reader by monitoring the absorbance of the reagent at 570 nm while using 600 nm as a reference wavelength based on the manufacturer’s protocol. Live/Dead assay was used to stain cells based on the manufacturer protocol (L3224, Thermo Fisher Scientific).
Immunofluorescence staining
Cells were fixed with 4% formaldehyde followed by PBS washes, permeabilized with 0.1% Triton X-100 for 10 min, and incubated in blocking solution (PBS, 1% normal goat serum) for 30 min. Samples were incubated with primary antibodies (PAX6: 42-6600, SOX1: AF3369, SOX2: AF2018, Nestin: ABD69MI; Fisher Scientific) at a dilution of 1:100-1:300 for 1 hr and washed twice for 5 min with PBS to remove residues. Another incubation with secondary antibodies (Alexa Fluor 555: A27039, Alexa Fluor 488: A-11008; Thermo Fisher Scientific) at a dilution of 1:1000 for 1 hr was used, followed by PBS washes for 5 min. DAPI (1:1000, D9542, Sigma-Aldrich) was added for nuclear staining. Images were obtained using a Keyence BZ-X710 microscope equipped with full BZ acquisition and analysis software.
Quantitative gene expression
The quantitative real-time polymerase chain reaction (qRT-PCR) was performed using the RNeasy Mini Kit (Qiagen) based on the manufacturer’s protocol. The iScript cDNA Synthesis Kit (Bio-Rad) was used for cDNA synthesis. The QuantStudio 6 Flex Real-Time PCR System (Thermo Fisher Scientific) was used to perform quantitative real-time PCR. Taq polymerase and Taqman primers (Thermo Fisher Scientific) glyceraldehyde-3-phosphate dehydrogenase (GAPDH Hs02786624_g1), neural cell adhesion molecule 1 (NCAM1 Hs00941830_m1), heparin binding EGF like growth factor (HBEGF Hs00181813_m1), heat shock protein family member 1 (HSPB1 Hs00356629_g1), enolase 2 (ENO2 Hs00157360_m1), vascular endothelial growth factor A (VEGF-A Hs00900055_m1), glial cell derived neurotrophic factor (GDNF Hs01931883_s1), brain derived neurotrophic factor (BDNF Hs02718934_s1), and neurotrophin 3 (NTF3 Hs00267375_s1) for formed the PCR reaction mixtures. The Delta-Delta CT method was utilized for analysis with the GAPDH housekeeping gene and alginate-immobilized hNPCs on tissue culture wells as references.
Statistical analysis
Sample pairs were analyzed using the Student’s t-test. Multiple samples were evaluated with one-way or two-way analysis of variance (ANOVA) followed by Tukey and multiple comparisons using GraphPad Prism software (San Diego, CA). A p value of <0.05 was accepted as statistically significant for all analyses.
Data availability
The authors declare that all the data in this manuscript are available.
References
Kabu, S., Gao, Y., Kwon, B. K. & Labhasetwar, V. Drug delivery, cell-based therapies, and tissue engineering approaches for spinal cord injury. J Control Release 219, 141–154 (2015).
Menzies, F. M., Fleming, A. & Rubinsztein, D. C. Compromised autophagy and neurodegenerative diseases. Nature Reviews Neuroscience 16, 345–357 (2015).
Gorman, A. M. Neuronal cell death in neurodegenerative diseases: recurring themes around protein handling. J. Cell. Mol. Med. 12, 2263–2280 (2008).
Haston, K. M. & Finkbeiner, S. Clinical Trials in a Dish: The Potential of Pluripotent Stem Cells to Develop Therapies for Neurodegenerative Diseases. Annu. Rev. Pharmacol. Toxicol. 56, 489–510 (2016).
Trounson, A. & McDonald, C. Stem Cell Therapies in Clinical Trials: Progress and Challenges. Cell Stem Cell 17, 11–22 (2015).
Takahashi, K. & Yamanaka, S. Induction of pluripotent stem cells from mouse embryonic and adult fibroblast cultures by defined factors. Cell 126, 663–676 (2006).
Volarevic, V. et al. Ethical and Safety Issues of Stem Cell-Based Therapy. International Journal of Medical Sciences 15, 36–45 (2018).
Srikanth, P. & Young-Pearse, T. L. Stem cells on the brain: modeling neurodevelopmental and neurodegenerative diseases using human induced pluripotent stem cells. J. Neurogenet. 28, 5–29 (2014).
Shi, Y., Kirwan, P., Smith, J., Robinson, H. P. C. & Livesey, F. J. Human cerebral cortex development from pluripotent stem cells to functional excitatory synapses. Nature Neuroscience 15, 477–486 (2012).
Paşca, A. M. et al. Functional cortical neurons and astrocytes from human pluripotent stem cells in 3D culture. Nat. Methods 12, 671–678 (2015).
Daadi, M. M. et al. Human neural stem cell grafts modify microglial response and enhance axonal sprouting in neonatal hypoxic-ischemic brain injury. Stroke 41, 516–523 (2010).
Horie, N. et al. Transplanted stem cell-secreted VEGF effects post-stroke recovery, inflammation, and vascular repair. Stem Cells 29 (2011).
Chen, J. et al. Therapeutic benefit of intravenous administration of bone marrow stromal cells after cerebral ischemia in rats. Stroke 32, 1005–1011 (2001).
Andres, R. H. et al. Human neural stem cells enhance structural plasticity and axonal transport in the ischaemic brain. Brain 134, 1777–1789 (2011).
Lepore, A. C. et al. Long-term fate of neural precursor cells following transplantation into developing and adult CNS. Neuroscience 139, 513–530 (2006).
Webber, D. J., Bradbury, E. J., McMahon, S. B. & Minger, S. L. Transplanted neural progenitor cells survive and differentiate but achieve limited functional recovery in the lesioned adult rat spinal cord. Regen Med 2, 929–945 (2007).
Abati, E., Bresolin, N., Comi, G. P. & Corti, S. Preconditioning and Cellular Engineering to Increase the Survival of Transplanted Neural Stem Cells for Motor Neuron Disease Therapy. Mol. Neurobiol, https://doi.org/10.1007/s12035-018-1305-4 (2018).
Chang, K.-A. et al. Biphasic Electrical Currents Stimulation Promotes both Proliferation and Differentiation of Fetal Neural Stem Cells. Plos one 6, e18738 (2011).
Patel, N. & Poo, M. M. Orientation of neurite growth by extracellular electric fields. J. Neurosci. 2, 483–496 (1982).
Prabhakaran, M. P., Ghasemi-Mobarakeh, L., Jin, G. & Ramakrishna, S. Electrospun conducting polymer nanofibers and electrical stimulation of nerve stem cells. J. Biosci. Bioeng. 112, 501–507 (2011).
Stewart, E. et al. Electrical stimulation using conductive polymer polypyrrole promotes differentiation of human neural stem cells: a biocompatible platform for translational neural tissue engineering. Tissue Eng Part C Methods 21, 385–393 (2015).
George, P. M. et al. Electrical preconditioning of stem cells with a conductive polymer scaffold enhances stroke recovery. Biomaterials 142, 31–40 (2017).
Machado, A. F. P., Santana, E. F., Tacani, P. M. & Liebano, R. E. The effects of transcutaneous electrical nerve stimulation on tissue repair: A literature review. Can J Plast Surg 20, 237–240 (2012).
Paternostro-Sluga, T., Fialka, C., Alacamliogliu, Y., Saradeth, T. & Fialka-Moser, V. Neuromuscular electrical stimulation after anterior cruciate ligament surgery. Clin. Orthop. Relat. Res. 166–175 (1999).
Kim, K.-M., Croy, T., Hertel, J. & Saliba, S. Effects of Neuromuscular Electrical Stimulation After Anterior Cruciate Ligament Reconstruction on Quadriceps Strength, Function, and Patient-Oriented Outcomes: A Systematic Review. J Orthop Sports Phys Ther 40, 383–391 (2010).
Willand, M. P. Electrical Stimulation Enhances Reinnervation After Nerve Injury. Eur J Transl Myol 25, 243–248 (2015).
Boda, S. K., Thrivikraman, G. & Basu, B. Magnetic field assisted stem cell differentiation – role of substrate magnetization in osteogenesis. J. Mater. Chem. B 3, 3150–3168 (2015).
Hess, R. et al. Synergistic effect of defined artificial extracellular matrices and pulsed electric fields on osteogenic differentiation of human MSCs. Biomaterials 33, 8975–8985 (2012).
Esfandiari, E. et al. The effect of high frequency electric field on enhancement of chondrogenesis in human adipose-derived stem cells. Iran J Basic Med Sci 17, 571–576 (2014).
Creecy, C. M. et al. Mesenchymal stem cell osteodifferentiation in response to alternating electric current. Tissue Eng Part A 19, 467–474 (2013).
Li, L. et al. Direct-current electrical field guides neuronal stem/progenitor cell migration. Stem Cells 26, 2193–2200 (2008).
Cao, L. et al. Endogenous electric currents might guide rostral migration of neuroblasts. EMBO Rep. 14, 184–190 (2013).
Pires, F., Ferreira, Q., Rodrigues, C. A. V., Morgado, J. & Ferreira, F. C. Neural stem cell differentiation by electrical stimulation using a cross-linked PEDOT substrate: Expanding the use of biocompatible conjugated conductive polymers for neural tissue engineering. Biochim. Biophys. Acta 1850, 1158–1168 (2015).
Tsai, M.-T., Li, W.-J., Tuan, R. S. & Chang, W. H. Modulation of osteogenesis in human mesenchymal stem cells by specific pulsed electromagnetic field stimulation. J. Orthop. Res. 27, 1169–1174 (2009).
Hronik-Tupaj, M., Rice, W. L., Cronin-Golomb, M., Kaplan, D. L. & Georgakoudi, I. Osteoblastic differentiation and stress response of human mesenchymal stem cells exposed to alternating current electric fields. Biomed Eng Online 10, 9 (2011).
Kotnik, Tadej & Damijan, Miklavcic. Theoretical evaluation of voltage inducement on internal membranes of biological cells exposed to electric fields. Biophysical Journal 90(2), 480–491, https://doi.org/10.1529/biophysj.105.070771 (2006).
Sato, M. J. et al. Switching direction in electric-signal-induced cell migration by cyclic guanosine monophosphate and phosphatidylinositol signaling. PNAS 106, 6667–6672 (2009).
Heo, C. et al. The control of neural cell-to-cell interactions through non-contact electrical field stimulation using graphene electrodes. Biomaterials 32, 19–27 (2011).
Zhang, J. et al. Electrically guiding migration of human induced pluripotent stem cells. Stem Cell Rev 7, 987–996 (2011).
Kaur, G., Adhikari, R., Cass, P., Bown, M. & Gunatillake, P. Electrically conductive polymers and composites for biomedical applications. RSC Advances 5, 37553–37567 (2015).
George, P. M. et al. Fabrication and biocompatibility of polypyrrole implants suitable for neural prosthetics. Biomaterials 26, 3511–3519 (2005).
George, P. M. et al. Three-dimensional conductive constructs for nerve regeneration. J Biomed Mater Res A 91, 519–527 (2009).
LaVan, D. A., George, P. M. & Langer, R. Simple, three-dimensional microfabrication of electrodeposited structures. Angew. Chem. Int. Ed. Engl. 42, 1262–1265 (2003).
Huang, E. J. & Reichardt, L. F. Neurotrophins: Roles in Neuronal Development and Function. Annu Rev Neurosci 24, 677–736 (2001).
Chalazonitis, A. et al. Neurotrophin-3 is required for the survival-differentiation of subsets of developing enteric neurons. J. Neurosci. 21, 5620–5636 (2001).
Henderson, C. E. Role of neurotrophic factors in neuronal development. Curr. Opin. Neurobiol. 6, 64–70 (1996).
Cohen-Cory, S. & Fraser, S. E. Effects of brain-derived neurotrophic factor on optic axon branching and remodelling in vivo. Nature 378, 192–196 (1995).
Sebert, M. E. & Shooter, E. M. Expression of mRNA for neurotrophic factors and their receptors in the rat dorsal root ganglion and sciatic nerve following nerve injury. J. Neurosci. Res. 36, 357–367 (1993).
Onorati, M. et al. Molecular and functional definition of the developing human striatum. Nat. Neurosci. 17, 1804–1815 (2014).
Osumi, N. The role of Pax6 in brain patterning. Tohoku J. Exp. Med. 193, 163–174 (2001).
Suter, D. M., Tirefort, D., Julien, S. & Krause, K.-H. A Sox1 to Pax6 switch drives neuroectoderm to radial glia progression during differentiation of mouse embryonic stem cells. Stem Cells 27, 49–58 (2009).
Shi, Y., Kirwan, P. & Livesey, F. J. Directed differentiation of human pluripotent stem cells to cerebral cortex neurons and neural networks. Nat Protoc 7, 1836–1846 (2012).
Boissart, C. et al. Differentiation from human pluripotent stem cells of cortical neurons of the superficial layers amenable to psychiatric disease modeling and high-throughput drug screening. Translational Psychiatry 3, e294 (2013).
Li, H. et al. Differentiation of neurons from neural precursors generated in floating spheres from embryonic stem cells. BMC Neuroscience 10, 122 (2009).
Pevny, L. H., Sockanathan, S., Placzek, M. & Lovell-Badge, R. A role for SOX1 in neural determination. Development 125, 1967–1978 (1998).
Venere, M. et al. Sox1 marks an activated neural stem/progenitor cell in the hippocampus. Development 139, 3938–3949 (2012).
Graham, V., Khudyakov, J., Ellis, P. & Pevny, L. SOX2 functions to maintain neural progenitor identity. Neuron 39, 749–765 (2003).
Bylund, M., Andersson, E., Novitch, B. G. & Muhr, J. Vertebrate neurogenesis is counteracted by Sox1-3 activity. Nat. Neurosci. 6, 1162–1168 (2003).
Morshead, C. M. et al. Neural stem cells in the adult mammalian forebrain: a relatively quiescent subpopulation of subependymal cells. Neuron 13, 1071–1082 (1994).
Reynolds, B. A. & Weiss, S. Generation of neurons and astrocytes from isolated cells of the adult mammalian central nervous system. Science 255, 1707–1710 (1992).
Frederiksen, K. & McKay, R. D. Proliferation and differentiation of rat neuroepithelial precursor cells in vivo. J. Neurosci. 8, 1144–1151 (1988).
Dahlstrand, J., Lardelli, M. & Lendahl, U. Nestin mRNA expression correlates with the central nervous system progenitor cell state in many, but not all, regions of developing central nervous system. Brain Res. Dev. Brain Res. 84, 109–129 (1995).
Song, S. & George, P. M. Conductive polymer scaffolds to improve neural recovery. Neural Regen Res 12, 1976–1978 (2017).
Oh, B., Levinson, A., Lam, V., Song, S. & George, P. Electrically Conductive Scaffold to Modulate and Deliver Stem Cells. J Vis Exp, https://doi.org/10.3791/57367 (2018).
Mooney, E. et al. The electrical stimulation of carbon nanotubes to provide a cardiomimetic cue to MSCs. Biomaterials 33, 6132–6139 (2012).
Sun, S., Titushkin, I. & Cho, M. Regulation of mesenchymal stem cell adhesion and orientation in 3D collagen scaffold by electrical stimulus. Bioelectrochemistry 69, 133–141 (2006).
McMurtrey, R. J. Analytic Models of Oxygen and Nutrient Diffusion, Metabolism Dynamics, and Architecture Optimization in Three-Dimensional Tissue Constructs with Applications and Insights in Cerebral Organoids. Tissue Eng Part C Methods 22, 221–249 (2016).
Ribeiro, A. S., Powell, E. M. & Leach, J. B. Neural Stem Cell Differentiation in 2D and 3D Microenvironments. in 26th Southern Biomedical Engineering Conference SBEC 2010, April 30 - May 2, 2010, College Park, Maryland, USA (eds. Herold, K. E., Vossoughi, J. & Bentley, W. E.) 422–425 (Springer Berlin Heidelberg, 2010).
Zuccato, C. & Cattaneo, E. Brain-derived neurotrophic factor in neurodegenerative diseases. Nat Rev Neurol 5, 311–322 (2009).
Zhao, M., Dick, A., Forrester, J. V. & McCaig, C. D. Electric field-directed cell motility involves up-regulated expression and asymmetric redistribution of the epidermal growth factor receptors and is enhanced by fibronectin and laminin. Mol. Biol. Cell 10, 1259–1276 (1999).
Xiang, Y. et al. Functional electrical stimulation-facilitated proliferation and regeneration of neural precursor cells in the brains of rats with cerebral infarction. Neural Regen Res 9, 243–251 (2014).
Wan, J., Ramachandran, R. & Goldman, D. HB-EGF is necessary and sufficient for Müller glia dedifferentiation and retina regeneration. Dev. Cell 22, 334–347 (2012).
Delle Monache, S. et al. Inhibition of angiogenesis mediated by extremely low-frequency magnetic fields (ELF-MFs). PLoS ONE 8, e79309 (2013).
Kappé, G. et al. The human genome encodes 10 alpha-crystallin-related small heat shock proteins: HspB1-10. Cell Stress Chaperones 8, 53–61 (2003).
Landry, J. & Huot, J. Modulation of actin dynamics during stress and physiological stimulation by a signaling pathway involving p38 MAP kinase and heat-shock protein 27. Biochem. Cell Biol. 73, 703–707 (1995).
Srivastava, A. K. et al. Mutant HSPB1 overexpression in neurons is sufficient to cause age-related motor neuronopathy in mice. Neurobiol Dis 47, 163–173 (2012).
Kijima, K. et al. Small heat shock protein 27 mutation in a Japanese patient with distal hereditary motor neuropathy. J. Hum. Genet. 50, 473–476 (2005).
Dierick, I. et al. Relative contribution of mutations in genes for autosomal dominant distal hereditary motor neuropathies: a genotype-phenotype correlation study. Brain 131, 1217–1227 (2008).
Benedetti, S. et al. Analyzing histopathological features of rare charcot-marie-tooth neuropathies to unravel their pathogenesis. Arch. Neurol. 67, 1498–1505 (2010).
Huang, J. et al. Electrical regulation of Schwann cells using conductive polypyrrole/chitosan polymers. J Biomed Mater Res A 93, 164–174 (2010).
Huang, J. et al. Electrical stimulation to conductive scaffold promotes axonal regeneration and remyelination in a rat model of large nerve defect. PLoS ONE 7, e39526 (2012).
Song, J. et al. Polymerizing Pyrrole Coated Poly (l-lactic acid-co-ε-caprolactone) (PLCL) Conductive Nanofibrous Conduit Combined with Electric Stimulation for Long-Range Peripheral Nerve Regeneration. Front Mol Neurosci 9, 117 (2016).
Huang, Y.-J., Wu, H.-C., Tai, N.-H. & Wang, T.-W. Carbon nanotube rope with electrical stimulation promotes the differentiation and maturity of neural stem cells. Small 8, 2869–2877 (2012).
Oikari, L. E., Okolicsanyi, R. K., Griffiths, L. R. & Haupt, L. M. Data defining markers of human neural stem cell lineage potential. Data Brief 7, 206–215 (2016).
Zhao, M., Bai, H., Wang, E., Forrester, J. V. & McCaig, C. D. Electrical stimulation directly induces pre-angiogenic responses in vascular endothelial cells by signaling through VEGF receptors. J. Cell. Sci. 117, 397–405 (2004).
Amaral, S. L., Linderman, J. R., Morse, M. M. & Greene, A. S. Angiogenesis induced by electrical stimulation is mediated by angiotensin II and VEGF. Microcirculation 8, 57–67 (2001).
Schmid, R. S. et al. NCAM stimulates the Ras-MAPK pathway and CREB phosphorylation in neuronal cells. J. Neurobiol. 38, 542–558 (1999).
Weinhold, B. et al. Genetic ablation of polysialic acid causes severe neurodevelopmental defects rescued by deletion of the neural cell adhesion molecule. J. Biol. Chem. 280, 42971–42977 (2005).
Eckhardt, M. et al. Mice deficient in the polysialyltransferase ST8SiaIV/PST-1 allow discrimination of the roles of neural cell adhesion molecule protein and polysialic acid in neural development and synaptic plasticity. J. Neurosci. 20, 5234–5244 (2000).
Angata, K., Chan, D., Thibault, J. & Fukuda, M. Molecular dissection of the ST8Sia IV polysialyltransferase. Distinct domains are required for neural cell adhesion molecule recognition and polysialylation. J. Biol. Chem. 279, 25883–25890 (2004).
Madl, C. M. et al. Maintenance of Neural Progenitor Cell Stemness in 3D Hydrogels Requires Matrix Remodeling. Nat Mater 16, 1233–1242 (2017).
Ghosh, S. et al. Three-dimensional culture of melanoma cells profoundly affects gene expression profile: a high density oligonucleotide array study. J. Cell. Physiol. 204, 522–531 (2005).
Liu, C.-C. et al. ENO2 Promotes Cell Proliferation, Glycolysis, and Glucocorticoid-Resistance in Acute Lymphoblastic Leukemia. Cell. Physiol. Biochem. 46, 1525–1535 (2018).
Sanzey, M. et al. Comprehensive analysis of glycolytic enzymes as therapeutic targets in the treatment of glioblastoma. PLoS ONE 10, e0123544 (2015).
Yamada, M. et al. Electrical stimulation modulates fate determination of differentiating embryonic stem cells. Stem Cells 25, 562–570 (2007).
Acknowledgements
This research was supported in part by the Stanford University Dean’s Postdoctoral Fellowship and the Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD) of the National Institutes of Health (NIH) under Award Number F32HD098808 (S.S.), the Alliance for Regenerative Rehabilitation Research and Training (P2C HD08684) and NIH K08NS089976 (P.M.G.). We would like to thank colleague Neha Srivathsa for performing some of the cell culture and Yuxin Liu for measuring the polymer conductivity.
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S.S. and P.M.G. designed the experiments. S.S. performed the experiments. D.A. helped with cell culture and PCR experiments. C.C. and A.P. modeled the electrical and nutrient simulations. K.M. imaged cell viability of the 2D platform. B.O. took SEM images of the materials. S.S. and P.M.G. wrote the manuscript.
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Song, S., Amores, D., Chen, C. et al. Controlling properties of human neural progenitor cells using 2D and 3D conductive polymer scaffolds. Sci Rep 9, 19565 (2019). https://doi.org/10.1038/s41598-019-56021-w
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DOI: https://doi.org/10.1038/s41598-019-56021-w
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