Your search keyword '"Neurite guidance"' showing total 38 results

1. Fabrication of Ferritin Nanoparticle Patterns for Controlling Neuron Adhesion and Neurite Outgrowth

Author

Tran, Anh Quang, Nguyen, Thanh-Nghia, Khanh, Phung Cong Phi, Tan, Tran Duc, Offenhaeusser, Andreas, Beck, Tobias, Mayer, Dirk, Magjarević, Ratko, Series Editor, Ładyżyński, Piotr, Associate Editor, Ibrahim, Fatimah, Associate Editor, Lackovic, Igor, Associate Editor, Rock, Emilio Sacristan, Associate Editor, Vo, Van Toi, editor, Nguyen, Thi-Hiep, editor, Vong, Binh Long, editor, Le, Ngoc Bich, editor, and Nguyen, Thanh Qua, editor

Published

2024

2. Sensitivity of CNN image analysis to multifaceted measurements of neurite growth

Author

Joseph T. Vecchi, Sean Mullan, Josue A. Lopez, Madeline Rhomberg, Annamarie Yamamoto, Annabelle Hallam, Amy Lee, Milan Sonka, and Marlan R. Hansen

Subjects

Neurite growth, Neuron morphology, Machine learning, Convolutional neural network, Explainable AI, Neurite guidance, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Quantitative analysis of neurite growth and morphology is essential for understanding the determinants of neural development and regeneration, however, it is complicated by the labor-intensive process of measuring diverse parameters of neurite outgrowth. Consequently, automated approaches have been developed to study neurite morphology in a high-throughput and comprehensive manner. These approaches include computer-automated algorithms known as 'convolutional neural networks' (CNNs)—powerful models capable of learning complex tasks without the biases of hand-crafted models. Nevertheless, their complexity often relegates them to functioning as 'black boxes.' Therefore, research in the field of explainable AI is imperative to comprehend the relationship between CNN image analysis output and predefined morphological parameters of neurite growth in order to assess the applicability of these machine learning approaches. In this study, drawing inspiration from the field of automated feature selection, we investigate the correlation between quantified metrics of neurite morphology and the image analysis results from NeuriteNet—a CNN developed to analyze neurite growth. NeuriteNet accurately distinguishes images of neurite growth based on different treatment groups within two separate experimental systems. These systems differentiate between neurons cultured on different substrate conditions and neurons subjected to drug treatment inhibiting neurite outgrowth. By examining the model's function and patterns of activation underlying its classification decisions, we discover that NeuriteNet focuses on aspects of neuron morphology that represent quantifiable metrics distinguishing these groups. Additionally, it incorporates factors that are not encompassed by neuron morphology tracing analyses. NeuriteNet presents a novel tool ideally suited for screening morphological differences in heterogeneous neuron groups while also providing impetus for targeted follow-up studies.

Published

2023

3. Sensitivity of CNN image analysis to multifaceted measurements of neurite growth.

Author

Vecchi, Joseph T., Mullan, Sean, Lopez, Josue A., Rhomberg, Madeline, Yamamoto, Annamarie, Hallam, Annabelle, Lee, Amy, Sonka, Milan, and Hansen, Marlan R.

Subjects

IMAGE analysis, MACHINE learning, CONVOLUTIONAL neural networks, FEATURE selection, NEURAL development, DIGITAL image correlation, TRACE analysis

Abstract

Quantitative analysis of neurite growth and morphology is essential for understanding the determinants of neural development and regeneration, however, it is complicated by the labor-intensive process of measuring diverse parameters of neurite outgrowth. Consequently, automated approaches have been developed to study neurite morphology in a high-throughput and comprehensive manner. These approaches include computer-automated algorithms known as 'convolutional neural networks' (CNNs)—powerful models capable of learning complex tasks without the biases of hand-crafted models. Nevertheless, their complexity often relegates them to functioning as 'black boxes.' Therefore, research in the field of explainable AI is imperative to comprehend the relationship between CNN image analysis output and predefined morphological parameters of neurite growth in order to assess the applicability of these machine learning approaches. In this study, drawing inspiration from the field of automated feature selection, we investigate the correlation between quantified metrics of neurite morphology and the image analysis results from NeuriteNet—a CNN developed to analyze neurite growth. NeuriteNet accurately distinguishes images of neurite growth based on different treatment groups within two separate experimental systems. These systems differentiate between neurons cultured on different substrate conditions and neurons subjected to drug treatment inhibiting neurite outgrowth. By examining the model's function and patterns of activation underlying its classification decisions, we discover that NeuriteNet focuses on aspects of neuron morphology that represent quantifiable metrics distinguishing these groups. Additionally, it incorporates factors that are not encompassed by neuron morphology tracing analyses. NeuriteNet presents a novel tool ideally suited for screening morphological differences in heterogeneous neuron groups while also providing impetus for targeted follow-up studies. [ABSTRACT FROM AUTHOR]

Published

2023

4. Brain Slice Derived Nerve Fibers Grow along Microcontact Prints and are Stimulated by Beta-Amyloid(42)

Author

Katharina Steiner and Christian Humpel

Subjects

microcontact printing, organotypic brain slices, neurite guidance, collagen, polyornithine, beta-amyloid, tau, alzheimer's disease, Biochemistry, QD415-436, Biology (General), QH301-705.5

Abstract

Background: Alzheimer’s disease is characterized by extracellular beta-amyloid plaques, intraneuronal tau neurofibrillary tangles and excessive neurodegeneration. The mechanisms of neuron degeneration and the potential of these neurons to form new nerve fibers for compensation remain elusive. The present study aimed to evaluate the impact of beta-amyloid and tau on new formations of nerve fibers from mouse organotypic brain slices connected to collagen-based microcontact prints. Methods: Organotypic brain slices of postnatal day 8–10 wild-type mice were connected to established collagen-based microcontact prints loaded with polyornithine to enhance nerve fiber outgrowth. Human beta-amyloid(42) or P301S mutated aggregated tau was co-loaded to the prints. Nerve fibers were immunohistochemically stained with neurofilament antibodies. The physiological activity of outgrown neurites was tested with neurotracer MiniRuby, voltage-sensitive dye FluoVolt, and calcium-sensitive dye Rhod-4. Results: Immunohistochemical staining revealed newly formed nerve fibers extending along the prints derived from the brain slices. While collagen-only microcontact prints stimulated nerve fiber growth, those loaded with polyornithine significantly enhanced nerve fiber outgrowth. Beta-amyloid(42) significantly increased the neurofilament-positive nerve fibers, while tau had only a weak effect. MiniRuby crystals, retrogradely transported along these newly formed nerve fibers, reached the hippocampus, while FluoVolt and Rhod-4 monitored electrical activity in newly formed nerve fibers. Conclusions: Our data provide evidence that intact nerve fibers can form along collagen-based microcontact prints from mouse brain slices. The Alzheimer’s peptide beta-amyloid(42) stimulates this growth, hinting at a neuroprotective function when physiologically active. This “brain-on-chip” model may offer a platform for screening bioactive factors or testing drug effects on nerve fiber growth.

Published

2024

5. 3D Printed Cell Culture Chamber for Testing the Effect of Pump-Based Chronic Drug Delivery on Inner Ear Tissue.

Author

Schwieger, Jana, Frisch, Anna Sophie, Rau, Thomas S., Lenarz, Thomas, Hügl, Silke, and Scheper, Verena

Subjects

*INNER ear, *HAIR cells, *CELL culture, *SPIRAL ganglion, *COCHLEAR implants, *CELL physiology

Abstract

Cochlear hair cell damage and spiral ganglion neuron (SGN) degeneration are the main causes of sensory neural hearing loss. Cochlear implants (CIs) can replace the function of the hair cells and stimulate the SGNs electrically. The condition of the SGNs and their spatial distance to the CI are key factors for CI-functionality. For a better performance, a high number of neurons and a closer contact to the electrode are intended. Neurotrophic factors are able to enhance SGN survival and neurite outgrowth, and thereby might optimize the electrode-nerve interaction. This would require chronic factor treatment, which is not yet established for the inner ear. Investigations on chronic drug delivery to SGNs could benefit from an appropriate in vitro model. Thus, an inner ear inspired Neurite Outgrowth Chamber (NOC), which allows the incorporation of a mini-osmotic pump for long-term drug delivery, was designed and three-dimensionally printed. The NOC's function was validated using spiral ganglion explants treated with ciliary neurotrophic factor, neurotrophin-3, or control fluid released via pumps over two weeks. The NOC proved to be suitable for explant cultivation and observation of pump-based drug delivery over the examined period, with neurotrophin-3 significantly increasing neurite outgrowth compared to the other groups. [ABSTRACT FROM AUTHOR]

Published

2022

6. 3D‐Printed Soft Lithography for Complex Compartmentalized Microfluidic Neural Devices

Author

Janko Kajtez, Sebastian Buchmann, Shashank Vasudevan, Marcella Birtele, Stefano Rocchetti, Christian Jonathan Pless, Arto Heiskanen, Roger A. Barker, Alberto Martínez‐Serrano, Malin Parmar, Johan Ulrik Lind, and Jenny Emnéus

Subjects

3D printing, compartmentalized devices, fast prototyping, human neural stem cells, neurite guidance, nigrostriatal pathway, Science

Abstract

Abstract Compartmentalized microfluidic platforms are an invaluable tool in neuroscience research. However, harnessing the full potential of this technology remains hindered by the lack of a simple fabrication approach for the creation of intricate device architectures with high‐aspect ratio features. Here, a hybrid additive manufacturing approach is presented for the fabrication of open‐well compartmentalized neural devices that provides larger freedom of device design, removes the need for manual postprocessing, and allows an increase in the biocompatibility of the system. Suitability of the method for multimaterial integration allows to tailor the device architecture for the long‐term maintenance of healthy human stem‐cell derived neurons and astrocytes, spanning at least 40 days. Leveraging fast‐prototyping capabilities at both micro and macroscale, a proof‐of‐principle human in vitro model of the nigrostriatal pathway is created. By presenting a route for novel materials and unique architectures in microfluidic systems, the method provides new possibilities in biological research beyond neuroscience applications.

Published

2020

7. A locust embryo as predictive developmental neurotoxicity testing system for pioneer axon pathway formation.

Author

Bode, Karsten, Bohn, Maja, Reitmeier, Jennifer, Betker, Philine, Stern, Michael, and Bicker, Gerd

Subjects

*MIGRATORY locust, *TEST systems, *LOCUSTS, *CELLULAR recognition, *EMBRYOS, *NEUROTOXICOLOGY, *AXONS

Abstract

Exposure to environmental chemicals during in utero and early postnatal development can cause a wide range of neurological defects. Since current guidelines for identifying developmental neurotoxic chemicals depend on the use of large numbers of rodents in animal experiments, it has been proposed to design rapid and cost-efficient in vitro screening test batteries that are mainly based on mixed neuronal/glial cultures. However, cell culture tests do not assay correct wiring of neuronal circuits. The establishment of precise anatomical connectivity is a key event in the development of a functional brain. Here, we expose intact embryos of the locust (Locusta migratoria) in serum-free culture to test chemicals and visualize correct navigation of identified pioneer axons by fluorescence microscopy. We define separate toxicological endpoints for axonal elongation and navigation along a stereotyped pathway. To distinguish developmental neurotoxicity (DNT) from general toxicity, we quantify defects in axonal elongation and navigation in concentration–response curves and compare it to the biochemically determined viability of the embryo. The investigation of a panel of recognized DNT-positive and -negative test compounds supports a rather high predictability of this invertebrate embryo assay. Similar to the semaphorin-mediated guidance of neurites in mammalian cortex, correct axonal navigation of the locust pioneer axons relies on steering cues from members of this family of cell recognition molecules. Due to the evolutionary conserved mechanisms of neurite guidance, we suggest that our pioneer axon paradigm might provide mechanistically relevant information on the DNT potential of chemical agents on the processes of axon elongation, navigation, and fasciculation. [ABSTRACT FROM AUTHOR]

Published

2020

8. 3D‐Printed Soft Lithography for Complex Compartmentalized Microfluidic Neural Devices.

Author

Kajtez, Janko, Buchmann, Sebastian, Vasudevan, Shashank, Birtele, Marcella, Rocchetti, Stefano, Pless, Christian Jonathan, Heiskanen, Arto, Barker, Roger A., Martínez‐Serrano, Alberto, Parmar, Malin, Lind, Johan Ulrik, and Emnéus, Jenny

Subjects

SOFT lithography, MICROFLUIDIC devices, CONSTRUCTION materials, HUMAN stem cells

Abstract

Compartmentalized microfluidic platforms are an invaluable tool in neuroscience research. However, harnessing the full potential of this technology remains hindered by the lack of a simple fabrication approach for the creation of intricate device architectures with high‐aspect ratio features. Here, a hybrid additive manufacturing approach is presented for the fabrication of open‐well compartmentalized neural devices that provides larger freedom of device design, removes the need for manual postprocessing, and allows an increase in the biocompatibility of the system. Suitability of the method for multimaterial integration allows to tailor the device architecture for the long‐term maintenance of healthy human stem‐cell derived neurons and astrocytes, spanning at least 40 days. Leveraging fast‐prototyping capabilities at both micro and macroscale, a proof‐of‐principle human in vitro model of the nigrostriatal pathway is created. By presenting a route for novel materials and unique architectures in microfluidic systems, the method provides new possibilities in biological research beyond neuroscience applications. [ABSTRACT FROM AUTHOR]

Published

2020

9. The geometry of photopolymerized topography influences neurite pathfinding by directing growth cone morphology and migration.

Author

Vecchi JT, Rhomberg M, Guymon CA, and Hansen MR

Subjects

Growth Cones, Cells, Cultured, Neurons, Spiral Ganglion, Neurites, Cochlear Implants

Abstract

Objective . Cochlear implants provide auditory perception to those with severe to profound sensorineural hearing loss: however, the quality of sound perceived by users does not approximate natural hearing. This limitation is due in part to the large physical gap between the stimulating electrodes and their target neurons. Therefore, directing the controlled outgrowth of processes from spiral ganglion neurons (SGNs) into close proximity to the electrode array could provide significantly increased hearing function. Approach. For this objective to be properly designed and implemented, the ability and limits of SGN neurites to be guided must first be determined. In this work, we engineer precise topographical microfeatures with angle turn challenges of various geometries to study SGN pathfinding and use live imaging to better understand how neurite growth is guided by these cues. Main Results. We find that the geometry of the angled microfeatures determines the ability of neurites to navigate the angled microfeature turns. SGN neurite pathfinding fidelity is increased by 20%-70% through minor increases in microfeature amplitude (depth) and by 25% if the angle of the patterned turn is made obtuse. Further, we see that dorsal root ganglion neuron growth cones change their morphology and migration to become more elongated within microfeatures. Our observations also indicate complexities in studying neurite turning. First, as the growth cone pathfinds in response to the various cues, the associated neurite often reorients across the angle topographical microfeatures. Additionally, neurite branching is observed in response to topographical guidance cues, most frequently when turning decisions are most uncertain. Significance. Overall, the multi-angle channel micropatterned substrate is a versatile and efficient system to assess neurite turning and pathfinding in response to topographical cues. These findings represent fundamental principles of neurite pathfinding that will be essential to consider for the design of 3D systems aiming to guide neurite growth in vivo ., (Creative Commons Attribution license.)

Published

2024

10. Microenvironments Designed to Support Growth and Function of Neuronal Cells

Author

Aleeza Farrukh, Shifang Zhao, and Aránzazu del Campo

Subjects

biomaterials, neuroregeneration, axon growth, neurite guidance, nerve repair, Technology

Abstract

Strategies for neural tissue repair heavily depend on our ability to temporally reconstruct the natural cellular microenvironment of neural cells. Biomaterials play a fundamental role in this context, as they provide the mechanical support for cells to attach and migrate to the injury site, as well as fundamental signals for differentiation. This review describes how different cellular processes (attachment, proliferation, and (directional) migration and differentiation) have been supported by different material parameters, in vitro and in vivo. Although incipient guidelines for biomaterial design become visible, literature in the field remains rather phenomenological. As in other fields of tissue regeneration, progress will depend on more systematic studies on cell-materials response, better understanding on how cells behave and understand signals in their natural milieu from neurobiology studies, and the translation of this knowledge into engineered microenvironments for clinical use.

Published

2018

11. Morfološka karakterizacija neurona spiralnog ganglija uzgojenih u pulsirajućem elektromagnetskom polju

Author

Borić, Tina, Kovačić, Damir, Zoranić, Larisa, and Weber, Ivana

Subjects

elektromagnetsko polje, electromagnetic field, in vitro cultures, Spiral ganglion neuron, morphology, neurite guidance, morfologija, NATURAL SCIENCES. Physics. Biophysics and Medical Physics, Neuroni spiralnog ganglija, in vitro kulture, navođenje neurita, PRIRODNE ZNANOSTI. Fizika. Biofizika i medicinska fizika

Abstract

Spiral ganglion neurons (SGNs), located in the modiolus of the cochlea, transmit auditory signals from mechanosensory hair cells to the cochlear nucleus in the brain stem. Damage of sensitive hair cells, the most common cause of hearing loss, typically leads to the degeneration of SGNs. A cochlear implant (CI), as the most successful neuroprosthetic clinical intervention, allows patients with hearing loss to bypass damaged hair cells by direct electrical stimulation of SGNs. However, one of the main limitations of cochlear implants is the neuroanatomical gap between electrodes and nerve fibers. Finding ways to influence neurite growth direction to reduce the anatomical gap would highly improve a cochlear implant's spatial and temporal resolution. This thesis investigated the effect of substrate type and electromagnetic field (EMF) on the morphology and orientation of SGNS. We conclude that the EMF may reduce the soma radii of SGNs while the micro pillared substrates have the potential to enlarge them. In addition, we found a significant influence of EMF and substrate type on the orientation of SGNs., Neuroni spiralnog ganglija (NSG), smješteni u modiolusu pužnice, prenose slušne signale od slušnih stanica dlačica do kohlearne jezgre u moždanom deblu. Oštećenje ili gubitak neurona spiralnih ganglija i slušnih stanica primarni je uzrok gubitka sluha. Kohlearna implantacija jedan je od najuspješnijih načina obnavljanja osjeta sluha kod ljudi sa slušnim oštećenjem. Jedno od glavnih ograničenja kohlearnog implantata je postojanje anatomske praznine između elektroda i živčanih vlakana. Otkriće metoda kojima bi se moglo utjecati na smjer rasta neurita, u svrhu smanjivanja te anatomske praznine, značajno bi poboljšalo prostornu i vremensku rezoluciju kohlearnog implanta. Cilj ovog rada bio je ispitati mogu li na morfologiju i orijentaciju neurona spiralnog ganglija utjecati vrsta podloge i elektromagnetsko polje. Utvrđeno je da prisutnost elektromagnetskog polja smanjuje radijuse tijela neurona spiralnog ganglija, dok ih supstrati s mikropilarima povećavaju. Osim toga, pokazalo se da vrsta podloge i elektromagnetsko polje značajno utječu na orijentaciju neurona spiralnog ganglija. Dobiveni nalazi poticaj su za daljnja istraživanja ovog područja.

Published

2023

12. Gold nano‐decorated aligned polyurethane nanofibers for enhancement of neurite outgrowth and elongation.

Author

Demir, Ulku Selcen, Shahbazi, Reza, Calamak, Semih, Ozturk, Sukru, Gultekinoglu, Merve, and Ulubayram, Kezban

Abstract

Abstract: Neurite outgrowth and elongation of neural cells is the most important subject that is considered in nerve tissue engineering. In this regard, aligned nanofibers have taken much attention in terms of providing guidance for newly outgrown neurites. The main objective of this study was to fabricate aligned polyurethane nanofibers by electrospinning process and decorate them with gold nanoparticles to further investigate the synergistic effects of nanotopography, biological nerve growth factor (NGF) and electrical stimulations on neurite outgrowth and elongation of pheochromocytoma (PC‐12) model cells. In this regard, smooth and uniform aligned polyurethane nanofibers with the average diameter of 519 ± 56 nm were fabricated and decorated with the gold nanoparticles with the average diameter of ∼50 nm. PC‐12 cells were cultured on the various nanofiber surfaces inside the bio‐mimetic bioreactor system and exposed either to NGF alone or combination of NGF and electrical stimulation. It was found that 50 ng/mL NGF concentration is an optimal value for the stimulation of neurite outgrowth. After 4 days of culture under 100 mV, 10 ms electrical stimulation in 1 h/day period it was found that the gold nanoparticle decorated aligned polyurethane nanofibers increased the neurite outgrowth and elongation more with the combinational NGF and electrical stimulation. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 1604–1613, 2018. [ABSTRACT FROM AUTHOR]

Published

2018

13. The geometry of photopolymerized topography influences neurite pathfinding by directing growth cone morphology and migration.

Author

Vecchi JT, Rhomberg M, Guymon CA, and Hansen MR

Abstract

Cochlear implants (CIs) provide auditory perception to those with profound sensorineural hearing loss: however, the quality of sound perceived by a CI user does not approximate natural hearing. This limitation is due in part to the large physical gap between the stimulating electrodes and their target neurons. Therefore, directing the controlled outgrowth of processes from spiral ganglion neurons (SGNs) into close proximity to the electrode array could provide significantly increased hearing function. For this objective to be properly designed and implemented, the ability and limits of SGN neurites to be guided must first be determined. In this work, we engineered precise topographical microfeatures with angle turn challenges of various geometries to study SGN pathfinding. Additionally, we analyze sensory neurite growth in response to topographically patterned substrates and use live imaging to better understand how neurite growth is guided by these cues. In assessing the ability of neurites to sense and turn in response to topographical cues, we find that the geometry of the angled microfeatures determines the ability of neurites to navigate the angled microfeature turns. SGN neurite pathfinding fidelity can be increased by 20-70% through minor increases in microfeature amplitude (depth) and by 25% if the angle of the patterned turn is made more obtuse. Further, by using engineered topographies and live imaging of dorsal root ganglion neurons (DRGNs), we see that DRGN growth cones change their morphology and migration to become more elongated within microfeatures. However, our observations also indicate complexities in studying neurite turning. First, as the growth cone pathfinds in response to the various cues, the associated neurite often reorients across the angle topographical microfeatures. This reorientation is likely related to the tension the neurite shaft experiences when the growth cone elongates in the microfeature around a turn. Additionally, neurite branching is observed in response to topographical guidance cues, most frequently when turning decisions are most uncertain. Overall, the multi-angle channel micropatterned substrate is a versatile and efficient system to assess SGN neurite turning and pathfinding in response to topographical cues. These findings represent fundamental principles of neurite pathfinding that will be essential to consider for the design of 3D systems aiming to guide neurite growth in vivo .

Published

2023

14. Proper connectivity of Drosophila motion detector neurons requires Atonal function in progenitor cells.

Author

Oliva, Carlos, Ching-Man Choi, Nicolai, Laura J. J., Mora, Natalia, De Geest, Natalie, and Hassan, Bassem A.

Subjects

*DROSOPHILA, *PROGENITOR cells, *MORPHOGENESIS, *GENE regulatory networks, *CELL proliferation, *POSTSYNAPTIC potential

Abstract

Background Vertebrates and invertebrates obtain visual motion information by channeling moving visual cues perceived by the retina through specific motion sensitive synaptic relays in the brain. In Drosophila, the series of synaptic relays forming the optic lobe are known as the lamina, medulla, lobula and lobula plate neuropiles. The fly's motion detection output neurons, called the T4 and T5 cells, reside in the lobula plate. Adult optic lobe neurons are derived from larval neural progenitors in two proliferating compartments known as the outer and inner proliferation centers (OPC and IPC). Important insight has been gained into molecular mechanisms involved in the development of the lamina and medulla from the OPC, though less is known about the development of the lobula and lobula plate. Results Here we show that the proneural gene Atonal is expressed in a subset of IPC progenitors that give rise to the higher order motion detection neurons, T4 and T5, of the lobula plate. We also show that Atonal does not act as a proneural gene in this context. Rather, it is required specifically in IPC neural progenitors to regulate neurite outgrowth in the neuronal progeny. Conclusions Our findings reveal that a proneural gene is expressed in progenitors but is required for neurite development of their progeny neurons. This suggests that transcriptional programs initiated specifically in progenitors are necessary for subsequent neuronal morphogenesis. [ABSTRACT FROM AUTHOR]

Published

2014

15. Neurotrophins differentially stimulate the growth of cochlear neurites on collagen surfaces and in gels.

Author

Joanna Xie, Kwang Pak, Evans, Amaretta, Kamgar-Parsi, Andy, Fausti, Stephen, Mullen, Lina, and Ryan, Allen Frederic

Abstract

The article focuses on the study which aims to evaluate the growth of cochlear neurites in three-dimensional extracellular matrix molecules. The study examined the spiral ganglion explants from neonatal rats, in which the explants were exposed to soluble neurotrophins. The study showed that cochlear neurites grew on collagen surfaces and in three-dimensional collagen gels.

Published

2013

16. Unidirectional diphenylalanine nanotubes for dynamically guiding neurite outgrowth.

Author

Zu L, Shi H, Yang J, Zhang C, Fu Y, Xi N, Liu L, and Wang W

Subjects

Neurons, Neuronal Outgrowth, Cells, Cultured, Neurites physiology, Nanotubes

Abstract

Neural networks have been cultured in vitro to investigate brain functions and diseases, clinical treatments for brain damage, and device development. However, it remains challenging to form complex neural network structures with desired orientations and connections in vitro . Here, we introduce a dynamic strategy by using diphenylalanine (FF) nanotubes for controlling physical patterns on a substrate to regulate neurite-growth orientation in cultivating neural networks. Parallel FF nanotube patterns guide neurons to develop neurites through the unidirectional FF nanotubes while restricting their polarization direction. Subsequently, the FF nanotubes disassemble and the restriction of neurites disappear, and secondary neurite development of the neural network occurs in other direction. Experiments were conducted that use the hippocampal neurons, and the results demonstrated that the cultured neural networks by using the proposed dynamic approach can form a significant cross-connected structure with substantially more lateral neural connections than static substrates. The proposed dynamic approach for neurite outgrowing enables the construction of oriented innervation and cross-connected neural networks in vitro and may explore the way for the bio-fabrication of highly complex structures in tissue engineering., (© 2022 IOP Publishing Ltd.)

Published

2022

17. Formation of one-way-structured cultured neuronal networks in microfluidic devices combining with micropatterning techniques

Author

Takayama, Yuzo, Kotake, Naoki, Haga, Tatsuya, Suzuki, Takafumi, and Mabuchi, Kunihiko

Subjects

*NEURONS, *CULTURES (Biology), *MICROFABRICATION, *AXONS, *DEVELOPMENTAL biology, *NEURAL circuitry, *MICROFLUIDIC devices, *GLASS

Abstract

We present a simple method to regulate the direction of axon development in cultured neurons using microfabrication and microfluidics techniques. We fabricate a PDMS-based device and place it onto a chemically micropatterned glass substrate. We confirm that cultured neurons extend neurites along the medium flow direction and the micropatterned regions. [ABSTRACT FROM AUTHOR]

Published

2012

18. The influence of substrate curvature on neurite outgrowth is cell type dependent

Author

Smeal, Roy M. and Tresco, Patrick A.

Subjects

*CENTRAL nervous system regeneration, *NERVOUS system regeneration, *SURFACE chemistry, *CYTOSKELETON, *NEURONS

Abstract

Abstract: Damage to axonal tracts of the central nervous system results in costly and permanent disability. The observations of aborted neurite outgrowth and disorganized scarring in injured central nervous system tissue have motivated the hypothesis that engineered bridging devices might facilitate regeneration. It is thought that both the shape and surface chemistry are important design parameters, however, their relative importance is poorly understood. Previously, we utilized smooth cylindrical surfaces to demonstrate that surfaces designed with directionally varying curvature bias in a stereotyped way postnatal dorsal root ganglion axonal regeneration in the direction of minimum curvature independent of surface chemistry. In the present study, we extend this analysis to include adult dorsal root ganglion neurons and cerebellar granule cells, cell types more representative of the challenge faced clinically. We found that axonal outgrowth of both the adult neuron and the central neuron was less sensitive to substrate curvature than the outgrowth of the postnatal neurons. These differences were quantified by constructing distributions describing the probability of outgrowth for a defined range of surface curvatures. Both the adult neuron and the central neuron exhibited a higher probability of extension in high-curvature directions compared to the postnatal neuron implying that surface geometry may not be as potent a cue in directing the regeneration of these neurons. A microtubule-stabilizing agent enhanced the sensitivity to curvature of the adult neuron, partially reversing the increased probability of growing in a high-curvature direction. The results suggest novel methods to enhance directed neuron regeneration using bridging substrates. [Copyright &y& Elsevier]

Published

2008

19. Neuro tissue engineering of glial nerve guides and the impact of different cell types

Author

Lietz, Martin, Dreesmann, Lars, Hoss, Martin, Oberhoffner, Sven, and Schlosshauer, Burkhard

Subjects

*CELLS, *CELLULAR control mechanisms, *PHYSIOLOGICAL control systems, *CELL metabolism

Abstract

Abstract: The aim of neuro tissue engineering is to imitate biological features in order to enhance regeneration. Following lesions of peripheral nerves, Schwann cells (SCs) reorganize to form longitudinal bands of Büngner (boB) which function as guides for regrowing axons. In order to imitate boB in synthetic implants designed to bridge nerve lesions, we developed resorbable, semipermeable nerve guide conduits with microstructured internal polymer filaments. We utilized a novel microcell chip and identified three extracellular matrix components conducive for coating non-permissive polymer surfaces. In order to maximize SC alignment, seven different microtopographies were investigated via the silicon chip technology. Special longitudinal microgrooves directed SC orientation and growing axons of dorsal root ganglia (DRG), thus achieving stereotropism. When these results were applied to microgrooved polymer filaments inside nerve guide conduits, we observed highly oriented axon growth without meandering. Since scar-forming fibroblasts could potentially interfere with axonal regrowth, triple cultures with fibroblasts, SC and DRG were conducted. Fibroblasts positioned on the outer nanopore containing conduit wall, did not hamper neuronal and glial differentiation inside the tube. In summary, for more rapid regrowth, functional boB can be induced by guided microtissue engineering. By considering both the negative and positive effects of cell interactions, a more rational design of nerve implants becomes feasible. [Copyright &y& Elsevier]

Published

2006

20. Functional peptide sequences derived from extracellular matrix glycoproteins and their receptors.

Author

Meiners, Sally and Mercado, Mary

Abstract

Peptides derived from extracellular matrix proteins have the potential to function as potent therapeutic reagents to increase neuronal regeneration following central nervous system (CNS) injury, yet their efficacy as pharmaceutical reagents is dependent upon the expression of cognate receptors in the target tissue. This type of codependency is clearly observed in successful models of axonal regeneration in the peripheral nervous system, but not in the normally nonregenerating adult CNS. Successful regeneration is most closely correlated with the induction of integrins on the surface of peripheral neurons. This suggests that in order to achieve optimal neurite regrowth in the injured adult CNS, therapeutic strategies must include approaches that increase the number of integrins and other key receptors in damaged central neurons, as well as provide the appropriate growth-promoting peptides in a “regeneration cocktail.” In this review, we describe the ability of peptides derived from tenascin-C, fibronectin, and laminin-1 to influence neuronal growth. In addition, we also discuss the implications of peptide/receptor interactions for strategies to improve neuronal regeneration. [ABSTRACT FROM AUTHOR]

Published

2003

21. Microenvironments Designed to Support Growth and Function of Neuronal Cells

Author

Farrukh, Aleeza, Zhao, Shifang, and Del Campo, Aránzazu

Subjects

Biomaterials, Neurite guidance, Neuroregeneration, Nerve repair, Axon growth

Abstract

Strategies for neural tissue repair heavily depend on our ability to temporally reconstruct the natural cellular microenvironment of neural cells. Biomaterials play a fundamental role in this context, as they provide the mechanical support for cells to attach and migrate to the injury site, as well as fundamental signals for differentiation. This review describes how different cellular processes (attachment, proliferation, and (directional) migration and differentiation) have been supported by different material parameters, in vitro and in vivo. Although incipient guidelines for biomaterial design become visible, literature in the field remains rather phenomenological. As in other fields of tissue regeneration, progress will depend on more systematic studies on cell-materials response, better understanding on how cells behave and understand signals in their natural milieu from neurobiology studies, and the translation of this knowledge into engineered microenvironments for clinical use.

Published

2019

22. The effect of heat shocks, which alter somite segmentation, on Rohon-Beard neurite outgrowth from the spinal cord of Xenopus embryos.

Author

Patton, D.

Abstract

The vertebrate spinal cord shows a segmental pattern of dorsal and ventral nerve roots. It is believed that this peripheral neural segmentation depends on the segmentation of the somitic mesoderm into somites. I have studied the relationship between somite segmentation and the pattern of Rohon-Beard sensory neurite outgrowth from the spinal cord in Xenopus embryos. Most Rohon-Beard neurites grow out in fascicles from the spinal cord at the intersomite clefts, a smaller number of neurites growing out over the dorsal somite margins. Previous work on peripheral neural segmentation has relied on transplanting or destroying somitic mesoderm. Here a non-invasive technique has been used. The pattern of somite segmentation was disrupted by heat shocks, leading to regions of somite fusion where one or two intersomite clefts are absent. At the regions of somite fusion the number of sensory fascicles is then unchanged but their distribution is different. The segmental pattern of sensory fascicle outgrowth is replaced by a fairly even distribution of outgrowth fascicles. Two interpretations of the difference in fascicle outgrowth at fused and control somites are discussed. Firstly, that heat shocks have a direct affect on fascicle outgrowth. Secondly, that heat shocks affect fascicle outgrowth indirectly by disrupting somite segmentation. [ABSTRACT FROM AUTHOR]

Published

1991

23. Interaction of micropatterned topographical and biochemical cues to direct neurite growth from spiral ganglion neurons.

Author

Truong, Kristy, Leigh, Braden, Vecchi, Joseph T., Bartholomew, Reid, Xu, Linjing, Guymon, C. Allan, and Hansen, Marlan R.

Subjects

*SPIRAL ganglion, *NEURONS, *COCHLEAR implants, *FUNCTIONAL assessment, *SURFACE coatings, *HAIR cells

Abstract

• Photopolymerized topographical methacrylate patterns can be used to microcontact print patterned peptide substrates. • Spiral ganglion neurons align their outgrowth to chemoattractive and chemorepulsive microcontact printed peptide substrates. • These chemoattractive and chemorepulsive cues can be selectively adsorbed onto the ridges or grooves of microtopographical features. • Micropatterning of peptides in cooperative or antagonistic configurations with micro-topographical features enhances or disrupts neurite alignment, respectively. Functional outcomes with neural prosthetic devices, such as cochlear implants, are limited in part due to physical separation between the stimulating elements and the neurons they stimulate. One strategy to close this gap aims to precisely guide neurite regeneration to position the neurites in closer proximity to electrode arrays. Here, we explore the ability of micropatterned biochemical and topographic guidance cues, singly and in combination, to direct the growth of spiral ganglion neuron (SGN) neurites, the neurons targeted by cochlear implants. Photopolymerization of methacrylate monomers was used to form unidirectional topographical features of ridges and grooves in addition to multidirectional patterns with 90o angle turns. Microcontact printing was also used to create similar uni- and multi-directional patterns of peptides on polymer surfaces. Biochemical cues included peptides that facilitate (laminin, LN) or repel (EphA4-Fc) neurite growth. On flat surfaces, SGN neurites preferentially grew on LN-coated stripes and avoided EphA4-Fc-coated stripes. LN or EphA4-Fc was selectively adsorbed onto the ridges or grooves to test the neurite response to a combination of topographical and biochemical cues. Coating the ridges with EphA4-Fc and grooves with LN lead to enhanced SGN alignment to topographical patterns. Conversely, EphA4-Fc coating on the grooves or LN coating on the ridges tended to disrupt alignment to topographical patterns. SGN neurites respond to combinations of topographical and biochemical cues and surface patterning that leverages both cues enhance guided neurite growth. [ABSTRACT FROM AUTHOR]

Published

2021

24. Reduced Graphene Oxide Fibers for Guidance Growth of Trigeminal Sensory Neurons.

Author

Wang X, Guo M, Liu Y, Niu K, Zheng X, Yang Y, and Wang P

Subjects

Animals, Materials Testing, Oxidation-Reduction, Particle Size, Rats, Tissue Scaffolds chemistry, Biocompatible Materials chemistry, Graphite chemistry, Sensory Receptor Cells cytology, Tissue Engineering

Abstract

Neurite alignment and elongation play special roles in the treatment of neuron disease, design of tissue engineering implants, and bioelectrodes applications. For instance, the trigeminal neurons (TGNs) free nerve endings are a key component of the pulp-dentin complex. The reinnervation of the pulp canal space requires the recruitment of apically positioned free nerve endings through axonal guidance. Many studies have been carried to develop patterned two-dimensional substrates or three-dimensional scaffolds with aligned topographical structures to guide axonal growth. However, most of the strategies are either complicated/inconvenient in process or time-/cost-sacrifice. One-step dimensionally confined hydrothermal (DCH) technique has been considered an effective and facile approach to fabricate reduced graphene oxide fibers (rGOFs), and the rGOFs have shown significant potential in regulating neural stem cells differentiation toward neurons. Here, inspired by the relationship between the lateral size of GO nanosheets and the electrical conductivity of GO films made from GO sheets as a building block, we fabricated surface conductivity and topography-controlled rGOFs based on the DCH method. Well "self-patterned" directional channel structure of rGOF showed outstanding ability to improve the neurofilament alignment and migration, with the cell deviation angle less than 10° for over 90% of the cells, while a porous surface structure tended to form neuron nets. All of the rGOF possessed excellent cytocompatibility with TGNs. Our results underlined the high degree of alignment of topographical cues in guidance of neurite over high electrical conductivity. The as-prepared rGOFs could be used in many areas including biosensing, electrochemistry, energy, and peripheral or central nerve tissue engineering.

Published

2021

25. Cell Culture Platforms: Microscaffolds by Direct Laser Writing for Neurite Guidance Leading to Tailor‐Made Neuronal Networks (Adv. Biosys. 5/2019).

Author

Fendler, Cornelius, Denker, Christian, Harberts, Jann, Bayat, Parisa, Zierold, Robert, Loers, Gabriele, Münzenberg, Markus, and Blick, Robert H.

Subjects

CELL culture, NEURONS, NEURAL circuitry

Published

2019

26. Microscaffolds by Direct Laser Writing for Neurite Guidance Leading to Tailor‐Made Neuronal Networks.

Author

Fendler, Cornelius, Denker, Christian, Harberts, Jann, Bayat, Parisa, Zierold, Robert, Loers, Gabriele, Münzenberg, Markus, and Blick, Robert H.

Subjects

NEURONS, BIOLOGICAL neural networks, POLYMERIZATION

Abstract

While modern day integrated electronic circuits are essentially designed in a 2D fashion, the brain can be regarded as a 3D circuit. The thus enhanced connectivity enables much more complex signal processing as compared to conventional 2D circuits. Recent technological advances in the development of nano/microscale 3D structuring have led to the development of artificial neuron culturing platforms, which surpass the possibilities of classical 2D cultures. In this work, in vitro culturing of neuronal networks is demonstrated by determining predefined pathways through topological and chemical neurite guiding. Tailor‐made culturing substrates of microtowers and freestanding microtubes are fabricated using direct laser writing by two‐photon polymerization. The first scaffold design that allows for site‐specific cell attachment and directed outgrowth of single neurites along defined paths that can be arranged freely in all dimensions, to build neuronal networks with low cell density, is presented. The neurons cultured in the scaffolds show characteristic electrophysiological properties of vital cells after 10 d in vitro. The introduced scaffold design offers a promising concept for future complex neuronal network studies on defined neuronal circuits with tailor‐made design specific neurite connections beyond 2D. [ABSTRACT FROM AUTHOR]

Published

2019

27. Neurite Outgrowth is Directed by Schwann Cell Alignment in the Absence of Other Guidance Cues

Author

Thompson, Deanna M. and Buettner, Helen M.

Published

2006

28. The Application of Nanoscience for the Treatment of Spinal Cord Injuries

Author

Louw, Andrew

Subjects

Inflammation, Spinal Cord injuries, neurite guidance, Nanoparticles, Microglia, Nerve Regeneration

Abstract

Spinal cord injuries (SCI) are progressive neurodegenerative conditions, that have extremely limited medical recourse. Upon insult to the spinal cord, axons are severed, the blood brain barrier is compromised, and effector cells are activated to seal the lesion and clean up the debris. The astroglial scar and the secondary inflammatory response are primary causes preventing the natural restoration of the spinal cord. The lack of guidance to exploratory and potential regenerative axons towards their targets also presents challenging obstacle. As the acute presence of the astroglial scar is absolutely required to prevent excessive tissue disruption from prolonged inflammation, I chose to focus my studies on reducing secondary neuroinflammation and promoting axon regeneration and guidance. Chitosan nanoparticles have been extensively used for the delivery of small interfering RNA molecules to affect protein translation in a variety of tissues and cell types - most specifically to macrophages, the primary mediators of the inflammatory response. As microglia are functionally indistinguishable from activated macrophages in SCI, the chitosan nanoparticle system was selected to deliver a micro RNA (miRNA-124) species that has been shown to induce quiescence in macrophages. Our results after administering miRNA-124/chitosan nanoparticles in ex vivo rat microglia show uptake and a marked reduction of inflammatory markers (TNF-α, ROS, and MHC-II). In vivo spinal microinjection of nanoparticles showed macrophage-specific uptake by OX-42/ED-1 positive cells. To explore a less invasive delivery method, nanoparticles injected in the peritoneum were shown to be transported by macrophages to the SCI site, as seen by Cy-3 fluorescence co-localized with ED-1 expression at the lesion 72 h later. Microinjections of chitosan/miR-124 nanoparticles significantly reduced the activation of ED-1 positive macrophages in the injured spinal cord. Taken together these data present a potential minimally invasive treatment technique to reduce inflammation for a multitude of neurodegenerative conditions in the CNS After injury, neurons have the capacity to seal severed axons and reorganize their cytoskeleton remarkably quickly to produce new, exploratory growth cones that could benefit from directional guidance. Applying electrospinning techniques to nerve regeneration has been a central goal for the field, as the fabricated nanofibers have been shown in numerous examples to be highly conducive to neurite outgrowth in 2-dimensional in vitro studies. Here we apply heparan sulfate proteoglycan (HSPG) coatings to regenerated, aligned, silk fibroin nanofibers and show rapid neurite outgrowth of dorsal root ganglia. The HSPG coating is also capable of rendering the neurites insensitive to neurocan, a growth inhibitory chondroitin sulfate proteoglycan, in vitro. Prior attempts to implant nanofibers have been limited by their lack of biomimicry in the form of their tightly woven superstructures preventing cellular ingrowth. We manage to insert our nanofibers inside a synthetic tube, prompting an application to patent our novel nanofiber nerve regeneration conduit. The efficacy of this implantable, 3-dimensional nanofiber device is currently being evaluated in the rat hemisection SCI model. Assuming the success of our conduit, the combination of our studies should provide the basis of a multifaceted approach for treating SCI.

Published

2015

29. Substrate Curvature Influences the Direction of Nerve Outgrowth

Author

Smeal, Roy M., Rabbitt, Richard, Biran, Roy, and Tresco, Patrick A.

Published

2005

30. Oriented Schwann Cell Monolayers for Directed Neurite Outgrowth

Author

Thompson, Deanna M. and Buettner, Helen M.

Published

2004

31. Neurotrophins differentially stimulate the growth of cochlear neurites on collagen surfaces and in gels

Author

Joanna, Xie, Kwang, Pak, Amaretta, Evans, Andy, Kamgar-Parsi, Stephen, Fausti, Lina, Mullen, and Allen Frederic, Ryan

Subjects

inner ear, extracellular matrix, grants-supported paper, neurite guidance, neurotrophin, cochlear implant, collagen gel, neuron, Peripheral Nerve Injury and Neural Regeneration, otorhinolaryngologic diseases, peripheral nerve injury, sense organs, neural regeneration, neuroregeneration

Abstract

The electrodes of a cochlear implant are located far from the surviving neurons of the spiral ganglion, which results in decreased precision of neural activation compared to the normal ear. If the neurons could be induced to extend neurites toward the implant, it might be possible to stimulate more discrete subpopulations of neurons, and to increase the resolution of the device. However, a major barrier to neurite growth toward a cochlear implant is the fluid filling the scala tympani, which separates the neurons from the electrodes. The goal of this study was to evaluate the growth of cochlear neurites in three-dimensional extracellular matrix molecule gels, and to increase biocompatibility by using fibroblasts stably transfected to produce neurotrophin-3 and brain-derived neurotrophic factor. Spiral ganglion explants from neonatal rats were evaluated in cultures. They were exposed to soluble neurotrophins, cells transfected to secrete neurotrophins, and/or collagen gels. We found that cochlear neurites grew readily on collagen surfaces and in three-dimensional collagen gels. Co-culture with cells producing neurotrophin-3 resulted in increased numbers of neurites, and neurites that were longer than when explants were cultured with control fibroblasts stably transfected with green fluorescent protein. Brain-derived neurotrophic factor-producing cells resulted in a more dramatic increase in the number of neurites, but there was no significant effect on neurite length. It is suggested that extracellular matrix molecule gels and cells transfected to produce neurotrophins offer an opportunity to attract spiral ganglion neurites toward a cochlear implant.

Published

2014

32. Proper connectivity of Drosophila motion detector neurons requires Atonal function in progenitor cells

Author

Chingman Choi, Laura Nicolaï, Bassem A. Hassan, Natalie De Geest, Natalia Mora, and Carlos Oliva

Subjects

Neurite, neural progenitor, neurite guidance, Motion Perception, Context (language use), Nerve Tissue Proteins, Developmental Neuroscience, Neural Stem Cells, medicine, Basic Helix-Loop-Helix Transcription Factors, Neurites, Animals, Drosophila Proteins, Motion perception, Medulla, Neurons, Retina, biology, Optic Lobe, Nonmammalian, biology.organism_classification, Neural stem cell, medicine.anatomical_structure, Drosophila melanogaster, atonal, nervous system, Drosophila, Developmental biology, Neuroscience, Research Article

Abstract

Background Vertebrates and invertebrates obtain visual motion information by channeling moving visual cues perceived by the retina through specific motion sensitive synaptic relays in the brain. In Drosophila, the series of synaptic relays forming the optic lobe are known as the lamina, medulla, lobula and lobula plate neuropiles. The fly’s motion detection output neurons, called the T4 and T5 cells, reside in the lobula plate. Adult optic lobe neurons are derived from larval neural progenitors in two proliferating compartments known as the outer and inner proliferation centers (OPC and IPC). Important insight has been gained into molecular mechanisms involved in the development of the lamina and medulla from the OPC, though less is known about the development of the lobula and lobula plate. Results Here we show that the proneural gene Atonal is expressed in a subset of IPC progenitors that give rise to the higher order motion detection neurons, T4 and T5, of the lobula plate. We also show that Atonal does not act as a proneural gene in this context. Rather, it is required specifically in IPC neural progenitors to regulate neurite outgrowth in the neuronal progeny. Conclusions Our findings reveal that a proneural gene is expressed in progenitors but is required for neurite development of their progeny neurons. This suggests that transcriptional programs initiated specifically in progenitors are necessary for subsequent neuronal morphogenesis.

Published

2013

33. Simultaneous pre- and post-synaptic electrophysiological recording from Xenopus nerve-muscle co-cultures

Author

Bruce, Yazejian, Rita M, Yazejian, Rachel, Einarsson, and Alan D, Grinnell

Subjects

Male, Embryo, Nonmammalian, Patch-Clamp Techniques, Physiology, Xenopus, neurite guidance, Neuromuscular Junction, Presynaptic Terminals, Biophysics, Neurophysiology, embryo, neurons, varicosity, patch clamp, Neurobiology, Animals, synaptic currents, Issue 73, Motor Neurons, primary culture, cell culture, synaptogenesis, microdisection, Muscles, animal model, Synaptic Potentials, Coculture Techniques, Electrophysiological Phenomena, Electrophysiology, Cellular Biology, neurotransmitter release, Synapses, Female, motoneurons, Anatomy, Neuroscience, Developmental Biology

Abstract

Much information about the coupling of presynaptic ionic currents with the release of neurotransmitter has been obtained from invertebrate preparations, most notably the squid giant synapse1. However, except for the preparation described here, few vertebrate preparations exist in which it is possible to make simultaneous measurements of neurotransmitter release and presynaptic ionic currents. Embryonic Xenopus motoneurons and muscle cells can be grown together in simple culture medium at room temperature; they will form functional synapses within twelve to twenty-four hours, and can be used to study nerve and muscle cell development and synaptic interactions for several days (until overgrowth occurs). Some advantages of these co-cultures over other vertebrate preparations include the simplicity of preparation, the ability to maintain the cultures and work at room temperature, and the ready accessibility of the synapses formed2-4. The preparation has been used widely to study the biophysical properties of presynaptic ion channels and the regulation of transmitter release5-8. In addition, the preparation has lent itself to other uses including the study of neurite outgrowth and synaptogenesis9-12, molecular mechanisms of neurotransmitter release13-15, the role of diffusible messengers in neuromodulation16,17, and in vitro synaptic plasticity18-19.

Published

2013

34. Neurite Guidance on Laser-Scribed Reduced Graphene Oxide.

Author

Lee SH, Lee HB, Kim Y, Jeong JR, Lee MH, and Kang K

Abstract

This paper describes a one-step, chemical-free method to generate micropatterned in vitro neuronal networks on chemically unmodified reduced graphene oxide. The suggested method relies on infrared-based photothermal reduction of graphene oxide, which concurrently leads to the formation of submicrometer-scale surface roughness that promotes neuronal adhesion and guides neurite outgrowth. A commercially available laser source (LightScribe DVD drive) controlled by a computer software can be used to reduce graphene oxide (GO), and its repetitive scribing to a GO film brings about gradual increase and decrease in electrical conductivity and neurite guiding ability of the scribed regions, respectively. Our results also indicate that the observed adhesion-promoting and neurite guiding effect originate from the contrast in surface nanotopography, but not that in conductivity. This method is readily applicable to diverse graphene-based biomedical devices.

Published

2018

35. Nanoimprinted Anisotropic Topography Preferentially Guides Axons and Enhances Nerve Regeneration.

Author

Huang YA, Ho CT, Lin YH, Lee CJ, Ho SM, Li MC, and Hwang E

Subjects

Animals, Anisotropy, Axons ultrastructure, Biocompatible Materials chemical synthesis, Biocompatible Materials chemistry, Cerebral Cortex cytology, Cerebral Cortex drug effects, Ganglia, Spinal injuries, Ganglia, Spinal surgery, Mice, Mice, Inbred C57BL, Molecular Imprinting methods, Nanostructures chemistry, Nanostructures ultrastructure, Nerve Regeneration physiology, Neurites drug effects, Neurites ultrastructure, Peripheral Nerve Injuries pathology, Polyethylenes chemical synthesis, Polyethylenes chemistry, Polyvinyls chemical synthesis, Polyvinyls chemistry, Primary Cell Culture, Rats, Sensory Receptor Cells drug effects, Sensory Receptor Cells ultrastructure, Axons drug effects, Biocompatible Materials pharmacology, Guided Tissue Regeneration methods, Nerve Regeneration drug effects, Peripheral Nerve Injuries therapy, Polyethylenes pharmacology, Polyvinyls pharmacology

Abstract

Surface topography has a profound effect on the development of the nervous system, such as neuronal differentiation and morphogenesis. While the interaction of neurons and the surface topography of their local environment is well characterized, the neuron-topography interaction during the regeneration process remains largely unknown. To address this question, an anisotropic surface topography resembling linear grooves made from poly(ethylene-vinyl acetate) (EVA), a soft and biocompatible polymer, using nanoimprinting, is established. It is found that neurons from both the central and peripheral nervous system can survive and grow on this grooved surface. Additionally, it is observed that axons but not dendrites specifically align with these grooves. Furthermore, it is demonstrated that neurons on the grooved surface are capable of regeneration after an on-site injury. More importantly, these injured neurons have an accelerated and enhanced regeneration. Together, the data demonstrate that this anisotropic topography guides axon growth and improves axon regeneration. This opens up the possibility to study the effect of surface topography on regenerating axons and has the potential to be developed into a medical device for treating peripheral nerve injuries., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

36. Neurotrophins differentially stimulate the growth of cochlear neurites on collagen surfaces and in gels.

Author

Xie J, Pak K, Evans A, Kamgar-Parsi A, Fausti S, Mullen L, and Ryan AF

Abstract

The electrodes of a cochlear implant are located far from the surviving neurons of the spiral ganglion, which results in decreased precision of neural activation compared to the normal ear. If the neurons could be induced to extend neurites toward the implant, it might be possible to stimulate more discrete subpopulations of neurons, and to increase the resolution of the device. However, a major barrier to neurite growth toward a cochlear implant is the fluid filling the scala tympani, which separates the neurons from the electrodes. The goal of this study was to evaluate the growth of cochlear neurites in three-dimensional extracellular matrix molecule gels, and to increase biocompatibility by using fibroblasts stably transfected to produce neurotrophin-3 and brain-derived neurotrophic factor. Spiral ganglion explants from neonatal rats were evaluated in cultures. They were exposed to soluble neurotrophins, cells transfected to secrete neurotrophins, and/or collagen gels. We found that cochlear neurites grew readily on collagen surfaces and in three-dimensional collagen gels. Co-culture with cells producing neurotrophin-3 resulted in increased numbers of neurites, and neurites that were longer than when explants were cultured with control fibroblasts stably transfected with green fluorescent protein. Brain-derived neurotrophic factor-producing cells resulted in a more dramatic increase in the number of neurites, but there was no significant effect on neurite length. It is suggested that extracellular matrix molecule gels and cells transfected to produce neurotrophins offer an opportunity to attract spiral ganglion neurites toward a cochlear implant.

Published

2013

37. Neurite guidance through 3D hydrogel layers in a microfluidic environment

Author

Kunze, Anja, Meissner, Robert, and Renaud, Philippe

Subjects

nervous system, neurite guidance, microfluidic, neurons, hydrogel, patterned 3D cell culture, chemical gradient

Abstract

Neuronal cell culture models in vitro are often restricted to 2D surfaces. Engineering the complexity of the neuronal microenvironment in microfluidic systems can help to generate more tissue like cultures. We have developed a new neuronal cell culturing system based on a microfluidic device that can culture primary neurons in a 3D patterned hydro- gel based microenvironment. Perpendicular to the culture channel a chemical gradient was established to guide neurites. Neurons cultured under a 62.5 ng (ml mm)-1 nerve growth factor (NGF) gradient up to 9 days in vitro (DIV), extended their neurites through the hydrogel in the direction of the higher concentration.

38. Micro-engineering the Cerebral Cortical Cell Niche A new Cell Culture Tool for Neuroscience Research

Author

Kunze, Anja and Renaud, Philippe

Subjects

NGF, gradients, acide okadaïque, Okadaic acid, Hyper-phosphorylated Tau, Disease propagation, organisation de plusieurs couches de cellules, maladie d'Alzheimer, Microfluidics, formation des synapses, orientation des neurites, Multiple cell layer organization, cellules neuronales, organisation de la culture en 3D, propagation des maladies, Alzheimer's Disease, Neural cells, Gradients, 3D micropatterned culture, Synapse formation, B27, Neurite guidance, protéines Tau hyper-phosphorylée, microfluidique

Abstract

A major problem in traditional cell culture methods, such as Petri dishes and culture flasks, is the very simplified artificial environment around the cells. Traditional cell culture methods lack features of the native cell niche, such as gradients and cell organization. This lack probably explains why pharmaceutics against the neurodegenerative Alzheimer's disease successfully stop the propagation of the disease in the Petri dish, but fail so far in clinical trials. This thesis intends to improve cell culture methods for neuroscience research related to neural developmental questions and neurodegenerative diseases. As the cortex is the main part in our brain, related to memory, emotions and perception, this thesis does focus on cell culture tools and protocols for primary cortical neurons. Currently, dissociated neurons are cultured in pure or co-culture of neural and non-neural cells, but structuring elements and controlled gradient formation is missing. The first part of this thesis discusses different studies that implicate environmental components for neural cells in their native neural cell niche. We will establish a generic neural cell niche, which consists of different neural and non-neural cells, a structured 3D environment, molecular gradients and oriented neurite networks, in a nutshell. Additionally, a simplified model of the generic neural cell niche is introduced that is implemented in a microfluidic base cell culture tool. This novel artificial neural cell niche will provide cell layer structure in 3D and local control of molecular gradients at the microscale. We will use microfluidic technology to integrate missing features in cell culture techniques for primary cortical neurons. The microfluidic device will consist of three parts: (1) a main cell culture channel that is used to organize neural cells in 3D hydrogel layers, side-by-side; (2) parallel perfusion channels to mimic nutrient supply and to control stable gradient formation, (3) interconnecting microchannels, called junction channels, that separate perfusion driven molecular transport from diffusive molecular transport. The perfusion channels are connected to device-incorporated reservoirs that allow maintenance of stable molecular gradients based on perfusion and diffusion without the use of peristaltic or syringe pumps. By injecting cortical neurons entrapped in an agarose-alginate solution in the microfluidic device, we generated 3D micropatterned neural cell layers with stable gradients perpendicular to the layer orientation. We demonstrated neurite outgrowth behavior until three weeks in culture. The application of different cell organization patterns revealed an influence of the pattern on the cell culture response. Using neurotrophic gradients of nerve growth factor (NGF) and nutrient supplements (B27), we showed that neurite guidance and synapse formation followed synergistic NGF/B27 gradients. We found that the gradient induced effects are very sensitive to changes in the environmental structure, such as the cell layer organization. Using a gradient of a phosphatase inhibitor, okadaic acid, we generated locally diseased states of the protein Tau in both 2D and 3D micropatterned neural cell cultures. The diseased form of Tau, hyper-phosphorylated Tau, is a major hallmark of Alzheimer's disease. For the first time, local formation of hyper-phosphorylated Tau was demonstrated to affect a defined cell population in a compartmentalized 2D or 3D neural cell culture. Our results revealed that the propagation mechanism of this Alzheimer's diseased lesion is determined through the formation of the 2D or 3D environment. We think that this new neural cell culture tool has the potential to answer biological questions related to environmental and structural parameters involved in the formation of the cerebral cortex and in the propagation of neurodegenerative diseases. Future studies in modern neuroscience research can now better investigate the effect of gradient parameters such as the slope, average concentration or gradient profile on cell culture and disease propagation in a controlled manner. Furthermore, the influence of cell patterns in 2D and 3D is addressed with the ability to modify cell position, density and type at the microscale. The local formation of neurodegenerative disease lesions in a micropatterned neural cell culture is generic, which makes the integration of other neurodegenerative disease models, such as Parkinson's disease, Amyotrophic lateral sclerosis or Huntington's disease, possible.