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Niranjan Reddy, K.
- Verification of GPIO Core Functions using Universal Verification Methodology
Abstract Views :285 |
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Authors
Affiliations
1 Malla Reddy Engineering College for Women, Hyderabad, Telangana State, IN
2 Gitam Institute of Technology, Gitam University, Visakhapatnam, AP, IN
1 Malla Reddy Engineering College for Women, Hyderabad, Telangana State, IN
2 Gitam Institute of Technology, Gitam University, Visakhapatnam, AP, IN
Source
International Journal of Research in Signal Processing, Computing & Communication System Design, Vol 1, No 1 (2015), Pagination: 16-19Abstract
The OPB GPIO design provides a general purpose input/output interface to a 32-bit On-Chip Peripheral Bus (OPB). The GPIO IP core is user-programmable generalpurpose I/O controller. That is use is to implement functions that are not implemented with the dedicated controllers in a system and require simple input and/or output software controlled signals. It is one of the important peripheral that is listed on any FPGA board. In this project we are atomizing the operation of the GPIO by writing the code in SYSTEM-VERILOG and simulating it in QUESTA MODELSIM. The main aim of this project is to verify the output by using GPIO pins depending up on the preference the code. We verify the GPIO modules by using UVM [Universal verification Methodology]. The functional verification of the RTL design of the GPIO is carried out for the better optimum design.- CMTI’s Role in Metrology
Abstract Views :203 |
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Authors
Affiliations
1 Central Manufacturing Technology Institute, Tumkur Road, Bangalore, IN
1 Central Manufacturing Technology Institute, Tumkur Road, Bangalore, IN
Source
Manufacturing Technology Today, Vol 13, No 6 (2014), Pagination: 11-15Abstract
With the objective of catering the R&D needs of machine tools and allied areas in focus, along with the basic infrastructure of the institute, various laboratories including metrology laboratory were setup in CMTI to support developmental activities and to assist prototype workshop. With the advancement of time, these laboratories started catering to the needs of industries throughout India. Over last 5 decades, CMTI had significantly contributed in Product development, Technology development, Training, Framing Standards, Development of Artefacts in Metrology field. CMTI has been a forerunner in all the above aspects in the country particularly in dimensional and surface metrology.- Establishment of Optimum Number of Scanning Points for a Scanning Feature Using Ultra Precision CMM
Abstract Views :184 |
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Authors
Affiliations
1 Micro Engineering & Nano Technology Department, Central Manufacturing Technology Institute, Tumkur Road, Bangalore, IN
2 National Institute of Technology Karnataka, Surathkal, IN
1 Micro Engineering & Nano Technology Department, Central Manufacturing Technology Institute, Tumkur Road, Bangalore, IN
2 National Institute of Technology Karnataka, Surathkal, IN
Source
Manufacturing Technology Today, Vol 11, No 3 (2012), Pagination: 23-26Abstract
Coordinate Measuring Machine (CMM) is a measuring system with a movable probing system and capability to determine spatial coordinates on a work piece surface, that can be further analyzed to arrive at the required parameters. As geometry of feature is not ideal, the number of points, their distribution and their computation method have an effect on the results of dimension, form and position and therefore on also coordinate system. Discrete point probing uses only few points to calculate the ideal circle; the outcome of this is incorrect information on form shape. For features having functional requirement like assembly, running accuracy form is critical and true shape of the feature is required. Hence, CMMs are developed with scanning feature; which supplies the large data quantities for evaluation. The optimization of scanning parameters like number of points for a feature is one of the important parameters in the coordinate metrology. The aim of the paper is to describe the effect of number of points for scanning a feature and optimization of this scanning parameter and to adopt the optimized scanning data to the discrete point probing system.Keywords
CMM, Scanning, Discrete Point Probing, Form, Feature, Optimization.- Measurement of Straightness of High Aspect Ratio Thick Walled Cylinder-A Concept
Abstract Views :230 |
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Authors
Affiliations
1 Central Manufacturing Technology Institute, Bangalore, IN
1 Central Manufacturing Technology Institute, Bangalore, IN
Source
Manufacturing Technology Today, Vol 11, No 1-2 (2012), Pagination: 5-10Abstract
Productivity in manufacture of high aspect ratio cylinders depends on how quickly the inspection parameters are measured and corrective actions are token. Long cylinders undergo a series of processes including bend removal and machining. These processes undergo a series of iterations consuming considerable amount of time for the measurement of straightness of cylinder. In this paper, a concept is proposed, where, the straightness of the bore of a cylinder (barrel) is measured in-situ on the machine. In this method, the barrel diameter and thickness are measured at number of planes using touch trigger probe and ultrasonic transducer respectively. Ultrasonic transducer assembly and the touch trigger probe are mounted on the turret of the CNC Turn Mill Centre. The setup for ultrasonic based measurement includes a nozzle for the supply of stream of liquid on the work piece, an ultrasonic transducer and a data capturing unit. Echo from ultrasonic waves is obtained back from the stream enabling the measurement of the relative position from the outer profile of the work piece to its internal profile. By orienting (rotating) the work piece at different locations in the same plane, thickness and diameters are measured. Straightness is measured by continuing to measure along the length of the cylinder. The thickness and diameters obtained are then used for the evaluation of straightness of the bore.Keywords
Straightness, Cylinder, Touch Trigger Probe, Ultrasonic Transducer.- Micro Finish & Micro Wire EDM Applications in Precision Manufacturing
Abstract Views :185 |
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Authors
Affiliations
1 Micro Engineering and Nano Technology Dept., Central Manufacturing Technology Institute, Tumkur Road, Bangalore, IN
1 Micro Engineering and Nano Technology Dept., Central Manufacturing Technology Institute, Tumkur Road, Bangalore, IN
Source
Manufacturing Technology Today, Vol 6, No 1 (2007), Pagination: 20-22Abstract
Today, wire EDM is providing the most economical solution for manufacture of Dies, Punches and special tools required in almost all the engineering industries. Often, Wire EDM is found to be the only solution for parts, which are extremely difficult or Impossible to handle with any other method of machining. Now, the same process is found to be Ideally suited for manufacture of micro components. These products require very high surface finish, profile accuracy and smallest possible radius In the corners. With the continuous refinement and innovations in the technology, the design of the machine, the spark generator and the operation software the Micro finish and Micro Wire EDMs have been developed. This paper gives the main features of the Micro Finish & Micro wire EDM and the some of the parts machined on this type of machine, which give insight to the use of this type of machine In precision manufacturing.- Micro-Drilling of Precision Flat Bottom Holes in Titanium
Abstract Views :186 |
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Authors
Affiliations
1 Micro Engineering & Nano Technology Department, CMTI, Bangalore, IN
1 Micro Engineering & Nano Technology Department, CMTI, Bangalore, IN
Source
Manufacturing Technology Today, Vol 3, No 3 (2004), Pagination: 7-9Abstract
In Non Destructive Testing (NDT) ultrasonic flaw detectors are extensively used for inspection of metallic raw materials like forgings, castings and rolled sections for internal imperfections and defects like cracks, voids, inclusions etc. In these Ultrasonic flaw detectors Ultrasonic standard reference blocks are used as masters for allowable level of flaws in metallic raw materials. These reference blocks are also used for calibration of flaw detectors. These reference blocks are made with precisely drilled flat bottom holes (FBH) of different diameters depending on the allowable level of flaws. Reference blocks with flat bottom holes of dia from 2 mm down to dia 0.5 mm are mainly used in aerospace applications. These blocks are to be made in the same material that is to be inspected. The typical test materials are Aluminium, Steel, Titanium and Nickel base alloys. This paper deals with micro-drilling of 0.5 mm diameter flat bottom holes in Titanium material Ultrasonic Standard Reference Blocks.- Development of Ultrasonic Standard Reference Blocks of Aerospace Quality
Abstract Views :210 |
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Authors
Affiliations
1 Precision Engineering and Nano Technology Department, Central Manufacturing Technology Institute, Bangalore-560022, IN
2 Aircraft Research and Design Centre, HAL, Bangalore-560037, IN
1 Precision Engineering and Nano Technology Department, Central Manufacturing Technology Institute, Bangalore-560022, IN
2 Aircraft Research and Design Centre, HAL, Bangalore-560037, IN
Source
Manufacturing Technology Today, Vol 1, No 2 (2002), Pagination: 5-7Abstract
Ultrasonic standard reference blocks are extensively used in calibration and performance evaluation of Ultrasonic flaw detectors. They are also used in inspection of metallic raw materials like forgings, castings and rolled sections apart from machined components for any flaws like cracks, inclusions etc. These reference blocks consist of precisely drilled flat bottom holes (FBH) to act as intentional flaws and they are made from the same material that is to be inspected to get the same acoustic response. The typical test materials are Titanium alloys, Copper alloys, Aluminium alloys and Steels. Ultrasonic response tests are carried out for studying the intensity of the returned echo from the flat bottom, over different metal travel distances. Reference blocks with flat bottom of dia from 2 mm down to 0.5 mm are used mainly in aerospace applications. This paper deals with the manufacturing and inspection techniques employed in the indigenous development of Titanium Alloy reference blocks of 1.2 mm FBH.- Development of High Precision Glass Scale Gratings Using Ultra Fast Pulsed Laser
Abstract Views :216 |
PDF Views:1
Authors
Affiliations
1 Central Manufacturing Technology Institute (CMTI), Bengaluru, Karnataka, IN
1 Central Manufacturing Technology Institute (CMTI), Bengaluru, Karnataka, IN
Source
Manufacturing Technology Today, Vol 17, No 1 (2018), Pagination: 3-6Abstract
Standard glass scale is just like a kind of very precise ruler and on its surface, accurate divisions are equally marked. The standard glass scales are frequently used in calibration of precise instruments with non contact method of measurements like optical microscopes, video microscopes, profile projectors etc. With the help of ultra fast pulsed laser micromachining system devised a state of the art process for manufacturing standard glass scales. The machined standard scales were calibrated using F25 CMM for 10 mm range scale and Profile projector for 150 mm range scale. The results of the calibration shows the accuracy of the Glass scales at par with the scales manufactured by photolithography process.Keywords
Standard Glass Scale, Gratings, Stage Micrometers, Ultra Fast Pulsed Laser.- Investigation on the Effect of Nucleation Time on CNT Growth Process using RF-PECVD
Abstract Views :231 |
PDF Views:0
Authors
Affiliations
1 Central Manufacturing Technology Institute (CMTI), Bengaluru, IN
2 National Institute of Technology Karnataka (NITK), Surathkal, IN
1 Central Manufacturing Technology Institute (CMTI), Bengaluru, IN
2 National Institute of Technology Karnataka (NITK), Surathkal, IN
Source
Manufacturing Technology Today, Vol 18, No SP 3 (2019), Pagination: 25-30Abstract
Carbon Nano Tubes (CNTs) were deposited on Silicon substrate by RF plasma enhanced chemical vapour deposition (RF-PECVD). The deposition was carried out at 550 V bias and 600°C with C2H2 precursor gas diluted with H2 in the ratio of 1:4. Transition metal catalysts are required for CNT growth by PECVD. It is believed that the catalyst on the substrate must be in the form of particles instead of smooth, continuous films. The eventual particle size and the resultant nanotube diameter correlates to film thickness. Thinner films in general lead to smaller particles and tube diameters. While a small grain size is not guaranteed in as-prepared films, steps are taken to break the film into desired particles to form island like structures. This work investigates the effect of Nucleation and the time interval of Nucleation on the CNT growth process.Keywords
CNT, Nucleation, RF-PECVDReferences
- 1. Meyyappan M and Srivastava D: Carbon Nanotubes: Handbook of Nanoscience, Engineering, and Technology, 2003, Boca Raton, FL: CRC Press.
- Meyyappan M: Plasma Sources, ‘Sci. Technol’. 12, 2003, 205–216.
- RGuzm´an de Villoria: Nanotechnology, 20, 2009, 405611 (IOP publishing)
- The Wondrous World of Carbon Nanotubes ‘a review of current carbon nanotube technologies’: 2003, Eindhoven University of Technology
- Review on Surface Modification of Microelectrode Array for Extracellular Recording of the Neural Interface System
Abstract Views :160 |
PDF Views:0
Authors
Affiliations
1 Central Manufacturing Technology Institute, Bengaluru, Karnataka, IN
1 Central Manufacturing Technology Institute, Bengaluru, Karnataka, IN
Source
Manufacturing Technology Today, Vol 21, No 1-2 (2022), Pagination: 3-20Abstract
Globally neurological diseases are increasing due to unhealthy lifestyles, environmental influences, and physical injuries. So, MEA (microelectrode array) based neural interface systems can restore the lost neural functions to treat neurological diseases through stimulating or recording a neuronal signal. In 1664 Jan Swammerdam was the first to explain nerve function and nerve stimulation. Nowadays, many neural recording systems are available for interfacing with the brain. These systems can be classified into two ways: intracellular or extracellular recording. The extracellular recording is the technique of recording or stimulating the neural signals by placing the electrode near the tissues or cells. It is a less invasive approach compared to an intracellular recording. Generally, the neural interface systems are classified as the CNS (central nervous system) and PNS (peripheral nervous system). Microelectrode arrays can interface in the central nervous system to treat neurological diseases. A mechanical mismatch is a significant problem that arises during the insertion of the implant into the brain tissue. So, various surface modification techniques are considered a viable solution among researchers to address this issue. Also, laser and EDM-based new fabrication techniques are getting more attention over photolithography techniques for reducing the fabrication timing, cost, and usage of hazardous chemicals.Keywords
Microelectrode Array, Neural Interface Systems, Laser and EDM Fabrication Techniques, Surface Modification.References
- Abidian, M. R., & Martin, D. C. (2008). Experimental and theoretical characterization of implantable neural microelectrodes modified with conducting polymer nanotubes. Biomaterials, 29(9), 1273–1283. https://doi.org/10.1016/j.biomaterials.2007.11.022
- Bamberg, E., & Rakwal, D. (2008). Experimental investigation of wire electrical discharge machining of gallium-doped germanium. Journal of Materials Processing Technology, 197(1–3), 419–427. https://doi.org/10.1016/j.jmatprotec.2007.06.038
- Bao, M., & Wang, W. (1996). Future of microelectromechanical systems (MEMS). Sensors and Actuators, A: Physical, 56(1–2). https://doi.org/10.1016/0924-4247(96)01274-5
- Berces, Z., Toth, K., Marton, G., Pál, I., KovátsMegyesi, B., Fekete, Z., Ulbert, I., & Pongrácz, A. (2016). Neurobiochemical changes in the vicinity of a nanostructured neural implant. Scientific Reports, 6. https://doi.org/10.1038/srep35944
- Buzsáki, G., Anastassiou, C. A., & Koch, C. (2012). The origin of extracellular fields and currents-EEG, ECoG, LFP and spikes. Nature Reviews Neuroscience, 13(6), 407–420. https://doi.org/10.1038/nrn3241
- Chaileshwar, R. D., Mamilla, R. S., & Magadum, S. (2020), A brief review on laser surface texturing of biomaterials for cell culture applications. Manufacturing Technology Today, 19(9), 8-12. http://www.ischolar.info/index.php/MTT/article/view/207948
- Chapman, C. A. R., Chen, H., Stamou, M., Biener, J., Biener, M. M., Lein, P. J., & Seker, E. (2015). Nanoporous gold as a neural interface coating: Effects of topography, surface chemistry, and feature size. ACS Applied Materials and Interfaces, 7(13), 7093–7100. https://doi. org/10.1021/acsami.5b00410
- Cheung, K. C., Renaud, P., Tanila, H., &Djupsund, K. (2007). Flexible polyimide microelectrode array for in vivo recordings and current source density analysis. Biosensors and Bioelectronics, 22(8), 1783–1790. https://doi.org/10.1016/j.bios.2006.08.035
- Dee, K. C., Puleo, D. A., & Bizios, R. (2003). An Introduction To Tissue-Biomaterial Interactions. An Introduction To TissueBiomaterial Interactions. https://doi.org/10.1002/0471270598
- Du, Z. J., Kolarcik, C. L., Kozai, T. D. Y., Luebben, S. D., Sapp, S. A., Zheng, X. S., Nabity, J. A., & Cui, X. T. (2017). Ultrasoft microwire neural electrodes improve chronic tissue integration. Acta Biomaterialia, 53, 46–58. https://doi.org/10.1016/j.actbio.2017.02.010
- Ereifej, E. S., Smith, C. S., Meade, S. M., Chen, K., Feng, H., & Capadona, J. R. (2018). The Neuroinflammatory Response to Nanopatterning Parallel Grooves into the Surface Structure of Intracortical Microelectrodes. Advanced Functional Materials, 28(12). https://doi.org/10.1002adfm.201704420
- Fattahi, P., Yang, G., Kim, G., & Abidian, M. R. (2014). A review of organic and inorganic biomaterials for neural interfaces. Advanced Materials, 26(12), 1846-1885. Wiley-VCH Verlag. https://doi.org/10.1002/adma.201304496
- Ferguson, M., Sharma, D., Ross, D., & Zhao, F. (2019). A Critical Review of Microelectrode Arrays and Strategies for Improving Neural Interfaces. Advanced Healthcare Materials, 8(19). Wiley-VCH Verlag. https://doi.org/10.1002/adhm.201900558
- Fiáth, R., Hofer, K. T., Csikós, V., Horváth, D., Nánási, T., Tóth, K., Pothof, F., Böhler, C., Asplund, M., Ruther, P., & Ulbert, I. (2018). Long-term recording performance and biocompatibility of chronically implanted cylindrically-shaped, polymer-based neural interfaces. Biomedizinische Technik, 63(3), 301–315. https://doi.org/10.1515/bmt-2017-0154
- Frazier, A. B. (1995). Recent applications of polyimide to micromachining technology. IEEE transactions on industrial electronics, 42(5), 442 - 448
- Ghane-Motlagh, B., & Sawan, M. (2013). A review of Microelectrode Array technologies: Design and implementation challenges. 2013 2nd International Conference on Advances in Biomedical Engineering, ICABME 2013, 38–41. https://doi.org/10.1109/ICABME.2013.6648841
- Gorham, W. F. (1966). A New, General Synthetic Method for the Preparation of Linear Poly-p-xylylenes. Journal of Polymer Science Part A-1: Polymer Chemistry, 4(12). https://doi.org/10.1002/pol.1966.150041209
- Gower, M. C. (2001). Laser micromachining for manufacturing MEMS devices. MEMS Components and Applications for Industry, Automobiles, Aerospace, and Communication, 4559. https://doi.org/10.1117/12.443040
- Green, R. A., Ordonez, J. S., Schuettler, M., Poole-Warren, L. A., Lovell, N. H., & Suaning, G. J. (2010). Cytotoxicity of implantable microelectrode arrays produced by laser micromachining. Biomaterials, 31(5), 886–893. https://doi.org/10.1016/j.biomaterials.2009.09.099
- Hamel, E. J. O., Grewe, B. F., Parker, J. G., & Schnitzer, M. J. (2015). Cellular level brain imaging in behaving mammals: An engineering approach. In Neuron, 86(1), 140-159. Cell Press. https://doi.org/10.1016/j.neuron.2015.03.055
- Hassler, C., Boretius, T., & Stieglitz, T. (2011). Polymers for neural implants. Journal of Polymer Science, Part B: Polymer Physics, 49 (1), 18–33. https://doi.org/10.1002/polb.22169
- Hayden, C. J., & Dalton, C. (2010). Direct patterning of microelectrode arrays using femtosecond laser micromachining. Applied Surface Science, 256(12), 3761–3766. https://doi.org/10.1016/j.apsusc.2010.01.022
- Holmes, A. S. (2001). Laser fabrication and assembly processes for MEMS. Laser Applications in Microelectronic and Optoelectronic Mnf VI, 4274. https://doi.org/10.1117/12.432522
- Karumbaiah, L., Saxena, T., Carlson, D., Patil, K., Patkar, R., Gaupp, E. A., Betancur, M., Stanley, G. B., Carin, L., & Bellamkonda, R. V. (2013). Relationship between intracortical electrode design and chronic recording function. Biomaterials, 34(33), 8061–8074. https://doi.org/10.1016/j.biomaterials.2013.07.016
- Keefer, E. W., Botterman, B. R., Romero, M. I., Rossi, A. F., & Gross, G. W. (2008). Carbon nanotube coating improves neuronal recordings. Nature Nanotechnology, 3(7), 434–439. https://doi.org/10.1038/nnano.2008.174
- Khorasani, M. T., &Mirzadeh, H. (2004). BHK cells behaviour on laser treated polydimethylsiloxane surface. Colloids and Surfaces B: Biointerfaces, 35(1), 67–71. https://doi.org/10.1016/j.colsurfb.2004.01.011
- Kornblum, H. I., Araujo, D. M., Annala, A. J., Tatsukawa, K. J., Phelps, M. E., & Cherry, S. R. (2000). In vivo imaging of neuronal activation and plasticity in the rat brain by high resolution positron emission tomography (microPET). Nature Biotechnology, 18(6), 655–660. https://doi.org/10.1038/76509
- Kozai, T. D. Y., Jaquins-Gerstl, A. S., Vazquez, A. L., Michael, A. C., & Cui, X. T. (2015). Brain tissue responses to neural implants impact signal sensitivity and intervention strategies. ACS Chemical Neuroscience, 6(1), 48–67. https://doi.org/10.1021/cn500256e
- Lee, S. K., & Na, S. J. (1999). KrF excimer laser ablation of thin Cr film on glass substrate. Applied Physics A: Materials Science and Processing, 68(4), 417–423. https://doi.org/10.1007/s003390050916
- Liu, Y., Zhang, X., & Hao, P. (2016). The effect of topography and wettability of biomaterials on platelet adhesion. Journal of Adhesion Science and Technology, 30(8), 878–893. https://doi.org/10.1080/01694243.2015.1129883
- Luan, L., Wei, X., Zhao, Z., Siegel, J. J., Potnis, O., Tuppen, C. A., Lin, S., Kazmi, S., Fowler, R. A., Holloway, S., Dunn, A. K., Chitwood, R. A., & Xie, C. (2017). Ultraflexible nanoelectronic probes form reliable, glial scar–free neural integration. Science Advances, 3(2). https://doi.org/10.1126/sciadv.1601966
- Neuron - Servier Medical Art. (n.d.). Retrieved December 9, 2021, from https://smart.servier.com/smart_image/neuron/
- Nicholls, J. G., & Kuffler, S. W. (2012). From Neuron to brain. Neuroscience (Fifth edition.). Sinauer Associates Inc.
- Polikov, V. S., Tresco, P. A., & Reichert, W. M. (2005). Response of brain tissue to chronically implanted neural electrodes. Journal of Neuroscience Methods, 148(1), 1–18. https://doi.org/10.1016/j.jneumeth.2005.08.015
- Qi, D., Liu, Z., Liu, Y., Jiang, Y., Leow, W. R., Pal, M., Pan, S., Yang, H., Wang, Y., Zhang, X., Yu, J., Li, B., Yu, Z., Wang, W., & Chen, X. (2017). Highly Stretchable, Compliant, Polymeric Microelectrode Arrays for In Vivo Electrophysiological Interfacing. Advanced Materials, 29(40). https://doi.org/10.1002/adma.201702800
- Rakwal, D., Heamawatanachai, S., Tathireddy, P., Solzbacher, F., & Bamberg, E. (2009). Fabrication of compliant high aspect ratio silicon microelectrode arrays using micro-wire electrical discharge machining. Microsystem Technologies, 15(5), 789-797. https://doi.org/10.1007/s00542-009-0792-7
- Rastogi, S. K., & Cohen-Karni, T. (2019). Nanoelectronics for neuroscience. Encyclopedia of Biomedical Engineering, (Vols. 1–3, pp. 631–649). https://doi.org/10.1016/B978-0-12-801238-3.99893-3
- Reich, U., Mueller, P. P., Fadeeva, E., Chichkov, B. N., Stoever, T., Fabian, T., Lenarz, T., & Reuter, G. (2008). Differential fine-tuning of cochlear implant material-cell interactions by femtosecond laser microstructuring. Journal of Biomedical Materials Research - Part B Applied Biomaterials, 87(1), 146–153. https://doi.org/10.1002/jbm.b.31084
- Rodger, D. C., Fong, A. J., Li, W., Ameri, H., Ahuja, A. K., Gutierrez, C., Lavrov, I., Zhong, H., Menon, P. R., Meng, E., Burdick, J. W., Roy, R. R., Edgerton, V. R., Weiland, J. D., Humayun, M. S., & Tai, Y. C. (2008). Flexible parylene-based multielectrode array technology for high-density neural stimulation and recording. Sensors and Actuators, B: Chemical, 132(2), 449–460. https://doi.org/10.1016/j.snb.2007.10.069
- Rubehn, B., & Stieglitz, T. (2010). In vitro evaluation of the long-term stability of polyimide as a material for neural implants. Biomaterials, 31(13), 3449–3458. https://doi.org/10.1016/j.biomaterials.2010.01.053
- Salari, A., & Dalton, C. (2020). Editorial on the special issue on microelectrode arrays and application to medical devices. Micromachines, 11(8). MDPI AG. https://doi.org/10.3390/MI11080776
- Scanziani, M., & Häusser, M. (2009). Electrophysiology in the age of light. Nature, 461( 7266), 930-939. https://doi.org/10.1038/nature08540
- Sohal, H. S., Clowry, G. J., Jackson, A., O’Neill, A., & Baker, S. N. (2016). Mechanical flexibility reduces the foreign body response to long-term implanted microelectrodes in rabbit cortex. PLoS ONE, 11(10). https://doi.org/10.1371/journal.pone.0165606
- Song, X., Meeusen, W., Reynaerts, D., & van Brussel, H. (25 August 2000). Experimental Study of Micro-EDM Machining Performances on Silicon Wafer. Proc. SPIE 4174, Micromachining and microfabrication Process Technology VI. http://proceedings.spiedigitallibrary.org/
- Spira, M. E., & Hai, A. (2013). Multi-electrode array technologies for neuroscience and cardiology. Nature Nanotechnology, 8(2), 83-94. Nature Publishing Group. https://doi.org/10.1038/nnano.2012.265
- Stieglitz, T. (2016). Development of a polymer based neural probe.
- Szostak, K. M., Grand, L., & Constandinou, T. G. (2017). Neural interfaces for intracortical recording: Requirements, fabrication methods, and characteristics. In Frontiers in Neuroscience (Vol. 11, Issue DEC). Frontiers Media S.A. https://doi.org/10.3389/fnins.2017.00665
- Ward, M. P., Rajdev, P., Ellison, C., & Irazoqui, P. P. (2009). Toward a comparison of microelectrodes for acute and chronic recordings. Brain Research, 1282, 183–200. https://doi.org/10.1016/j.brainres.2009.05.052
- Williams, D. F. (2008). On the mechanisms of biocompatibility. Biomaterials, 29(20), 2941–2953.https://doi.org/10.1016/j.biomaterials.2008.04.023
- Zhang, E. N., Clément, J. P., Alameri, A., Ng, A., Kennedy, T. E., & Juncker, D. (2021). Mechanically Matched Silicone Brain Implants Reduce Brain Foreign Body Response. Advanced Materials Technologies, 6(3). https://doi.org/10.1002/admt.202000909