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Journals / Journaux
  1. Ghodsevali, E., Morneau-Gamache, S., Mathault, J., Landari, H., Boisselier, É., Boukadoum, M., Gosselin, B. and Miled, A., 2017. Miniaturized FDDA and CMOS Based Potentiostat for Bio-Applications. Sensors17(4), p.810.
  2. Villette, V., Levesque, M., Miled, A., Gosselin, B. and Topolnik, L., 2017. Simple platform for chronic imaging of hippocampal activity during spontaneous behaviour in an awake mouseScientific Reports7.
  3. Kara, A., Rouillard, C., Mathault, J., Boisvert, M., Tessier, F., Landari, H., Melki, I., Laprise-Pelletier, M., Boisselier, E., Fortin, M.A. and Boilard, E., 2016. Towards a multifunctional electrochemical sensing and niosome generation lab-on-chip platform based on a plug-and-play concept. Sensors16(6), p.778.
  4. Kara, A., Reitz, A., Mathault, J., Mehou-Loko, S., Amirdehi, M.A., Miled, A. and Greener, J., 2016. Electrochemical imaging for microfluidics: A full-system approach. Lab on a Chip16(6), pp.1081-1087.
  5. Miled, A., Auclair, B., Srasra, A. and Sawan, M., 2015. Reconfigurable prototyping microfluidic platform for DEP manipulation and capacitive sensing. IEEE transactions on biomedical circuits and systems9(2), pp.155-165.
  6. Facchin, S., Miled, M.A. and Sawan, M., 2015. In-Channel Constriction Valve for Cerebrospinal Fluid Sampling. IEEE Transactions on Magnetics51(3), pp.1-4.
  7. Miled, M.A.; Sawan, M.; HighThroughput Microfluidic Rapid Prototyping Packaging Methods for DEP manipulations, the Journal of Visualized Experiments, Vo 82, 2014.
  8. Miled, M.A., Gagne, A. and Sawan, M., 2013. Hybrid modeling method for a DEP based particle manipulation. Sensors13(2), pp.1730-1753.
  9. Miled, M.A., Massicotte, G. and Sawan, M., 2012. Low-voltage lab-on-chip for micro and nanoparticles manipulation and detection: Experimental results. Analog Integrated Circuits and Signal Processing73(3), pp.707-717.
  10. Miled, M.A. and Sawan, M., 2012. Dielectrophoresis-based integrated lab-on-chip for nano and micro-particles manipulation and capacitive detection. IEEE transactions on biomedical circuits and systems6(2), pp.120-132.
  11. Miled, M.A., Sawan, M. and Ghafar-Zadeh, E., 2009. A Dynamic Decoder for First-Order Sigma\Delta Modulators Dedicated to Lab-on-Chip Applications. IEEE Transactions on Signal Processing57(10), pp.4076-4084.
  12. Ghafar-Zadeh, E.; Sawan, M.; Therriault, D.; Miled, M.A.; Laboratoires-sur-puce une nouvelle technologie de diagnostic cellulaire et moléculaire, IEEE Canadian magasine, No.58, Sum. 2008.

Patents / Brevets

  1. Miled, M.A. ; Sawan, M; "Reconfigurable Modular Microfluidic System and Method", Publication number WO2012155266 A1

Conferences / Conférences

  1. Mathault, J., Landari, H., Tessier, F., Fortier, P., Miled, A., 2017 August. Biological Modeling Challenges in a Multiphysics Approach (Accepted MWSCAS).
  2. Mathault, J., Grenier, D., Miled, A., 2017 June .Counter/Reference-Based Potentiostat Architecture Analysis and Comparison (Accepted NEWCAS).
  3. Mathault, J., Morneau-Gamache, S., Ghodsevali, E., Landari, H., Boukadoum, M., Boisselier, E., Miled, A., 2017, June. Toward a New High-Throughput Electrochemical Imaging System for Dissolved BiomaterialsInternational Conference on Analytical Sciences and Spectroscopy; Halifax, NS, Canada, May 2015.
  4. Kisomi, A.A., Landari, H., Boukadoum, M., Miled, A. and Gosselin, B., 2016, August. Towards a multi-wavelength spectroscopy platform for blood characterization and analysis. In Engineering in Medicine and Biology Society (EMBC), 2016 IEEE 38th Annual International Conference of the (pp. 2994-2997). IEEE.
  5. Tessier, F., Laprise-Pelletier, M., Boilard, É., Fortin, M.A. and Miled, A., 2016, August. Automated and reconfigurable platform for niosome generation based on a microfluidic architecture. In Engineering in Medicine and Biology Society (EMBC), 2016 IEEE 38th Annual International Conference of the (pp. 2998-3001). IEEE.
  6. Ghodsevali, E., Landari, H., Boukadoum, M., Gosselin, B. and Miled, A., 2016, August. A wide range and high sensitivity four-channel compact electrochemical biosensor for neurotransmitter detection on a microfluidic platform. In Engineering in Medicine and Biology Society (EMBC), 2016 IEEE 38th Annual International Conference of the (pp. 5753-5756). IEEE.
  7. Ghodsevali, E., Boukadoum, M., Gosselin, B. and Miled, A., 2016, June. Low-power and low-noise fully differential difference amplifier for sub-nanoampere on-chip potentiostat. In New Circuits and Systems Conference (NEWCAS), 2016 14th IEEE International (pp. 1-4). IEEE.
  8. AvakhKisomi, A., Miled, A., Boukadoum, M., Morissette, M., Lellouche, F. and Gosselin, B., 2016, May. A novel wireless ring-shaped multi-site pulse oximeter. In Circuits and Systems (ISCAS), 2016 IEEE International Symposium on (pp. 2451-2454). IEEE.
  9. Kara, A., Mathault, J., Reitz, A., Boisvert, M., Tessier, F., Greener, J. and Miled, A., 2016, March. Microfluidic in-channel multi-electrode platform for neurotransmitter sensing. In Proc. of SPIE Vol (Vol. 9705, pp. 97050X-1).
  10. Kara, A., Miled, A. and Greener, J., 2015, December. Automated electrode array for in-channel electrochemical detection. In Electronics, Circuits, and Systems (ICECS), 2015 IEEE International Conference on (pp. 213-216). IEEE.
  11. Ghodsevali, E., Gosselin, B., Boukadoum, M. and Miled, A., 2015, October. High accuracy and sensitivity differential potentiostat with amplifier-based error cancellation feedback loop. In Biomedical Circuits and Systems Conference (BioCAS), 2015 IEEE (pp. 1-4). IEEE.
  12. Mathault, J., Zamprogno, P., Greener, J. and Miled, A., 2015, August. Microfluidic platform for neurotransmitter sensing based on cyclic voltammetry and dielectrophoresis for in vitro experiments. In Engineering in Medicine and Biology Society (EMBC), 2015 37th Annual International Conference of the IEEE (pp. 2171-2174). IEEE.
  13. Kara, A; Mathault, J; Greener, J; Miled, A; Electrochemical Imaging in Microchannels98th Canadian Chemistry Conference and Exhibition; Ottawa, ON, Canada, Jun. 2015.
  14. Kara, A; Mathault, J; Greener, J; Miled, A; Toward a New High-Throughput Electrochemical Imaging System for Dissolved BiomaterialsInternational Conference on Analytical Sciences and Spectroscopy; Halifax, NS, Canada, May 2015.
  15. Mathault, J., Gosselin, B. and Miled, A., 2015, May. 4V microfluidic platform for biological manipulation with glycine, glutamate, GABA and acetylcholine. In Electrical and Computer Engineering (CCECE), 2015 IEEE 28th Canadian Conference on (pp. 180-183). IEEE.
  16. Mathault, J; Gosselin, B; Miled, A; DEP based Digital Microfluidic Platform for L-glutamic acid, Glycine,Y-aminobutyric and Acetylcholine Chloride Neurotransmitter Manipulations, BRAIN grand challenges Conference, Washington, USA, Nov. 2014
  17. Miled, A; Zamprogno, P; Greener, J; Design and Characterization of a Microfluidic System for Dopamine Disorder Using Cyclic voltammetryBRAIN grand challenges Conference, Washington, USA, Nov. 2014
  18. Miled, A., 2014, August. Thermal effect of dielectrophoresis manipulation on cerebrospinal fluid. In Engineering in Medicine and Biology Society (EMBC), 2014 36th Annual International Conference of the IEEE (pp. 6187-6190). IEEE.
  19. Facchin, S; Sawan, M; Miled, A., In-Channel Droplet-Based Micro-Sampling technique for Lab-on-Chip, IEEE Conference on Electromagnetic Field Computation, May. 2014.
  20. Bouali, M; Miled, M.A; Sawan, M.; An On-Chip Low-Voltage and Programmable Power Supply System For a Modular Lab-on-a-ChipIEEE International Symposium on Bioelectronics and Bioinformatics, Apr. 2014.
  21. Miled, A. and Sawan, M., 2014, June. Reconfigurable lab-on-chip platform for algae cell manipulation. In Circuits and Systems (ISCAS), 2014 IEEE International Symposium on (pp. 646-649). IEEE.
  22. Xing, P., Miled, M.A. and Sawan, M., 2013, November. Glutamate, GABA and dopamine hydrochloride concentration effects on the conductivity and impedance of cerebrospinal fluid. In Neural Engineering (NER), 2013 6th International IEEE/EMBS Conference on (pp. 1037-1040). IEEE.
  23. Miled, M.A; Sawan, M., A 0.18 um CMOS Reconfigurable 8 x 8 Microelectrode Array Dedicated for LoC Applications. IEEE NEWCAS 2013
  24. Miled, M.A. and Sawan, M., 2013, July. Low-voltage DEP microsystem for submicron particle manipulation in artificial cerebrospinal fluid. In Engineering in Medicine and Biology Society (EMBC), 2013 35th Annual International Conference of the IEEE (pp. 1611-1614). IEEE. 
  25. Miled, M.A. and Sawan, M., 2012, August. Electrode robustness in artificial cerebrospinal fluid for dielectrophoresis-based LoC. In Engineering in Medicine and Biology Society (EMBC), 2012 Annual International Conference of the IEEE (pp. 1390-1393). IEEE.
  26. Miled, M.A.; Sawan, M., Wireless Fully Integrated LoC for DEP Based Cell Manipulation and Capacitive Sensing, CMC Texpo, 2012.
  27. Miled, M.A., Gagne, A. and Sawan, M., 2011, May. Electrodes architectures for dielectrophoretic-based cells manipulation in locs: Modeling, simulation and experimental results. In Mixed-Signals, Sensors and Systems Test Workshop (IMS3TW), 2011 IEEE 17th International (pp. 39-42). IEEE.
  28. Gagne, A., Miled, M.A. and Sawan, M., 2011, May. An improved multiphysics modelling approach for dielectrophoresis-based cell separation. In Electrical and Computer Engineering (CCECE), 2011 24th Canadian Conference on(pp. 001387-001390). IEEE.
  29. Miled, M.A.; Sawan, M., Étude, modélisation et validation des microélectrodes pour des structures Lab sur puce, ACFAS, 2011.
  30. Miled, M.A.; Sawan, M., Capteur implantable basé sur LSP dédié à la détection cellulaire par diélectrophorèse, Fetch, 2011.
  31. Miled, M.A., El-Achkar, C.M. and Sawan, M., 2010, June. Low-voltage dielectrophoretic platform for lab-on-chip biosensing applications. In NEWCAS Conference (NEWCAS), 2010 8th IEEE International (pp. 389-392). IEEE.
  32. Miled, M.A.; Sawan, M., High-Accuracy Cells Detection Based on Capacitive Measurement on Top of Novel L-Shaped Electrodes in Microfluidic Channel, IEEE sensors (accepted), Hawaii, 2010.
  33. Sawan, M., Miled, M.A. and Ghafar-Zadeh, E., 2010, August. Cmos/microfluidic lab-on-chip for cells-based diagnostic tools. In Engineering in Medicine and Biology Society (EMBC), 2010 Annual International Conference of the IEEE (pp. 5334-5337). IEEE.
  34. Miled, M.A.; Sawan, M., LoC Dielectrophoresis - Based Implantable Device Dedicated for Cells Manipulation and Detection, CMC Texpo, 2010.
  35. Miled, M.A. and Sawan, M., 2011, May. A new fully integrated cmos interface for a dielectrophoretic lab-on-a-chip device. In Circuits and Systems (ISCAS), 2011 IEEE International Symposium on (pp. 2349-2352). IEEE.
  36. Miled, M.A. and Sawan, M., 2010, August. A new CMOS/microfluidic interface for cells manipulation and separation in LoC devices. In Quality Electronic Design (ASQED), 2010 2nd Asia Symposium on (pp. 194-197). IEEE.
  37. Miled, M.A. and Sawan, M., 2009, June. Reconfigurable dielectrophoretic device for neurotransmitters sensing and manipulation. In Mixed-Signals, Sensors, and Systems Test Workshop, 2009. IMS3TW'09. IEEE 15th International (pp. 1-4). IEEE.
  38. Miled, M.A.; Sawan, M., Implantable Microsystems Dedicated for Neural Cells Separation and Detection, NAMIS 2008, Automn School, Tokyo, Japan Sept-Oct. 2008.
  39. Miled, M.A. and Sawan, M., 2008, May. Subthreshold transistor operation for a high sensitivity capacitive sensor. In Electrical and Computer Engineering, 2008. CCECE 2008. Canadian Conference on (pp. 001671-001674). IEEE.
  40. Miled, M.A., Ghafar-Zadeh, E. and Sawan, M., 2007, August. Fast decoding algorithm for first order dc-input sigma-delta modulators. In Circuits and Systems, 2007. MWSCAS 2007. 50th Midwest Symposium on (pp. 1380-1383). IEEE.
  41. Ghafar-Zadeh, E., Sawan, M., Hajj-Hassan, M. and Miled, M.A., 2007, August. A CMOS based microfluidic detector: Design, calibration and experimental results. In Circuits and Systems, 2007. MWSCAS 2007. 50th Midwest Symposium on (pp. 193-196). IEEE.

Application Notes / Notes d'applications

  1. Miled, M.A.; Sawan, M., Interconnecting Microtubes in Microfluidic ApplicationsCMC, 2012
  2. Miled, M.A.; Sawan, M.A Novel Multi-electrical Channel Manipulation and Detection Platform for Microfluidic Applications, CMC, 2012.
  3. Miled, M.A.; Sawan, M.Removable PDMS-based Interconnector for Low-pressure Microfluidic Applications, CMC, 2012.
  4. Miled, M.A.; Sawan, M.An Assembly Technique for Reusable Microfluidic Chips with Electrical Interface, CMC, 2012.

Invited talks / Conférence "invité"
  1. La "micro-fluidotronique": une fusion entre la microfluidique et la microélectronique pour une nouvelle génération de biocapteurs, CERMA, Research Centre for Advanced Materials, Université Laval, Québec City, QC, Canada, Mar. 2017.
  2. Toward Plug-and-Play Lab-on-Chip as a Versatile Sensors and Actuator for Bio- applications - Case of study: Electrochemical Imaging and Drug Delivery, North American Tunisan Engineer Group, Tunisia, Aug. 2016.
  3. Integrated Micro-Systems Based on Heteregenuous Technologies to Boost Research and Discoveries in Neuroscience:  Case of Microfluidics and Microelectronics Integration to Detect Neurotransmitter ActivityCRIUSMQ University Institute in Mental Health of Quebec Québec City, QC, Canada, Jan. 201715 Jan 2016.
  4. L’intégration de la microfluidique modulaire et la microélectronique/électronique pour les bio-applications, Université du Québec à Montréal (UQAM), Montréal, QC, Canada, Nov. 2015.
  5. Integrated Biosensors for Neuroscience: New Bioengineering Research Challenges, North American Tunisan Engineer Group, Tunisia, Aug. 2015.
  6. Lab-on-chip for Neurotransmitter Sensing: Advantages, Limitations and Challenges, University of Toronto, Toronto, ON, Canada, Nov. 2014.
  7. Toward Automated Lab-on-Chip for Brain Monitoring Major Advances and Challenges, York University, Toronto, ON, Canada, Nov. 2014.
  8. 3D Heterogeneous Microsystem Integration For Biomedical Applications: A Major Step Toward Fully Autonomous Lab-on-Chip, IEEE Santa Clara Valley(SCV) Section’s  Professional Activities Committee for Engineers (PACE), Santa Clara, CA, USA, Nov. 2013.