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01675 am a22001693u 4500 |
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264155 |
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|a Sun, Tao
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|a Holmes, David
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|a Gawad, Shady
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|a Green, Nicolas G
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|a Morgan, Hywel
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|a High speed multi-frequency impedance analysis of single particles in a microfluidic cytometer using maximum length sequences
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|c 2007.
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|z Get fulltext
|u https://eprints.soton.ac.uk/264155/1/J41_Sun_Holmes_Gawad_Green_Morgan_Lab_On_A_Chip_2007.pdf
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|a A novel impedance spectroscopy technique has been developed for high speed single biological particle analysis. A microfluidic cytometer is used to measure the impedance of single micrometre sized latex particles at high speed across a range of frequencies. The setup uses a technique based on maximum length sequence (MLS) analysis, where the time-dependent response of the system is measured in the time domain and transformed into the impulse response using fast M-sequence transform (FMT). Finally fast Fourier transform (FFT) is applied to the impulse response to give the transfer-function of the system in the frequency domain. It is demonstrated that the MLS technique can give multi-frequency (broad-band) measurement in a short time period (ms). The impedance spectra of polystyrene micro-beads are measured at 512 evenly distributed frequencies over a range from 976.5625 Hz to 500 kHz. The spectral information for each bead is obtained in approximately 1 ms. Good agreement is shown between the MLS data and both circuit simulations and conventional AC single frequency measurements.
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