Flow metering characterization within an electrical cell counting microfluidic device

Hassan, Umer; Watkins, Nicholas N.; Edwards, Chelsea E. R.; Bashir, Rashid

doi:10.1039/c3lc51278a

Cited by 47 publications

(35 citation statements)

References 15 publications

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“…However, the translation of their optical device to a portable system will have illumination non-uniformity and higher noise issues that they also mentioned in their article 17 . In our previous studies, we have also characterized in detail our microfluidic impedance sensors to count CD4 and CD8 T cells for HIV diagnostics using a differential capture technique 18,19 . We have also characterized the coincidence effects in our counter 20 and performed a detailed mathematical characterization of the electrical cell counting process 21 .…”

Section: Introductionmentioning

confidence: 99%

A microfluidic biochip for complete blood cell counts at the point-of-care

et al. 2015

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Complete blood cell counts (CBCs) are one of the most commonly ordered and informative blood tests in hospitals. The results from a CBC, which typically include white blood cell (WBC) counts with differentials, red blood cell (RBC) counts, platelet counts and hemoglobin measurements, can have implications for the diagnosis and screening of hundreds of diseases and treatments. Bulky and expensive hematology analyzers are currently used as a gold standard for acquiring CBCs. For nearly all CBCs performed today, the patient must travel to either a hospital with a large laboratory or to a centralized lab testing facility. There is a tremendous need for an automated, portable point-of-care blood cell counter that could yield results in a matter of minutes from a drop of blood without any trained professionals to operate the instrument. We have developed microfluidic biochips capable of a partial CBC using only a drop of whole blood. Total leukocyte and their 3-part differential count are obtained from 10 μL of blood after on-chip lysing of the RBCs and counting of the leukocytes electrically using microfabricated platinum electrodes. For RBCs and platelets, 1 μL of whole blood is diluted with PBS on-chip and the cells are counted electrically. The total time for measurement is under 20 minutes. We demonstrate a high correlation of blood cell counts compared to results acquired with a commercial hematology analyzer. This technology could potentially have tremendous applications in hospitals at the bedside, private clinics, retail clinics and the developing world.

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Section: Introductionmentioning

confidence: 99%

A microfluidic biochip for complete blood cell counts at the point-of-care

et al. 2015

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“…Over the past years, the drawbacks of conventional flow cytometers have encouraged efforts to take advantage of microfabrication technologies and advanced microfluidics to achieve smaller, simpler, more innovative and low-cost instrumentation with enhanced portability for on-site measurements. This miniaturization approach has in general made use of inexpensive polymers such as polydimethylsiloxane (PDMS) [18] and detection techniques easily integrated with electronics [19], such as optical fibers [20], CCD cameras [21], diode lasers [22,23], PIN photodiodes [24], electrodes [25] and magnetoresistive sensors [26]. Approaches such as label-free electrical impedance-based ones [27,28], while quantitative and high throughput, present high sensitivity to the sample matrix, being affected by components in the sample other than the target, specifically their charges, which greatly hinders these devices' use in off-laboratory locations.…”

Section: Introductionmentioning

confidence: 99%

Lab-on-Chip Cytometry Based on Magnetoresistive Sensors for Bacteria Detection in Milk

Fernandes

Duarte

Cardoso

et al. 2014

Sensors

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Flow cytometers have been optimized for use in portable platforms, where cell separation, identification and counting can be achieved in a compact and modular format. This feature can be combined with magnetic detection, where magnetoresistive sensors can be integrated within microfluidic channels to detect magnetically labelled cells. This work describes a platform for in-flow detection of magnetically labelled cells with a magneto-resistive based cell cytometer. In particular, we present an example for the validation of the platform as a magnetic counter that identifies and quantifies Streptococcus agalactiae in milk.

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“…Our group has previously developed a microfluidic biochip capable of performing blood cell counts from a drop of whole blood without any manual processing26. The electrical sensors are designed to count individual cells using the coulter principle, where the passage of a cell perturbs the electrical current within an orifice, creating a distinct impedance pulse262728. The biochip has shown good correlations in clinical studies when its cell counts were compared to the cell counts from haematology analyzers.…”

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confidence: 99%

A point-of-care microfluidic biochip for quantification of CD64 expression from whole blood for sepsis stratification

et al. 2017

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Sepsis, a potentially life-threatening complication of an infection, has the highest burden of death and medical expenses in hospitals worldwide. Leukocyte count and CD64 expression on neutrophils (nCD64) are known to correlate strongly with improved sensitivity and specificity of sepsis diagnosis at its onset. A major challenge is the lack of a rapid and accurate point-of-care (PoC) device that can perform these measurements from a minute blood sample. Here, we report a PoC microfluidic biochip to enumerate leukocytes and quantify nCD64 levels from 10 μl of whole blood without any manual processing. Biochip measurements have shown excellent correlation with the results from flow cytometer. In clinical studies, we have used PoC biochip to monitor leukocyte counts and nCD64 levels from patients’ blood at different times of their stay in the hospital. Furthermore, we have shown the biochip’s utility for improved sepsis diagnosis by combining these measurements with electronic medical record (EMR).

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Flow metering characterization within an electrical cell counting microfluidic device

Cited by 47 publications

References 15 publications

A microfluidic biochip for complete blood cell counts at the point-of-care

A microfluidic biochip for complete blood cell counts at the point-of-care

Lab-on-Chip Cytometry Based on Magnetoresistive Sensors for Bacteria Detection in Milk

A point-of-care microfluidic biochip for quantification of CD64 expression from whole blood for sepsis stratification

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