Investigation of Prothrombin Time in Human Whole-Blood Samples with a Quartz Crystal Biosensor

Müller, Lothar; Sinn, Stefan; Drechsel, Hartmut; Ziegler, Christiane; Wendel, Hans-Peter; Northoff, Hinnak; Gehring, Frank K.

doi:10.1021/ac9021117

Cited by 61 publications

(49 citation statements)

References 28 publications

(32 reference statements)

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“…This phenomenon provides a sensitive and convenient method for measuring the Tc values of clots. 17,19 Figure 4 plots a typical response curve of the ∆F 2 measured by the QCM during clot formation, which is similar to curves presented elsewhere. 17,21 Briefly, recalcified blood samples containing the various NPs were loaded onto a QCM sensor, which rapidly reduced its frequency, by approximately 4KHz, within approximately 30 seconds.…”

Section: Blood Tc Was Reduced By Hemostatic Nps Evaluated By Measurinsupporting

confidence: 58%

“…28 Interestingly, the ∆F 2 values obtained in this study were similar to those revealed by the oscillatory circuit in the QCM with dissipation monitoring (QCM-D) technique, which is used to detect mass deposition or changes in the viscosity of adjacent liquids or blood clots on quartz sensors. 17,19 Although the energy dissipation attributable to the differences in viscosity and density among the clot/PBS and others could not be evaluated by this QCM system, the SEM morphologies of the clots analyzed herein indicated the variation in ∆F 2 values among clots. The SEM morphologies in Figure 3 Figure 4D), according to the equation of Kanazawa and Gordon.…”

Section: Blood Tc Was Reduced By Hemostatic Nps Evaluated By Measurinmentioning

confidence: 83%

“…The QCM has demonstrated high sensitivity to small changes in mass, such as changes caused by the absorption of a protein on a surface or blood coagulation/clot formation, to which the oscillation frequency of the quartz in the device responds. [17][18][19][20][21] The oscillation frequency shifts (∆F 2 ) associated with the propagation of the fibrin network during the formation of clots were analyzed to determine how ANPs or FNPs affect blood clot structure. Compressional flow properties, including clot hardness and compressibility, were determined by texture profile analysis [22][23][24] using a micromechanical test system.…”

Section: Introductionmentioning

confidence: 99%

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Adenosine diphosphate-decorated chitosan nanoparticles shorten blood clotting times, influencing the structures and varying the mechanical properties of the clots

Chung

Lin

Wang

et al. 2014

IJN

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Chitosan nanoparticles (NPs) decorated with adenosine diphosphate (ADP) (ANPs) or fibrinogen (FNPs) were used to fabricate hemostatic NPs that can shorten blood clotting time and prevent severe local hemorrhage. The structure and mechanical properties of the blood clot induced with ANP (clot/ANP) or FNP (clot/FNP) were also investigated. The NPs, ANPs, and FNPs, which had particle sizes of 245.1±14.0, 251.0±9.8, and 326.5±14.5 nm and zeta potentials of 24.1±0.5, 20.6±1.9, and 15.3±1.5 mV (n=4), respectively, were fabricated by ionic gelation and then decorated with ADP and fibrinogen. The zeta potentials and Fourier transform infrared (FTIR) spectroscopy of the NPs confirmed that their surfaces were successfully coated with ADP and fibrinogen. The scanning electron microscope (SEM) micrographs of the structure of the clot induced with “undecorated” chitosan NPs (clot/NP), clot/ANP, and clot/FNP (at 0.05 wt%) were different, after citrated bloods had been recalcified by a calcium chloride solution containing NPs, ANPs, or FNPs. This indicated that many NPs adhered on the membrane surfaces of red blood cells, that ANPs induced many platelet aggregates, and that FNPs were incorporated into the fibrin network in the clots. Measurements of the blood clotting times (Tc) of blood clot/NPs, clot/ANPs, and clot/FNPs, based on 90% of ultimate frequency shifts measured on a quartz crystal microbalance (QCM), were significantly ( P <0.05) (n=4) shorter than that of a clot induced by a phosphate-buffered solution (PBS) (clot/PBS) (63.6%±3.1%, 48.3%±6.2%, and 63.2%±4.7%, respectively). The ΔF 2 values in the spectra of frequency shifts associated with the propagation of fibrin networks in the clot/ANPs and clot/FNPs were significantly lower than those of clot/PBS. Interestingly, texture profile analysis of the compressional properties showed significantly lower hardness and compressibility in clot/NPs and clot/ANPs ( P <0.05 or better) (n=4) compared with clot/PBS and clot/FNPs. Accordingly, among the hemostatic NPs, ANP substantially reduced blood clotting times, ΔF 2 values, and compression flow properties of the clot. Hence, ANPs have potential applications for preventing severe local hemorrhage.

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Section: Blood Tc Was Reduced By Hemostatic Nps Evaluated By Measurinsupporting

confidence: 58%

Section: Blood Tc Was Reduced By Hemostatic Nps Evaluated By Measurinmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 99%

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Adenosine diphosphate-decorated chitosan nanoparticles shorten blood clotting times, influencing the structures and varying the mechanical properties of the clots

Chung

Lin

Wang

et al. 2014

IJN

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“…Detailed information can be obtained from our previous studies on blood plasma viscosity 21,22 . During blood coagulation, a sudden change in the blood plasma viscosity occurs due to fibrin generation 13 . This kind of viscosity change creates an increase in the hydrodynamic loading of the vibrating structures in viscous liquids according to Sader's theory 27 .…”

Section: Characterization Of the Systemmentioning

confidence: 99%

A cartridge based sensor array platform for multiple coagulation measurements from plasma

et al. 2015

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ARTICLE This journal is © The Royal Society of Chemistry 2013Lab Chip, 2014, 00, 1-3 | 1 and Prothrombin Time (PT)). The system has a reader unit and a disposable cartridge. The reader has no electrical connections to the cartridge. This enables simple and low-cost cartridge designs and avoids reliability problems associated with the electrical connections. The cartridge consists of microfluidic channels and MEMS microcantilevers placed in each channel. Microcantilevers are made of electro-plated nickel. They are actuated remotely using an external electro-coil and the read-out is also conducted remotely by a laser. The phase difference between the cantilever oscillation and the coil drive is monitored in real-time. During coagulation, the viscosity of the blood plasma increases resulting in a change in phase read-out. The proposed assay was tested with human and control plasma samples for PT and aPTT measurements. PT and aPTT measurements with using control plasmas are comparable with manufacturer's data sheet and commercial reference device. The measurement system has an overall 7.28 % and 6.33 % CV for PT and aPTT, respectively. For further implementation, the microfluidic channels of the cartridge are functionalized for PT and aPTT tests by drying specific reagents in each channel. Since the simultaneous PT and aPTT measurements are needed in order to properly evaluate the coagulation system, one of the most prominent features of the proposed assay is the enabling parallel measurement of different coagulation parameters. Additionally, the design of the cartridge and the read out system, the obtained reproducible results with 10 µl plasma samples suggesting an opportunity of a possible Point-of -Care application.

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“…The researchers utilized microfluidic platforms [3], Quartz Crystal Microbalance (QCM) [4,5] Film Bulk Acoustic Resonator (FBAR) [6] based techniques for clot-time measurements. But they are limited to single tests and not multiplexed.…”

Section: Introductionmentioning

confidence: 99%

LoC sensor array platform for real-time coagulation measurements

Çakmak

Kılınç

Ermek

et al. 2014

2014 IEEE 27th International Conference on Micro Electro Mechanical Systems (MEMS)

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1This paper reports a MEMS-based sensor array enabling multiple clot-time tests in one disposable microfluidic cartridge using plasma. The versatile LoC (Lab-on-Chip) platform technology is demonstrated here for real-time coagulation tests (activated Partial Thrompoblastin Time (aPTT) and Prothrombin Time (PT)). The system has a reader unit and a disposable cartridge. The reader has no electrical connections to the cartridge, which consists of multiple microfluidic channels and MEMS microcantilevers placed in each channel. Microcantilevers are made of electro-plated nickel and actuated remotely using an external electro-coil. The read-out is also conducted remotely by a laser and the phase of the MEMS oscillator is monitored real-time. The system is capable of monitoring coagulation time with a precision estimated at 0.1sec.

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Investigation of Prothrombin Time in Human Whole-Blood Samples with a Quartz Crystal Biosensor

Cited by 61 publications

References 28 publications

Adenosine diphosphate-decorated chitosan nanoparticles shorten blood clotting times, influencing the structures and varying the mechanical properties of the clots

Adenosine diphosphate-decorated chitosan nanoparticles shorten blood clotting times, influencing the structures and varying the mechanical properties of the clots

A cartridge based sensor array platform for multiple coagulation measurements from plasma

LoC sensor array platform for real-time coagulation measurements

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