There is provided a method of detecting a change of a state of a liquid comprising the steps of: providing a liquid detection medium (12) comprising a liquid and having a plurality of anisotropic magnetic particles suspended therein; applying a modulated magnetic field across at least a portion of the liquid detection medium (12), wherein the magnetic field induces an alignment of the magnetic particles; introducing electromagnetic radiation (22) into the liquid detection medium (12); detecting a variable which is modulated by the applied magnetic field, wherein the variable is associated with the interaction of the electromagnetic radiation (22) with the magnetic particles and wherein the change in the state of the liquid causes a variation in the detected variable; and correlating the variation in the detected variable with the change in the state of the liquid.

A system and method is provided for measuring a mechanical property of a biological tube. The system and method operate to arrange a plurality of piezoelectric elements about the biological tube and apply a predetermined force or transduce an endogeneous or exogeneous force to the biological tube. The system and method also operate to receive a respective signal from each piezoelectric element in the plurality of piezoelectric elements responsive to the application of the predetermined force or a transduced endogenous or exogeneous force and calculate the mechanical property of the biological tube based on the signals received from the plurality of piezoelectric elements.

A device for measuring a tension of a bio-object construct as it is being stretched that includes a microscope, a holding member for accommodating the bio-object, and a probe. The microscope includes a condenser, an objective and a stage positioned therebetween. The stage is movable along a horizontal plane. The holding member is fixable on the stage. The probe has a first end attached to the condenser, and a second end placed in the holding member. The stage operably moves such that the bio-object construct moves toward the second end of the probe and contacts with the second end of the probe, thereby causing a displacement of the second end of the probe and a displacement of the bio-object construct, which are used to measure the tension of the bio-object construct.

Sensors employing bulk acoustic wave (BAW) resonators are used to assay characteristics of blood. The BAW sensors may be used to sense viscosity of a sample comprising blood to determine coagulation properties of the blood. The viscosity of the blood may be evaluated in the presence of agents that inhibit coagulation or that promote coagulation. The change in viscosity of the sample in the presence of such agents may provide information regarding whether the blood suffers from a coagulation disorder.

A device for assessing changes in erythrocyte deformability, such as erythrocyte sickling tendency in a controlled hypoxic atmosphere, comprising: an at least partially transparent inner wall, an at least partially transparent outer wall extending parallel with the inner wall, wherein a gap is present between the inner and outer walls for receiving a blood sample, wherein one of said walls is movable parallel to and relative to the other one of said walls so as to exert a shear force to the sample in the gap, a light source arranged to emit light in a perpendicular direction through overlapping transparent parts of the inner and outer walls, a camera arranged to observe the light from the light source after it is emitted through said transparent parts of the inner and outer walls in order to detect and assess a diffraction pattern therein when a blood sample is present in said gap and the movable wall is being moved, and an oxygen sensor arranged to be in contact with the blood sample in the gap between the inner and outer walls and to measure the oxygen concentration in the blood sample when the blood sample is present in said gap and the movable wall is being moved. The device is in particular useful for research and development in the field of sickle cell disease and the efficacy of medication and treatments.

An apparatus for determining blood clotting capacity comprises an actuator to cyclically move a member within a sample of blood received in a well in a tray and one of a deflection sensor and a position sensor to determine the position of the wetted member upon being acted upon by the actuator. The theoretical position of the wetted member, as determined using a known actuator force and wetted member physical data, is compared to the sensed deflection or position of the wetted member, and the resistance to movement of the wetted member caused by the blood is determined and correlated to a clotting capacity.

Disclosed is a system and method for determination of the viscoelastic properties of a viscoelastic substance based on the type of non-mechanical forces which drive the viscoelastic substance inside a channel. These forces may comprise capillary, gravitational, electric, magnetic, or any other type where neither a pump nor any relative velocity between solid surfaces is needed to induce the transport of fluid medium. As a result, the design of the system remains simple, and the system is capable of yielding results devoid of noise produced by mechanical forcing. The present disclosure a general analysis describing extraction of viscoelastic properties by observing flow-systems driven by any non-mechanical means, including capillary force and electro-osmotic force. Such time-dependent penetration depth may be recorded by optical, electrical or mechanical means and may further include the use of a computing device.

Disclosed is a device for mechanically characterizing an element of interest, for example an oocyte. The mechanical characterization device includes: a support receiving a container suitable for containing a liquid medium; a holder for holding the element of interest; an indenting member; a magnet for generating a magnetic field in which the indenting member is intended to move and which participates in suspending the indenting member with an unstable horizontal direction oriented coaxially to the longitudinal axis; a controller to control the magnet to maneuver the indenting member in translation along the unstable horizontal direction; and a component for determining the mechanical characteristics of the element of interest.

This determination method comprises the steps consisting of providing a reaction vessel (2) containing a blood sample (33) and a ferromagnetic ball (11) placed on a raceway (9) provided in the bottom of the reaction vessel (2), subjecting the ball (11) to a magnetic field so as to move the ball along the raceway (9) in an oscillatory motion, exposing the blood sample to an incident light beam (36), detecting a light beam (38) transmitted through the reaction vessel (2) and coming from the incident light beam (36) in such a way as to provide a measurement signal, carrying out a first processing of the measurement signal in such a way as to provide a first signal representative of the variation of at least one physical quantity representative of the movement of the ball (11), carrying out a second processing of the measurement signal in such a way as to provide a second signal representative of the variation of at least one optical property of the blood sample, determining a first value of the coagulation time of the blood sample from the first signal, and determining a second value of the coagulation time of the blood sample from the second signal.

A droplet-based microfluidic rheometer system and method of use for real-time viscosity monitoring of blood coagulation is disclosed. Droplets of blood samples are generated in a microfluidic rheometer, and the size of the droplets is highly correlated to the sample viscosity. The size of the droplets can be determined optically using an inverted light microscope and a camera or using electrodes. The microfluidic rheometer systems provides viscosity measurements in less than a second and consumes less than 1 l blood or plasma over an hour period. The viscosity measurements may be displayed and transmitted to the Internet or cloud storage.