Exemplary embodiments provide systems, devices and methods for simultaneously measuring mechanical and electrophysiological tissue responses (e.g., contractile function, or the like).

A method of measuring a stress-strain curve in a cell-cell adhesion interface, the method including: providing a structure including a first movable island supported by a first beam, a second movable island supported by a second beam, and a gap therebetween connected by a pair of cells forming a junction, the pair of cells comprising a cell-cell adhesion interface having an initial length defined by a distance between nuclei of the pair of cells; moving the second movable island with a defined displacement; determining a displacement of the first movable island based on moving the second movable island; calculating a difference between the displacement of the first movable island and the defined displacement of the second movable island based on moving the second movable island; determining an applied strain in the cell-cell adhesion interface between the pair of cells based on the difference divided by the initial length of the cell-cell adhesion interface; calculating a force between the cell-cell adhesion interface of the pair of cells based on the displacement of the first movable island; calculating a stress in the cell-cell adhesion interface between the pair of cells based on the force; and determining the stress-strain curve of the cell-cell adhesion interface between the pair of cells by plotting the calculated stress against the applied strain.

A method for testing the rigidity of a particular disposable for volumetric balancing, for a blood treatment device. The method includes filling the disposable or portion thereof with a liquid, enclosing the filled liquid, so that a certain volume of liquid is present in the disposable unit or the portion thereof, supplying and/or discharging a certain volume of liquid, and measuring the change in pressure caused by the supply and/or discharge of the volume of liquid. A blood treatment device is also provided.

An apparatus for measuring a characteristic of a sample using a centrifuge and optical components is disclosed. The centrifuge may be a standard benchtop centrifuge. The optical components may be sized and dimensioned to fit, along with the sample, inside the centrifuge.

A method using variable bead-oscillation-based stress parameters, including relative bead dimensionality or other structural features as well as stress duration or intensity or overall magnitude, in inducing different shear stresses in biological samples, for testing the effects of different combinations of various defined stress conditions.

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.

The present invention is directed to intelligent algorithms, methodologies and computer-implemented methodologies for biophysical and biochemical cellular monitoring and quantification enabling enhanced performance and objective analysis of advanced infectivity assays including neutralization assays and adventitious agent testing using fluidic and optical force-based measurements.

A system for applying and measuring tensions of a plurality of bio-object constructs includes a base; and a flexible body disposed on the base, wherein the flexible body defines a plurality of construct holes for accommodating the plurality of bio-object constructs, such that when the flexible body is bent, the bending of the flexible body causes tensions to be applied to the plurality of bio-object constructs, thereby causing displacements of the plurality of bio-object constructs.

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{umlaut over (.Math.)} blood or plasma over an hour period. The viscosity measurements may be displayed and transmitted to the Internet or cloud storage.

A system for applying and measuring tensions of a plurality of bio-object constructs includes a base; and a flexible body disposed on the base, wherein the flexible body defines a plurality of construct holes for accommodating the plurality of bio-object constructs, such that when the flexible body is bent, the bending of the flexible body causes tensions to be applied to the plurality of bio-object constructs, thereby causing displacements of the plurality of bio-object constructs.