Improved resolution and detection of nanoparticles are achieved when a nanopore connecting liquid compartments in a device running on the Coulter principle is provided with fluid coatings such as lipid walls. Fluid lipid walls are made of a lipid bilayer, and preferably include lipid anchored mobile ligands as part of the lipid bilayer. By varying the nature and concentration of the mobile ligand in the lipid bilayer, multifunctional coatings of lipids are provided.

In the particle analyzing apparatus of the present invention, first, an inner space with a negative pressure having a predetermined volume is formed in the cylinder of a syringe device for sucking a sample liquid in the measuring chamber, then, the negative pressure is applied to the measuring chamber, the sample liquid is sucked, and measurement of particle is performed in the measuring flow path. The control device calculates a particle analysis value from the measurement signal obtained by the measurement. The particle analysis value is obtained by the sucking force of the negative pressure and the control device further corrects the particle analysis value based on a standard pressure predetermined for the inner space.

A portable, stand-alone microfluidic interrogation device including a microprocessor and a touch-screen display. The touch-screen display can receive one or more user input to select a particular particle interrogation procedure, and subsequently show interrogation results. A microfluidic path extending through the interrogation device includes alignment structure that defines an interrogation zone in which particles carried in a fluid are urged toward single-file travel. Operable alignment structure may define sheath-, or non-sheath fluid flow. Desirably, a portion of the alignment structure is removable from the device in a tool-free procedure. The device may operate under the Coulter principle, and/or detect Stokes' shift phenomena, and/or other optically-based signal(s).

Microfluidic impedance based lab on chip is a sensor module to measure the impedance of a single biological cell flowing in channel of micrometer size. In the present invention, the enhancement in the channel cross-section 30 micron [h]45 micron [w] leads to reduce the pressure drop significantly i.e., around 40 kPa at 100 microliter/min, which demands by cartridge based micro-pump for portable devices at Point of Care (PoC) location. Lab on chip of present invention is capable of withstanding 20 Vpp for several hours without degradation of electrodes and also capable to measure the particle with dimension down to 2 microns. Lab on chip of present invention was also used to count the platelet of the diluted blood samples without any pretreatment and comparable to the clinical lab report.

A portable, stand-alone microfluidic interrogation device including a microprocessor and a touch-screen display. The touch-screen display can receive one or more user input to select a particular particle interrogation procedure, and subsequently show interrogation results. A microfluidic path extending through the interrogation device includes alignment structure that defines an interrogation zone in which particles carried in a fluid are urged toward single-file travel. Operable alignment structure may define sheath-, or non-sheath fluid flow. Desirably, a portion of the alignment structure is removable from the device in a tool-free procedure. The device may operate under the Coulter principle, and/or detect Stokes' shift phenomena, and/or other optically-based signal(s).

The present invention reports a novel microfluidic analyzer for the high-throughput, label-free measurement of particles suspended in a fluid. The present invention employs the resistive pulse technique (RPT) which affords very high electrical bandwidth for the device, which surpasses that of currently available systems and devices. Further, devices in accordance with the present invention are fabricated with very simple microfabrication technologies, making the present invention more cost efficient and easier to manufacture than currently available devices.

A method of forming a plurality of lipid bilayers over an array of cells in a nanopore based sequencing chip is disclosed. Each of the cells comprises a well. A first salt buffer solution with a first osmolarity is flowed over a cell in the nanopore based sequencing chip to substantially fill a well in the cell with the first salt buffer solution. A lipid and solvent mixture is flowed over the cell to deposit a lipid membrane over the well that encloses the first salt buffer solution in the well. A second salt buffer solution with a second osmolarity is flowed above the well to reduce the thickness of the lipid membrane, wherein the second osmolarity is a lower osmolarity than the first osmolarity such that an osmotic imbalance is created between a first volume inside the well and a second volume outside the well.

When using an immunological analysis method wherein antigen-antibody reactions are used to form complexes of microparticles and a substance being measured, purifying, then measuring by spectroscopy, and a mass spectrometry method wherein antigen-antibody reactions are used to form complexes of microparticles and a substance being measured, purifying, then measuring with a mass spectrometer, the amount of the complex flowing in the flow path for immunological analysis and the amount of the complex flowing in the flow path for mass spectrometry are unknown, so the substance being measured cannot be accurately quantified even when merging information obtained from immunological analysis and information obtained from mass spectrometry. The invention provides a mechanism for quantifying the complexes after formation of the complexes, on the flow path for mass spectrometry and the flow path for immunological analysis.

This flow cytometry system comprises a measuring chamber (11), an injection device (12) arranged to inject a flow of biological particles to be analyzed in the measuring chamber (11), an evacuation device (13) arranged to evacuate outside of the cytometry system the flow of biological particles injected in the measuring chamber (11), a measuring set arranged to measure at least one optical property of the biological particles to be analyzed, the measuring set including an emission device (42) arranged to emit a light beam in the direction of the measuring chamber (11) and capable of crossing the flow of biological particles, and at least one collecting device (43a) arranged to collect light rays coming from the measuring chamber (11). The flow cytometry system further comprises a support (6) on which the injection device (12), the evacuation device (13), the emission device (42) and the at least one collecting device (43a) are mounted.

According to one embodiment, a particle inspection system includes a voltage driving circuit which applies a driving voltage for a particle inspection to a particle inspection chip, a current-voltage conversion circuit which converts, into a voltage signal, a current signal output from the particle inspection chip when the driving voltage is applied to the particle inspection chip, a detection circuit which detects, based on the voltage signal, whether the sample liquid is introduced into a detection region of the particle inspection chip, and an analysis circuit which analyzes the fine particle, in the sample liquid based on the voltage signal. The voltage driving circuit varies the driving voltage based on the detection result of the detection circuit.