Single-Cell Sorting of Microorganisms by Flow or Slide-Based (Including Laser Scanning) Cytometry

Size-Dependent Filtration and Trapping of Microparticles in a Microfluidic Chip Using Graduated Gaps and Centrifugal Force

We proposed size-dependent microparticle filtration and trapping using graduated microchannel gaps and centrifugal force using a three-dimensional magnetically driven microtool (3D-MMT) in a microfluidic chip made of polydimethylsiloxane (PDMS). Our paper contributes the following to the field: (1) Particle filtration is robust against pressure fluctuation due to tube vibration between the chip and pump. (2) Clogging by microparticles is avoided by rotating the 3D-MMT in a microchamber. (3) Size-classified microparticles are trapped by flow control along microchannel gaps. Different-sized microparticles flow in spiral microchannels and are filtered based on size between gaps and the substrate by centrifugal force. Microparticles larger than gaps remain in the inner microchannel. Rotating the 3D-MMT using an external magnetic circuit generates swirling flow in the microchamber. Size-classified microparticles are trapped in microchannels by closing the drain port for the targeted particle. Trapped particles are measured by direct observation and treated by reagent. After experiments, trapped particles are extracted by opening drain ports. We demonstrated microparticle filtration and microparticle trapping in the microfluidic chip.

In-Situ Formation of a Gel Microbead for Laser Micromanipulation of Microorganisms, DNA, and Viruses

We proposein situformation of gel microbeads made of a thermoreversible hydrogel for indirect laser micromanipulation of microorganisms, DNA, and viruses. Using a 1064 nm laser, we irradiated an aqueous solution mixed with poly-(N-isopropylacrylamide) through a high- magnification lens, thereby forming a gel microbead through heating at the laser focus. The gel microbead, trapped by the laser, was used to indirectly manipulate micro- and nano-scale samples. Laser tweezers stably handle micro-scale object ranging from several tens of nm to several hundreds of µm. This cannot be done with nano-scale objects of a few nm, however, due to laser beam heating. We demonstrate how to manipulate microorganisms, DNA, and viruses indirectly using a gel microbead made from an aqueous poly-(N-isopropylacrylamide) solution. We reduced laser power for gel microbead formation, and used the gel microbead trapped by the laser to manipulate microorganisms, DNA, and viruses.

On-Chip Microparticle Manipulation Using Disposable Magnetically Driven Microdevices

We propose novel microdevices that are driven by magnetic force for microparticles manipulation in a microchip. We developed two microdevices - a particle sorter and a particle filter. In the particle sorter, we perform sorting by switching the microchannel flow by driving a magnetic shuttle. In the particle filter, we perform size-based particle filtering by using the space between a magnetic shuttle and a microchannel. The microparticles which are bigger than the available space are stuck in the microchannels and solution passes through the space. These devices are easily implemented into a microchip at low cost. We make the microchip disposable by making the electromagnet part detachable. We succeeded in driving the magnetic shuttle in the microchannel and confirmed the functionality of the particle sorter and the particle filter. Our proposal has the following advantages: (1) Treatment of the target or complicated control systems are not needed, (2) Microdevices are easily implemented in a microchip, (3) The microchip is made disposable by making the electromagnet part detachable.

On chip single-cell separation and immobilization using optical tweezers and thermosensitive hydrogel

A novel approach appropriate for rapid separation and immobilization of a single cell by concomitantly utilizing laser manipulation and locally thermosensitive hydrogelation is proposed in this paper. We employed a single laser beam as optical tweezers for separating a target cell and locating it adjacent to a fabricated, transparent micro heater. Simultaneously, the target cell is immobilized or partially entrapped by heating the thermosensitive hydrogel with the micro heater. The state of the thermosensitive hydrogel can be switched from sol to gel and gel to sol by controlling the temperature through heating and cooling by the micro heater. After other unwanted cells are removed by the high-speed cleaning flow in the microchannel, the entrapped cell is successfully isolated. It is possible to collect the immobilized target cell for analysis or culture by switching off the micro heater and releasing the cell from the entrapment. We demonstrated that the proposed approach is feasible for rapid manipulation, immobilization, cleaning, isolation and extraction of a single cell. The experimental results are shown here.

Laser printing of single cells: statistical analysis, cell viability, and stress

Methods to print patterns of mammalian cells to various substrates with high resolution offer unique possibilities to contribute to a wide range of fields including tissue engineering, cell separation, and functional genomics. This manuscript details experiments demonstrating that BioLP Biological Laser Printing, can be used to rapidly and accurately print patterns of single cells in a noncontact manner. Human osteosarcoma cells were deposited into a biopolymer matrix, and after 6 days of incubation, the printed cells are shown to be 100% viable. Printing low numbers of cells per spot by BioLP is shown to follow a Poisson distribution, indicating that the reproducibility for the number of cells per spot is therefore determined not by the variance in printed volume per drop but by random sampling statistics. Potential cell damage during the laser printing process is also investigated via immunocytochemical studies that demonstrate minimal expression of heat shock proteins by printed cells. Overall, we find that BioLP is able to print patterns of osteosarcoma cells with high viability, little to no heat or shear damage to the cells, and at the ultimate single cell resolution.

Microfabrication and Laser Manipulation of Functional Microtool Using In-Situ Photofabrication

Single cell experiments have become very important for investigating unknown cell properties. We developed a novel technique to study individual cell properties on a chip using newly developed cell manipulation by laser tweezers with the photo-crosslinkable resin, using this resin to developed functional colored, fluorescent, cell binding, rotation free, and rope shaped microtools on a chip. Colored and fluorescent microtools are for cell manipulation using inexpensive image processing. Cell binding microtools are for high-speed transport of target cells. Rotation free microtools are for attitude control and precise force measurement of cells and DNA. Rope shaped microtools are for versatile manipulation. Laser tweezers is used to position-control microtools. We used a mercury lamp for UV illumination at the local area for combining microtools and fabricated our functional microtools and manipulated cells on the microchip.

Immobilization of individual cells by local photo-polymerization on a chip

A novel separation method for random screening of target cells from a large heterogeneous population by using a local photo-polymerization is developed. A photo-crosslinkable resin solution is mixed with the sample liquid and we controlled the state from sol to gel by irradiating the near ultraviolet (UV) light with the mercury lamp and He-Cd laser near the target cell. We applied three types of immobilization methods such as direct immobilization method, caging method, and direct immobilization with position control method. The selected cell is immobilized in the cured resin directly or inside the cage of the cured resin. In the position control method, laser tweezers are employed to manipulate the target cell indirectly by using the droplet of the resin as a microtool. The cell is positioned properly by the laser manipulation system and is immobilized in the polymerized resin. After the selected cells are immobilized we can easily remove the other objects by the cleaning flow in the microchannel since the polymerized resin strongly binds with the cover glass and resists more than 466 mm s(-1) flow speed in the microchannel (microchannel size: width is 500 micron and depth is 100 micron). We tested the mercury lamp as well as the He-Cd laser for UV-light irradiation at the local area and confirmed improvement of resolution of the cured area by using the He-Cd laser (from 7 micron to 5 micron). Based on this method, we succeeded in single cell immobilization and basic experiments such as culture and fluorescent dyeing of immobilized yeast cells.