Abstract: The present invention provides a nucleic acid sequence amplification method and apparatuses thereof that are simple in the design and easy to miniaturize and integrate into complex apparatuses, with capability of using DNA polymerases that are not thermostable. In the present invention, a plurality of heat sources are combined to supply or remove heat from specific regions of the sample such that a specific spatial temperature distribution is maintained inside the sample by locating a relatively high temperature region lower in height than a relatively low temperature region.

Abstract: Disclosed is a method for detaching cultured cells that can selectively detach cultured adhered cells. The scaffold to which the cells adhere is configured from at least a cell adhesion factor containing carbon nanotubes, and by means of radiating laser light in a spot shape on the scaffold in a region where cells are adhered, a shock wave is generated by the heat arising by means of the photothermal conversion of the carbon nanotubes, and by means of this shock wave, the cells are caused to be in a non-adhered state.

Abstract: An incubator including a cultivating chamber for cultivating cultures, a water supply control unit for supplying water into the cultivating chamber through a water supply passage and adjusting the humidity of the inside of the cultivating chamber, and a filter provided in the water supply passage.

Abstract: Control of humidity in chemical reactors, and associated systems and methods, are generally described. In certain embodiments, the humidity within gas transport conduits and chambers can be controlled to inhibit unwanted condensation within gas transport pathways. By inhibiting condensation within gas transport pathways, clogging of such pathways can be limited (or eliminated) such that transport of gas can be more easily and controllably achieved. In addition, strategies for purging condensed liquid from chemical reactor systems are also described.

Abstract: There is provided a cell chip including: a first substrate provided with a culture region receiving a bio-material and a humidity control space storing water for maintenance of humidity; a second substrate coupled to the first substrate; and a first wall member surrounding the culture region.

Abstract: There is provided a cell culture device including: a cell chip receiving part receiving a cell chip; a drug storing part storing a drug; and a circulation part connecting the cell chip receiving part and the drug storing part to one another and circulating the drug therebetween. The cell culture device may allow for the observation or examination of a reaction between a cell and a drug in an environment similar to that of the inside of a body.

Abstract: The invention relates to a user access port for a controlled atmosphere apparatus comprising a porthole extending through a wall; a sealing assembly comprising a first sealing means and a second sealing means for maintaining a sealing barrier across the porthole, whereby the first sealing means comprises a first closure member that is adapted to at least substantially seal the porthole when arranged in a closed position and allow user access to the porthole when arranged in an open position; the second sealing means is mounted so as to extend at least substantially across the porthole and comprises a sealed access member and a second closure member, whereby the sealed access member comprises a user access aperture having a peripheral edge adapted to form a sealing contact with an arm of a user when an operator extends his arm through the user access aperture and whereby the second closure member is adapted to at least substantially seal the user access aperture when arranged in a closed position and at least

Abstract: Disclosed is a tissue-derived biomaterial carrier device (1) comprising a carrier case 810), an arm (125) provided upright on an interior bottom wall surface of the carrier case (10), a mounting part (121), a swing mechanism (122), a temperature control box (20) provided detachably on an exterior wall surface of the carrier case (10), and a heater (201) provided in the temperature control box (20). The mounting part (121) receives the mounting of a housing vessel in which a tissue-derived biomaterial is housed (an opening part (121a)). The swing mechanism (122) swingably supports the mounting part (121) relative to the arm (125). With the temperature control box (20) mounted on the carrier case (10), the heater (201) in the temperature control box (20) receives the supply of electric power from a battery (203) and regulates the temperature within the carrier case (10).

Abstract: Multiplex binding assay assemblies are disclosed. The assemblies include at least one assay bar that has a top side, a bottom side, and at least one well accessible from the top side of the assay bar, with each well including a side surface, a bottom surface, an open top end. Each well also includes at least one secondary container, with each secondary container including a capillary tube that (i) begins at a location within an interior volume of the well and (ii) ends at a location beneath the bottom side of the assay bar. The assemblies further include a guiding track, which includes a set of two rails, with each rail having its own separate groove. Such grooves are configured to run parallel to each other with a distance between such grooves, with a first groove configured to receive a protruding element (or an end) of a first side of the assay bar, and a second groove configured to receive a protruding element (or an end) of a second side of the assay bar.

Abstract: An apparatus for processing at least one biological sample accommodated on at least one carrier member (15) in a chamber includes, at least one reservoir (18) able to accommodate a fluid on a surface inside the chamber adjacent to and/or facing a substantial part of the at least one biological sample. The apparatus may comprise a bottom member (12) arranged to support at least one carrier member (15) carrying at least one biological sample and a lid (14) including at least one fluid reservoir (18). The reservoir filled with water provides humidity to the chamber and impedes drying out of the sample.

Abstract: A biochemical processing apparatus for performing biochemical processing in a container having a plurality of wells capable of holding liquid includes an opening/closing mechanism configured to open or close a lid capable of hermetically and selectively sealing the plurality of wells.

Abstract: An apparatus comprising an assembly and a cover. The assembly comprises a sample block configured to receive a microtiter tray having a plurality of vials, each vial comprising a cap having a surface and a perimeter. The cover comprises a platen, vertically and horizontally displaceable in relationship to the sample block, the platen having a plurality of recesses. Each recess corresponds to a respective vial and is shaped and arranged to clear the surface of its respective cap when the cover is displaced onto the sample block. The cover includes a skirt in contact with and surrounding a perimeter of the platen. The skirt is configured for mating with a perimeter of a microtiter tray when a microtiter tray is received in the sample block, and also configured such that the cover contacts a microtiter tray when a microtiter tray is received in the sample block.

Abstract: A culture container includes a first transparent member being capable of keeping a predetermined temperature; a second transparent member facing to the first transparent member; a housing member to which the first transparent member and the second transparent member are adhered forming a culture space being capable of housing a well plate together with the first transparent member and the second transparent member; and a sealing member for sealing a liquid injected into the culture space between the first transparent member and the housing member.

Abstract: A biotip according to an embodiment of the invention moves a reaction mixture along a longitudinal direction under the force of gravity. The biotip includes a chamber formed of a transparent material and filled with a liquid having a smaller specific gravity than the reaction mixture and immiscible with the reaction mixture, and a seal that seals the chamber. The liquid has a volume resistivity of greater than 0 ?·cm and 5×1013 ?·cm or less.

Abstract: Novel methods and systems for polymerase chain reaction (PCR) are disclosed. A PCR device has a bottom heater layer, a central reacting layer, and a top heater layer. The central reacting layer has a PCR reacting chamber connected with fluidics channels. Photoluminescence of a DNA solution in the PCR reactive chamber is carried out through the transparent top layers.

Abstract: The invention relates to a device for carrying out of chemical or biological reactions with a reaction vessel receiving element for receiving a microtiter plate with several reaction vessels, wherein the reaction vessel receiving element has several recesses arranged in a regular pattern to receive the respective reaction vessels, a heating device for heating the reaction vessel receiving element, and a cooling device for cooling the reaction vessel. The invention is characterized by the fact that the reaction vessel receiving element is divided into several segments. The individual segments are thermally decoupled from one another, and each segment is assigned a heating device which may be actuated independently of the others. By means of the segmentation of the reaction vessel receiving element, it is possible for zones to be set and held at different temperatures.

Abstract: In one implementation, an electronic device includes a first body portion, a second body portion movably coupled to the first body portion, a heat source, and a thermal conductor in thermal communication with the heat source. The heat source is disposed within one of the first body portion or the second body portion. The thermal conductor has a first end portion, a second end portion, and a flexible portion between the first end portion and the second end portion. The first end portion of the thermal conductor is disposed within the first body portion. The second end portion of the thermal conductor is disposed within the second body portion.

Abstract: A culture apparatus comprising: an inner box configured to form a culture chamber; an outer box configured to cover the inner box; a fan configured to circulate gas inside the culture chamber through an air passage provided in the inner box within the culture chamber; a first through hole configured to penetrate a wall configuring a part of the air passage in the inner box; a second through hole configured to penetrate the wall and disposed at a position at which a flow velocity of the gas circulated through the air passage by the fan is lower than a flow velocity of the gas around the first through hole; a connecting pipe configured to connect the first through hole and the second through hole outside of the inner box; and a sensor configured to detect a concentration of the gas flowing in the culture chamber.

Abstract: A polymerase chain reaction (“PCR”) apparatus includes a PCR chip holder which accommodates and supports a PCR chip, a housing which supports ends of the PCR chip holder, a temperature control element which moves perpendicularly with respect to the PCR chip holder in a space between the housing and the PCR chip holder in the housing, and an elastic unit which elastically biases the temperature control element toward the PCR chip holder, between the temperature control element and the housing. The temperature control element includes a top surface which is selectively contacted to a bottom surface of the PCR chip.

Abstract: A micro-fluidic device includes a plurality of heaters on a substrate for heating the substrate. The plurality of heaters define a plurality of temperature regions having distinct temperatures on the substrate. A flow feature layer is formed above the substrate to define a channel extending across the substrate through each temperature region. As fluid is repeatedly pumped within the channel, it flows from one temperature region to a next temperature region to undergo thermal cycling.

Abstract: An apparatus for thermal cycling can transfer heat uniformly and efficiently. The apparatus can be used in a method that reduces condensation on sample wells. The apparatus can also be manufactured to provide uniform configurations.

Abstract: A temperature cycling system (10, 110) is provided for repeatedly heating and cooling a reaction mixture (16). The system (10, 110) includes a first heater (27) and a second heater (28) each movable between a first orientation in which the first or second heater (27, 28) affects the temperature of the reaction mixture (16) and a second orientation in which the first or second heater (27, 28) does not substantially affect the temperature of the reaction mixture (16). During temperature cycling, the second heater (28) is in the second orientation when the first heater (27) is in the first orientation, and the second heater (28) is in the first orientation when the first heater (27) is in the second orientation.

Abstract: The invention relates to an air-conditioning space (10) for storing samples in a time-controlled manner, comprising a device (22) for automatically feeding sample containers (18) into a climatically sealed space (12) having at least one wall (43), into which a sample container (18) can be inserted into the climatically sealed space (12) through an opening (40, 42), wherein the feed device (22) has at least one drive and control unit, and an incubator receptacle (30) for receiving the samples (18) is provided inside the climatically sealed space (12). The invention is distinguished by the fact that the feed device has an automatic feed arm (22, 24) which grips a sample container (18) from a receiving position outside the climatically sealed space (12) and deposits the sample container (18) there in a clear deposit position in an incubator receptacle (30).

Abstract: The invention provides an animal cell culture kit to be used favorably for culturing animal cells, a method for culturing animal cells, a method for culturing selectively animal cells, and a method for differentiating a cell. An animal cell culture kit according to the invention includes an incubator containing one or more types of functional groups selected from the group consisting of hydrophilic functional groups and hydrophobic functional groups at predetermined contents on a surface, and a serum-free culture medium. Since the animal cell culture kit includes an incubator having a functional group suitable for adhesion and proliferation of specific animal cells, proliferation of animal cells can be promoted even with a serum-free culture medium.

Abstract: Method for converting a carbon source such as a plant-derived material into a hydrocarbon or hydrocarbon precursor, via a microorganism-catalysed aerobic reaction. The microorganism is cultivated in the presence of the carbon source and of oxygen, in a reaction vessel having a capacity of about 2000 litres or greater which comprises an aeration system for supplying oxygen to the microorganism. Also provided is an apparatus for use in the method, comprising a reaction vessel of capacity 2000 litres or greater, and an aeration system.

Abstract: Thermocycling system, including methods and apparatus, for performing a flow-based reaction on a sample in fluid. The system may include a plurality of segments defining at least two temperature regions, and also may include a plurality of heating elements configured to maintain each temperature region at a different desired temperature. At least one of the heating elements may be a thermoelectric cooler operatively disposed to transfer heat to and/or from a temperature region The system further may include a fluid channel extending along a helical path that passes through the temperature regions multiple times such that fluid flowing in the channel is heated and cooled cyclically.

Abstract: A chemical and/or biochemical system (1) having at least one reaction vessel (3) in which chemical and/or biochemical reactions may take place, the temperature of the reaction vessels being cycled between at least a highest predetermined temperature and a lowest predetermined temperature, the system comprising a thermal mount (4) for receiving the reaction vessel (s), the thermal mount being thermally coupled to a first, thermally conductive side of a thermoelectric module (5), a second thermally conductive side of the thermoelectric module being thermally coupled to a heat sink (6) and being provided with a pair of electrical contacts (33) to which a pair of electrically conductive wires (34) is connected for coupling to a power source, characterized in that a flexible adhesive (31, 32) is provided between the first thermally conductive side of the thermoelectric module and the thermal mount and between the second thermally conductive side of the thermoelectric module and the heat sink, whereby the adhesive

Abstract: A thermal cycler is provided that may be used as a nucleic acid amplification apparatus. The cycler has at least three temperature zones that can be set at different temperatures, the temperature zones including a first temperature zone, an intermediate zone, and a second temperature zone. The cycler has a channel including a plurality of forward subchannels and a plurality of backward subchannels, with the forward subchannels being different from the backward subchannels in terms of cross-sectional area in the intermediate zone. The channel is configured to continuously flow a fluid alternately through one of the forward subchannels and one of the backward subchannels, so that the fluid travels repeatedly between the first temperature zone and the second temperature zone via the intermediate zone, whereby the fluid is thermally cycled while the fluid flows through the channel.

Abstract: A thermal cycler includes: a first mounting unit and a second mounting unit which are cylindrical; a temperature gradient forming unit which forms a temperature gradient along mounting directions of the first mounting unit and the second mounting unit; and a driving mechanism which rotates the first mounting unit, the second mounting unit, and the temperature gradient forming unit around a rotating shaft having a component perpendicular to a direction in which gravity is applied and a component intersecting the mounting directions of the first mounting unit and the second mounting unit, wherein the first mounting unit and the second mounting unit are disposed on opposite sides to each other with the rotating shaft interposed therebetween, the mounting direction of the first mounting unit and the mounting direction of the second mounting unit are in the same direction.

Abstract: The field of the invention relates to a device for incubating a sample. The present disclosure provides an incubator for shaking and/or heating at least one sample. The device comprises at least one inductor placed below an induction heating plate. A heat conducting plate is mounted onto the induction heating plate. The device further comprises a moving arrangement for placing the sample onto the heat conducting plate.

Abstract: The feasibility of using CO2 from a concentrated source to grow microalgae is limited by the high cost of CO2 capture and transportation, as well as significant CO2 loss during algae culture. Another challenge is the inability of algae in using CO2 during night while CO2 is continuously produced from the source. To address these challenges, this invention provides a process in which CO2 is captured as bicarbonate and used as feedstock for algae culture. Then the carbonate is regenerated in the algae culture process as absorbent to capture more CO2, which is converted to bicarbonate for use as feedstock, etc. This process significantly reduces carbon capture costs since it avoids the energy for carbonate regeneration. Also, transporting a solid or aqueous bicarbonate solution has a much lower cost than transporting compressed CO2, and using bicarbonate provides a better alternative for CO2 delivery to algae culture systems than supplying CO2 gas.

Abstract: Systems and methods for multiple analyte detection include a system for distribution of a biological sample that includes a substrate, wherein the substrate includes a plurality of sample chambers, a sample introduction channel for each sample chamber, and a venting channel for each sample chamber. The system may further include a preloaded reagent contained in each sample chamber and configured for nucleic acid analysis of a biological sample that enters the substrate and a sealing instrument configured to be placed in contact with the substrate to seal each sample chamber so as to substantially prevent sample contained in each sample chamber from flowing out of each sample chamber. The substrate can be constructed of detection-compatible and assay-compatible materials.

Abstract: An apparatus 20 for biological or chemical reactions, in particular PCR, includes a heat removal module 22 adapted to receive snugly a reaction vessel 24 in such a manner as to create good thermal conductivity contact between the module and the vessel. The heat removal module 22 is formed of a thermally conductive material having therein a channel 64 adapted for the flow of a coolant liquid. The heat removal module 22 is constructed with an array of receiving stations 62 for the reception of a corresponding array of reaction vessels 24.

Abstract: The invention concerns methods for automated culture of embryonic stem cells (ESCs) such as human ESCs. In some aspects, methods of the invention employ optimized culture media and limited proteolytic treatment of cells to separate cell clusters for expansion. Automated systems for passage and expansion of ESCs are also provided.

Abstract: An infant warmer includes an infant enclosure defining an infant compartment, and a heating system pneumatically coupled with the infant compartment. The heating system includes a heater configured to selectively transfer heat to the infant compartment, and a thermal storage device configured to store heat from the heater and to selectively transfer said stored heat to the infant compartment. The infant warmer also includes a controller operatively connected to the heating system. The controller is configured to regulate the transfer of heat from the thermal storage device such that a target temperature is maintained within the infant compartment.

Abstract: The invention provides a device for growing genetically enhanced aquatic photoautotrophic organisms in a stable culture, causing the organisms to produce ethanol, and then separating, collecting, and removing the ethanol in situ.

Abstract: A portable warmer for use with a cell culture plate in order to maintain culture samples borne by the culture plate at a desired temperature includes a body having formed therein a shelf that is sized and shaped to generally conform to the outside dimensions of the base of a cell culture plate. The shelf includes a substantially horizontal surface atop of which the base of the cell culture plate may be freely rested. The shelf also includes a preferably electric heating element, which may be formed unitary with the horizontal surface of the shelf or may be contained within the body of the portable warmer in an area and in a manner adapted to cause heating of the horizontal surface of the shelf. The portable warmer is provided with one or more clamping devices for securing a received cell culture plate in place atop the shelf.

Abstract: A self-contained circulation system, which supports the formation of capillaries in capillary growth sections and allows the formation of micro organoids and/or micro tissue sections for monitoring the effect of one or more test compounds and determining efficacy, side-effects, biosafety, metabolites, mode of action or organ regeneration as well as methods of establishing such micro organoids and/or micro tissue in the self-contained circulation system.

Abstract: An incubator comprising: a culture chamber configured to accommodate culture; a dish structure configured to contain a liquid; an ultrasonic vibrator provided in a part of the dish structure, the ultrasonic vibrator configured to atomize the liquid; and a gas-liquid contact structure configured to bring the atomized liquid into contact with air in the chamber to be cultured.

Abstract: A bioreactor processing unit (10) includes at least one cell culture module (200) comprising: a base (202) including a receiving station (204) for removably receiving a plurality of bioreactor vessels (400) at respective locations (206); and a clamp plate (240). The clamp plate (240) is removably connectable to the base (202). The system further includes a drive mechanism (226) and multiple fluid conduits. When the system is to be used for an experiment run, vessels (400) are loaded into the receiving station (204) and the clamp plate (240) is connected to the base (202), forming a connection between the drive mechanism and the vessels, for transmitting input motion from the drive mechanism (226) into multiple rotary motion outputs for turning a stirrer (416) in each vessel (400).

Abstract: An incubator includes: a mount table having placed thereon a container, a holding member holding the container, or a storage member storing the holding members in a vertical-multi-stage manner; a carrying-in door on one side-face of the incubator including first and second antennas in an interior; a discrimination unit to determine that the container or holding member is placed on the table if radio waves are transmitted/received between the first antenna and a tag of the container or holding member, and determine that the storage member is placed if radio waves are transmitted/received between the second antenna and the tag of the holding member in the storage member; and a warning unit to warn if the container or holding member is placed thereon and a specified storage destination is a place for storage member, or the storage member is placed and the destination is a place for holding member.

Abstract: A culture apparatus comprising: a fan configured to circulate air inside a culture chamber in a predetermined direction in the culture chamber; a duct configured to guide air circulating inside the culture chamber along a wall face inside the culture chamber from an upper part to a lower part of the culture chamber; and a gas generator detachable from a predetermined position at a lower part of the duct, the gas generator being configured to take in air discharged from a lower part of the duct and discharge together with the air taken in a hydrogen peroxide gas to sterilize the inside of the culture chamber generated from a hydrogen peroxide solution into the culture chamber.

Abstract: The invention relates to a method for analyzing the effect of a gaseous medium on a biological test system using an extracellular metabolization system. The method consists of the following steps: a biological test sample is cultivated on a permeable carrier, the gaseous medium is guided over the surface of the biological test system in order to form an exposition atmosphere over the biological test system, the extracellular metabolization system is added to a conservation medium and the permeable carrier is brought into contact with a conservation medium that comprises the extracellular metabolization system below the permeable carrier, in such a manner that the extracellular metabolization system only passes through the permeable carrier and that the biological test system is not submerged by the conservation medium containing the extracellular metabolization system.

Abstract: An attachment unit for attachment of a reaction container including a channel filled with a reaction solution and a liquid having a specific gravity different from that of the reaction solution and being immiscible with the reaction solution, the reaction solution moving close to opposed inner walls, a first heating unit that heats a first region of the channel and a second heating unit that heats a second region of the channel when the reaction container is attached to the attachment unit, a drive mechanism that switches arrangement of the attachment unit, the first heating unit, and the second heating unit between a first arrangement and a second arrangement in which a lowermost position of the channel is located within a first region and a second region, respectively, and a control unit that controls the drive mechanism, the first heating unit, and the second heating unit are provided.

Abstract: A pair or receptacles capable of housing an emitter probe and a detector probe are installed inside a bioreactor to monitor the properties of the nutrient media without contacting the nutrient media.

Abstract: The present invention relates to a cell observation apparatus that facilitates the setting of schedules. An observation schedule that has already been registered is presented to a user by a time schedule display unit of a schedule setting screen, and a new observation schedule is acquired in response to an input of set values of photographic conditions by the user. Then determination is made whether the photographing time of this observation schedule and the photographing time of the already registered observation schedule overlap, and when the photographing times are determined to overlap, the photographic conditions including the photographing time of one or both of the observation schedules are changed and the observation schedule is registered. The invention can be applied, for example, to incubators for culturing cells.

Abstract: An apparatus and method for thermal cycling including a pasting edge heater. The pasting edge heater can provide substantial temperature uniformity throughout the retaining elements during thermal cycling by a thermoelectric module.

Abstract: Provided herein is a portable thermocycler, comprising: (i) a case; (ii) a rotary plate in the case; (iii) a plurality of heating blocks arranged in a geometric pattern disposed on the rotary plate; and (iv) at least one vessel adapted to move and contact at least two of the plurality of heating blocks; wherein each of the heating blocks comprises a heating plate maintained at a set temperature over a thermally insulating material; wherein the geometric pattern comprises a number of center heating blocks arranged in a shape defining a polygon and a number of outside heating blocks disposed around the periphery of the rotary plate; and wherein the rotary plate includes a plurality of rotating wheels adapted to rotate at least one of the vessels into contact with each of the heating blocks.

Abstract: A microfluidic processing device includes a substrate defining a microfluidic network. The substrate is in thermal communication with a plurality of N independently controllable components and a plurality of input output contacts for connecting the substrate to an external controller. Each component has at least two terminals. Each terminal is in electrical communication with at least one contact. The number of contacts required to independently control the N components is substantially less than the total number of terminals. Upon actuation, the components typically heat a portion of the microfluidic network and/or sense a temperature thereof.

Abstract: A non-symmetric polymerise chain reaction (PCR) amplification method employing a limiting primer in low concentration whose concentration-adjusted melting point at least equals, and preferably exceeds, that of the excess primer, the latter in turn not being more than 25° C. below the melting temperature of the amplicon. Assays employing such amplification and labeled hybridization probes, including assays that include a detection step following primer extension or a low-temperature probe, or both. Kits for performing such assays and primer or primer-and-probe sets for performing the foregoing amplifications and assays.