Abstract: A process for the recovery of AFPs from natural sources, said process involving the steps ofa) isolating an AFP containing juice from the natural source;b) heat treating the natural source or the AFP containing juice to a temperature of at least 60.degree. C.;c) removing the insoluble fraction.

Abstract: A process for obtaining a frozen fish product comprises: treating frozen or non-frozen fish, which comprises molecules of myosin and molecules of actin, each molecule of myosin having a head region (6) and a tail region (8), such that the conformation of the head region of the molecule of myosin changes irreversibly and the conformation of the molecule of actin does not change completely and irreversibly; and storing the fish under freezing conditions. Suitable treatments for affecting the conformational change include application of pressure. The treated fish product has an increased resistance to frozen deterioration of texture.

Abstract: Disclosed are devices for amplifying a preselected polynucleotide in a sample by conducting a polynucleotide polymerization reaction. The devices comprise a substrate microfabricated to define a sample inlet port and a mesoscale flow system, which extends from the inlet port. The mesoscale flow system includes a polynucleotide polymerization reaction chamber in fluid communication with the inlet port which is provided with reagents required for polymerization and amplification of a preselected polynucleotide. In one embodiment the devices may be utilized to implement a polymerase chain reaction (PCR) in the reaction chamber (PCR chamber).

Abstract: A mesoscale sample preparation device capable of providing microvolume test samples, separated into a cell-enriched fraction and a fraction of reduced cell content, for performing various analyses, such as binding assays, determinations involving polynucleotide amplification and the like. Analytical systems including such devices are also disclosed.

Abstract: Disclosed are devices for detecting the presence of a preselected analyte in a fluid sample. The devices comprise a substrate microfabricated to define a sample inlet port, and a mesoscale flow system that includes a sample flow channel extending from the inlet port. The mesoscale flow system further includes an analyte detection region in fluid communication with the flow channel comprised of a binding moiety for specifically binding the analyte. The detection region is constructed with a mesoscale dimension sufficiently small to enhance binding of the binding moiety and the analyte. The binding moiety may be immobilized in the detection region. The mesoscale detection systems of the invention may be used in a wide range of applications, including the detection of cells or macromolecules, or for monitoring reactions or cell culture growth.

Abstract: A process for providing a tomato-based product comprising the following steps: a) applying ultra high pressure to a tomato piece, such that polygalacturonase is inactivated and pectinmethylesterase and preferably peroxidase are not inactivated; b) incubating the tomato piece with endogenous pectinmethylesterase to achieve a desired consistency and preferably with peroxidase to achieve a fresh aroma and/or flavour profile; and c) inactivating the pectinmethylesterase and any peroxidase.

Abstract: A method of processing a solid plant foodstuff comprises (a) heating the plant foodstuff using a mass heating method, according to which, during at least part of the heating step, the environmental pressure of the foodstuff being heated is so controlled in relation to the saturated vapour pressure of the foodstuff as to achieve a substantially uniform temperature through-out the solid foodstuff at the maximum temperature to be attained; (b) cooling the foodstuff by evaporation achieved by maintaining the environmental pressure of the foodstuff lower than the saturated vapour pressure of the foodstuff; characterised in that the time the plant foodstuff is at a temperature above 118.degree. C. is less than 29 seconds, and the time for which the plant foodstuff is above 70.degree. C. is less than approximately 100 seconds.

Abstract: Devices and methods are provided to facilitate the rapid, accurate analysis of a sample having cells characterized by their motility. The devices feature a solid substrate microfabricated to define a flow system including one or more ports or chambers, connected by elongate channels of various shapes having a mescoscale cross-sectional dimension on the order of 0.1 .mu.m to 1000 .mu.m. In one embodiment, the devices are fitted with various flow-regulating features to facilitate unimpeded movement of the motile cells of interest along the flow channels. In another embodiment, devices are provided for conducting replicate motile cell assays, or for conducting a series of different assays using a single test sample. In another embodiment, preparative devices are provided for separating and collecting selected motile cell types of interest.

Abstract: A mesoscale sample preparation device capable of providing microvolume test samples, separated into a cell-enriched fraction and a fraction of reduced cell content, for performing various analyses, such as binding assays, determinations involving polynucleotide amplification and the like. Analytical systems including such devices are also disclosed.

Abstract: A method of processing a solid foodstuff, such as a meat portion or portion of plant foodstuff, by a heating and cooling cycle in which the environmental pressure applied to the foodstuff is controlled during heating so that, at a maximum target temperature, all parts of the body of the foodstuff are conformed to this target temperature due to flow of water, transiently in the vapour phase, from hotter regions to cooler regions. In particular, at least when the target temperature is nominally attained, the pressure is set to the saturated vapour pressure of the foodstuff at the maximum target temperature.

Abstract: Disclosed are devices for detecting the presence of a preselected analyte in a fluid sample. The devices comprise a substrate microfabricated to define a sample inlet port, and a mesoscale flow system that includes a sample flow channel extending from the inlet port. The mesoscale flow system further includes an analyte detection region in fluid communication with the flow channel comprised of a binding moiety for specifically binding the analyte. The detection region is constructed with a mesoscale dimension sufficiently small to enhance binding of the binding moiety and the analyte. The binding moiety may be immobilized in the detection region. The mesoscale detection systems of the invention may be used in a wide range of applications, including the detection of cells or macromolecules, or for monitoring reactions or cell culture growth.

Abstract: Disclosed are devices and methods for analyzing a fluid cell containing sample. The devices are composed of a solid substrate, microfabricated to define at least one sample inlet port and a mesoscale flow system. The mesoscale flow system includes a sample flow channel, extending from the inlet port, and a cell handling region for treating cells disposed in fluid communication with the flow channel. The devices may further include a component for inducing flow of cells in the sample through the flow system. In one embodiment, the cell-handling region may include a cell lysis component to enable the lysis of cells in the sample, prior to, e.g., the detection of an intracellular component in the cell sample. In another embodiment, the cell handling region may have a cell capture region, with binding sites which reversibly bind to a specific population of cells in the cell sample, to permit the isolation of the specific cell population from the sample.

Abstract: Disclosed are devices for amplifying a preselected polynucleotide in a sample by conducting a polynucleotide amplification reaction. The devices are provided with a substrate microfabricated to include a polynucleotide amplification reaction chamber, having at least one cross-sectional dimension of about 0.1 to 1000 .mu.m. The device also includes at least one port in fluid communication with the reaction chamber, for introducing a sample to the chamber, for venting the chamber when necessary, and, optionally, for removing products or waste material from the device. The reaction chamber may be provided with reagents required for amplification of a preselected polynucleotide. The device also may include means for thermally regulating the contents of the reaction chamber, to amplify a preselected polynucleotide. Preferably, the reaction chamber is fabricated with a high surface to volume ratio, to facilitate thermal regulation.

Abstract: Disclosed are devices for amplifying a preselected polynucleotide in a sample by conducting a polynucleotide polymerization reaction. The devices comprise a substrate microfabricated to define a sample inlet port and a mesoscale flow system, which extends from the inlet port. The mesoscale flow system includes a polynucleotide polymerization reaction chamber in fluid communication with the inlet port which is provided with reagents required for polymerization and amplification of a preselected polynucleotide. In one embodiment the devices may be utilized to implement a polymerase chain reaction (PCR) in the reaction chamber (PCR chamber).

Abstract: Disclosed are devices and methods for detecting the presence of a preselected analyte in a fluid sample. The invention provides a device comprising a solid substrate, typically on the order of a few millimeters thick and approximately a 0.2 to 2.0 centimeters square, microfabricated to define a sample inlet port and a mesoscale flow system. A sample is passed through the mesoscale flow system, and the restriction or blockage of flow through the flow system is detected as a positive indication of the presence of the analyte. The mesoscale flow system includes in one embodiment a primary sample flow channel extending from the inlet port, and a fractal region, in fluid communication with the flow channel, comprising bifurcations leading to plural secondary flow channels. The device may be adapted for operation in conjunction with a pump, for example, to induce flow of a sample through the flow system.

Abstract: A hard-frozen anisotropic foodstuff is subjected to a process of "veneer-peeling" at a core temperature of -40.degree. C. to -5.degree. C. In this "veneer-peeling" the hard-frozen foodstuff is for example cut in the manner of a lathe or like a pencil-sharpener. If the foodstuff is raw or uncooked meat, veneer-peeling weakens or fragments the strong connective tissue within the meat whilst retaining the essential fibrous character of the muscle fibers resulting in less tough meat. Thus lower quality meat can be upgraded. A wide array of morphologies of meat particles can be prepared. Other food materials cut in this way are ice cream, coconut, vegetables and hide material leading to offcut with new and useful morphologies.

Abstract: Devices and methods are provided for the clinical analysis of a sperm sample. The devices include a solid substrate, typically on the order of a few millimeters thick and approximately 0.2 to 2.0 centimeters square, microfabricated to define a sample inlet port and a mesoscale flow channel extending from the inlet port. In one embodiment, a sperm sample is applied to the inlet port, and the competitive migration of the sperm sample through the mesoscale flow channel is detected to serve as an indicator of sperm motility. In another embodiment, the substrate of the device is microfabricated with a sperm inlet port, an egg nesting chamber, and an elongate mesoscale flow channel communicating between the egg nesting chamber and the inlet port. In this embodiment, a sperm sample is applied to the inlet port, and the sperm in the sample are permitted to competitively migrate from the inlet port through the channel to the egg nesting chamber, where in vitro fertilization occurs.

Abstract: Devices are provided for analyzing a fluid cell containing sample. The devices comprise a solid substrate, microfabricated to define at least one sample inlet port and a mesoscale flow system. The mesoscale flow system includes a sample flow channel, extending from the inlet port, and a cell handling region for treating cells disposed in fluid communication with the flow channel. The devices may further include a structure inducing flow of cells in the sample through the flow system. In one embodiment, the cell-handling region may comprise a cell lysis structure to enable the lysis of cells in the sample, prior to, e.g., the detection of an intracellular component in the cell sample. In another embodiment, the cell handling region may comprise a cell capture region, comprising binding sites which reversibly bind to a specific population of cells in the cell sample, to permit the isolation of the specific cell population from the sample.

Abstract: Devices and methods are provided for the clinical analysis of a sperm sample. The devices comprise a solid substrate, typically on the order of a few millimeters thick and approximately 0.2 to 2.0 centimeters square, microfabricated to define a sample inlet port and a mesoscale flow channel extending from the inlet port. In one embodiment, a sperm sample is applied to the inlet port, and the competitive migration of the sperm sample through the mesoscale flow channel is detected to serve as an indicator of sperm motility. In another embodiment, the substrate of the device is microfabricated with a sperm inlet port, an egg nesting chamber, and an elongate mesoscale flow channel communicating between the egg nesting chamber and the inlet port. In this embodiment, a sperm sample is applied to the inlet port, and the sperm in the sample are permitted to competitively migrate from the inlet port through the channel to the egg nesting chamber, where in vitro fertilization occurs.

Abstract: The invention concerns with translucent, thixotropic non-particulate denatured protein containing aqueous gels. Also a process for the preparation of these gels is disclosed. The gels can be incorporated in food products and in cosmetics.