Abstract: Disclosed herein are methods, systems, and compositions for the uniform pretreatment of biomass within seconds with low inhibitor formation. The pretreatment process is used to convert biomass to a fuel, sugars, or other useful chemicals by subjecting the feedstock to a rapid retention time under pressure and temperature and/or chemical reactant. The system includes at least one high pressure, steam impermiable plug and a continuously-operating valve discharge apparatus to discharge pretreated feedstock while maintaining uniform pressure on the pretreatment system.

Abstract: A valve assembly wherein the inner wall of the valve body comprises at least one opening for the entry of a liquid under pressure following output of a slurry or liquid from a tube or pipe. The valve assembly is particularly useful in maintaining a semi-continuous or continuous pressurized flow of biomass from an extruder and extending the reaction zone downstream from the extruder. An advantage of having an extended reaction zone allows for a complete treatment of materials without further wear on the extruder and also allows manipulation of the upstream treatment of materials in the tube or pipe.

Abstract: A valve assembly having a conical valve needle axially displaceable in a bore of a valve body wherein a portion of the larger diameter of the valve needle seats downstream at an annular ring when the valve is closed. There is an open area between one end of the valve body to the annular ring even at closure and nozzles for the input of a liquid. The inner wall of the valve body comprises at least one opening for the entry of a liquid under pressure following output of a slurry or liquid from a tube or pipe. The valve assembly is particularly useful in maintaining a semi-continuous or continuous pressurized flow of biomass from an extruder.

Abstract: An extruder and valve system comprises a conduit for conveying a biomass stream using a plurality of injector assemblies to provide water or other fluids and/or steam for pretreatment. Each injector in the assembly is connected to a corresponding port in the extruder. The ports can be positioned at discrete locations of the extruder or beyond to deliver the appropriate amount of fluid or steam for the processing of biomass or other materials.

Abstract: A physiological monitoring system can use physiological wearable monitors to collect and/or detect various parameters, such as cough, wheeze, heart rate, skin temperature, activity, respiration rate, skin impedance, electro-cardiogram data, blood pressure, galvanic skin response, and the like. One or more of these parameters, or other such parameters, may be used in methods in the fields of lung cancer, physiotherapy, monitoring disabled or challenged individuals, monitoring end of life conditions, monitoring breathing gas usage, monitoring patients and individual wellness, data acquisition, athletic sports monitoring, athletic sports entertainment, virtual reality feedback, telemedicine, hospital aid, illness detection and its severity, and public service, as examples. Such methods can use data from one or more wearable devices with the appropriate data processing to present the user or healthcare provider with the appropriate analysis.

Abstract: A physiological monitoring system can use physiological wearable monitors to collect and/or detect various parameters, such as cough, wheeze, heart rate, skin temperature, activity, respiration rate, skin impedance, electro-cardiogram data, blood pressure, galvanic skin response, and the like. One or more of these parameters, or other such parameters, may be used in methods in the fields of lung cancer, physiotherapy, monitoring disabled or challenged individuals, monitoring end of life conditions, monitoring breathing gas usage, monitoring patients and individual wellness, data acquisition, athletic sports monitoring, athletic sports entertainment, virtual reality feedback, telemedicine, hospital aid, illness detection and its severity, and public service, as examples. Such methods can use data from one or more wearable devices with the appropriate data processing to present the user or healthcare provider with the appropriate analysis.

Abstract: A wearable and/or a wearable mount solves many issues presented with conventional wearables and wearable mounts. For example, the wearable mount can be designed with a low ratio of adhesive contact area to wearable mount contact area while providing the capability to collect data and/or dispense medication on one specific spot and, further still, allowing the use of an easy to remove adhesive. This configuration may facilitate free movement of the body even when the wearable mount is attached to the skin. The wearable may have surface contacts, removing the need for ports that could be damaged. The adhesive layer can provide insulation and isolating properties for the contacts while the device is being worn. Finally, the wearable may be a patch-type wearable that allows the appearance of the wearable to be changed without the need for housing changes or other costly solutions.

Abstract: A wearable and/or a wearable mount solves many issues presented with conventional wearables and wearable mounts. For example, the wearable mount can be designed with a low ratio of adhesive contact area to wearable mount contact area while providing the capability to collect data and/or dispense medication on one specific spot and, further still, allowing the use of an easy to remove adhesive. This configuration may facilitate free movement of the body even when the wearable mount is attached to the skin. The wearable may have surface contacts, removing the need for ports that could be damaged. The adhesive layer can provide insulation and isolating properties for the contacts while the device is being worn. Finally, the wearable may be a patch-type wearable that allows the appearance of the wearable to be changed without the need for housing changes or other costly solutions.

Abstract: Disclosed herein are methods, systems, and compositions for the uniform pretreatment of biomass within seconds with low inhibitor formation. The pretreatment process is used to convert biomass to a fuel, sugars, or other useful chemicals by subjecting the feedstock to a rapid retention time under pressure and temperature and/or chemical reactant. The system includes at least one high pressure, steam impermiable plug and a continuously-operating valve discharge apparatus to discharge pretreated feedstock while maintaining uniform pressure on the pretreatment system.

Abstract: A physiological monitoring system can use physiological wearable monitors to collect and/or detect various parameters, such as cough, wheeze, heart rate, skin temperature, activity, respiration rate, skin impedance, electro-cardiogram data, blood pressure, galvanic skin response, and the like. One or more of these parameters, or other such parameters, may be used in methods in the fields of lung cancer, physiotherapy, monitoring disabled or challenged individuals, monitoring end of life conditions, monitoring breathing gas usage, monitoring patients and individual wellness, data acquisition, athletic sports monitoring, athletic sports entertainment, virtual reality feedback, telemedicine, hospital aid, illness detection and its severity, and public service, as examples. Such methods can use data from one or more wearable devices with the appropriate data processing to present the user or healthcare provider with the appropriate analysis.

Abstract: A wearable and/or a wearable mount solves many issues presented with conventional wearables and wearable mounts. For example, the wearable mount can be designed with a low ratio of adhesive contact area to wearable mount contact area while providing the capability to collect data and/or dispense medication on one specific spot and, further still, allowing the use of an easy to remove adhesive. This configuration may facilitate free movement of the body even when the wearable mount is attached to the skin. The wearable may have surface contacts, removing the need for ports that could be damaged. The adhesive layer can provide insulation and isolating properties for the contacts while the device is being worn. Finally, the wearable may be a patch-type wearable that allows the appearance of the wearable to be changed without the need for housing changes or other costly solutions.