Abstract: Systems and methods remove and manage heavy metals. In one implementation, an exemplary method can be applied to food processing and food consumption to remove heavy metals such as mercury, lead, uranium and cadmium before absorption by a living organism. The exemplary method exposes the food to a heavy-metal binding ligand, such as a concentrated protein or phytic acid, to form a heavy-metal chelate, and then allows the chelate to separate from the food. In another implementation, an exemplary probe possesses innovative molecular layers on its surface to detect and quantify heavy metals by attracting and binding traces of the heavy metals on a ligand layer.

Abstract: An efficient biomass fractionating system for an energy pulse crop is provided. Pulses include, e.g., peas, beans, and lentils. A method and ecosystem model applies a premium utilization to each fraction of a pulse crop so that no fraction is treated as waste. The methods may also be applied to other alternative crops, such as chestnut seeds, banana and 408 peel, and taro root. One example method removes a protein fraction first, as a food source, before using the remaining fractions to produce energy products, such as ethanol or methane, increasing the efficiency of the entire fractionating process. The fractionating method enables an ecosystem, in which pulses grow inexpensively on low-grade land or under poor conditions providing a cash crop food, energy, and chemical components. In a farm co-op model, the pulse crop provides sustainability as participants inexpensively produce protein, ethanol, and industrial chemical components.

Abstract: A electrochemical sensor system is provided. An example system utilizes electrical and steric properties of contaminants, such as pesticides, herbicides, and heavy metals to measure an ongoing concentration of multiple contaminants simultaneously in real time. An example system has a sensor array including sensors tuned to specific contaminants, each sensor having at least two conducting elements arranged in a capacitive relationship, for example, on a printed circuit board. A binding layer on the conducing elements of each sensor selectively binds a specific contaminant, which produces a signature change in a measureable electrical property, such as impedance. Enclosed sensors and chemical buffers preserve the chemical and physical environment of the contaminants for ongoing real-time measurement of dynamic concentrations. A delivery system enables samples containing contaminants to be automatically delivered to the array of sensors without adulterating the natural state of the samples.

Abstract: An efficient biomass fractionating system for an energy pulse crop is provided. Pulses include, e.g., peas, beans, and lentils. A method and ecosystem model applies a premium utilization to each fraction of a pulse crop so that no fraction is treated as waste. The methods may also be applied to other alternative crops, such as chestnut seeds, banana and 408 peel, and taro root. One example method removes a protein fraction first, as a food source, before using the remaining fractions to produce energy products, such as ethanol or methane, increasing the efficiency of the entire fractionating process. The fractionating method enables an ecosystem, in which pulses grow inexpensively on low-grade land or under poor conditions providing a cash crop food, energy, and chemical components. In a farm co-op model, the pulse crop provides sustainability as participants inexpensively produce protein, ethanol, and industrial chemical components.