The invention comprises a defined and safe soil substitute, herein referred to as “deconstructed soil”, that supports ecological balance in anaerobic microbial ecosystems, such as that inside the human gut, by shifting energy availability to favor growth of bacteria linked with gut health, and away from the most dominant species and species that are putatively harmful. The invention enables vulnerable bacterial groups to recover from a state of apparent extinction from the ecosystem in question. As it does not contain components that are prebiotic or probiotic, the deconstructed soil represents a new product concept for preventing and treating conditions associated with dysfunctional microbial ecosystems in the gastrointestinal tract of humans and animals, as well as other anaerobic microbial ecosystems.

The invention comprises a defined and safe soil substitute, herein referred to as “deconstructed soil”, that supports ecological balance in anaerobic microbial ecosystems, such as that inside the human gut, by shifting energy availability to favor growth of bacteria linked with gut health, and away from the most dominant species and species that are putatively harmful. The invention enables vulnerable bacterial groups to recover from a state of apparent extinction from the ecosystem in question. As it does not contain components that are prebiotic or probiotic, the deconstructed soil represents a new product concept for preventing and treating conditions associated with dysfunctional microbial ecosystems in the gastrointestinal tract of humans and animals, as well as other anaerobic microbial ecosystems.

Systems and methods for performing Direct Sodium Removal (DSR) therapy are provided in which an implantable device includes a pump coupled to an inlet catheter designed for placement in a patient's peritoneal cavity, an outlet catheter designed to be coupled to the patient's bladder, and is operably coupled to an analyte sensor, the pump programmed to transfer and/or cease transfer of fluid from the patient's peritoneal cavity to the patient's bladder for voiding responsive to a level of analyte detected by the analyte sensor. In addition, the system may include a processor that computes an amount of analyte transferred per pumping session.

Systems and methods for performing Direct Sodium Removal (DSR) therapy are provided in which an implantable device includes a pump coupled to an inlet catheter designed for placement in a patient's peritoneal cavity, an outlet catheter designed to be coupled to the patient's bladder, and is operably coupled to an analyte sensor, the pump programmed to transfer and/or cease transfer of fluid from the patient's peritoneal cavity to the patient's bladder for voiding responsive to a level of analyte detected by the analyte sensor. In addition, the system may include a processor that computes an amount of analyte transferred per pumping session.

A method of extracting active ingredients in mushrooms includes following steps: crushing a mushroom to obtain a crude mushroom crush; mixing the crude mushroom crush with deionized water to obtain a crude crush mixture; adding the crude crush mixture into a subcritical fluid extractor and extracting the crude crush mixture to obtain a crude mushroom extract; centrifuging the crude mushroom extract to harvest a first supernatant and a mushroom residue; mixing the mushroom residue with deionized water and a cellulase enzyme to obtain a reaction mixture; adding the reaction mixture into a high-pressure hydrolysis reactor and extracting the reaction mixture to obtain a hydrolysate; centrifuging the hydrolysate to obtain a second supernatant; and combining the first supernatant and the second supernatant, and then concentrating the combined first and second supernatants to obtain a mushroom extraction solution.

A method of extracting active ingredients in mushrooms includes following steps: crushing a mushroom to obtain a crude mushroom crush; mixing the crude mushroom crush with deionized water to obtain a crude crush mixture; adding the crude crush mixture into a subcritical fluid extractor and extracting the crude crush mixture to obtain a crude mushroom extract; centrifuging the crude mushroom extract to harvest a first supernatant and a mushroom residue; mixing the mushroom residue with deionized water and a cellulase enzyme to obtain a reaction mixture; adding the reaction mixture into a high-pressure hydrolysis reactor and extracting the reaction mixture to obtain a hydrolysate; centrifuging the hydrolysate to obtain a second supernatant; and combining the first supernatant and the second supernatant, and then concentrating the combined first and second supernatants to obtain a mushroom extraction solution.

The present disclosure is directed to compositions and methods for the administration of a nutraceutical. The present disclosure is also directed to compositions and methods for the trafficking of stem cells.

The present disclosure is directed to compositions and methods for the administration of a nutraceutical. The present disclosure is also directed to compositions and methods for the trafficking of stem cells.

The present disclosure is directed to compositions and methods for the administration of a nutraceutical. The present disclosure is also directed to compositions and methods for the trafficking of stem cells.

A Direct Sodium Removal method, apparatus and solution for treating patients in heart failure, and having a glomerular filtration rate greater than 15 mL/min/1.73 m.sup.2, or residual kidney function corresponding to normal to CKD Stage 4, is provided in which a no or low sodium DSR infusate is administered to the peritoneal cavity for a predetermined dwell period and then removed, thereby removing sodium from the body. The resulting elimination of fluid from the patient by i) functioning of the kidneys through urination and ii) direct removal of osmotic ultrafiltrate from the peritoneal cavity, restores serum sodium concentrations to healthy levels and thereby reduces fluid overload in the patient.