Systems and methods for administering one or more hydration compositions to an individual to improve vascular health are provided. A system comprises a hydration composition delivery element and a sensor operatively coupled to the hydration composition delivery element. The sensor is configured to determine one or more of the intake of fluids, the amount of fluid discharged, the activity level of the patient, or level of hydration of the patient based on the level of fluid in the hydration composition delivery element. The system further includes a monitoring system which, based on a signal received from the sensor, provides an indication of one or more of the need to intake fluid, the identity of a specific hydration composition of a plurality of hydration compositions to be consumed or an amount of a hydration composition to be consumed.

Systems and methods for administering one or more hydration compositions to an individual to improve vascular health are provided. A system comprises a hydration composition delivery element and a sensor operatively coupled to the hydration composition delivery element. The sensor is configured to determine one or more of the intake of fluids, the amount of fluid discharged, the activity level of the patient, or level of hydration of the patient based on the level of fluid in the hydration composition delivery element. The system further includes a monitoring system which, based on a signal received from the sensor, provides an indication of one or more of the need to intake fluid, the identity of a specific hydration composition of a plurality of hydration compositions to be consumed or an amount of a hydration composition to be consumed.

A method of treatment for mixed carbon dioxide, carbonic acid, saline and optional active additives for treating lower body cavity ailments includes delivery of dosage of the treatment at specified flow rates, using a) main housing having a hollow central area containing the dosage; b) a dosage dispenser head located at the distal end of the main housing, and having at least one flow channel for movement of the dosage from the main housing through the dosage dispenser head and to external of the dosage dispenser head; c) a dosage release control component located between the main housing and the dosage dispenser head to permit flow of the dosage through the dosage dispenser head in response to increased pressure against the dosage; and d) a pressure-changing moveable component on the main housing.

A method of treatment for mixed carbon dioxide, carbonic acid, saline and optional active additives for treating lower body cavity ailments includes delivery of dosage of the treatment at specified flow rates, using a) main housing having a hollow central area containing the dosage; b) a dosage dispenser head located at the distal end of the main housing, and having at least one flow channel for movement of the dosage from the main housing through the dosage dispenser head and to external of the dosage dispenser head; c) a dosage release control component located between the main housing and the dosage dispenser head to permit flow of the dosage through the dosage dispenser head in response to increased pressure against the dosage; and d) a pressure-changing moveable component on the main housing.

A method of treatment for mixed carbon dioxide, carbonic acid, saline and optional active additives for treating lower body cavity ailments includes delivery of dosage of the treatment at specified flow rates, using a) main housing having a hollow central area containing the dosage; b) a dosage dispenser head located at the distal end of the main housing, and having at least one flow channel for movement of the dosage from the main housing through the dosage dispenser head and to external of the dosage dispenser head; c) a dosage release control component located between the main housing and the dosage dispenser head to permit flow of the dosage through the dosage dispenser head in response to increased pressure against the dosage; and d) a pressure-changing moveable component on the main housing.

A method of treating diseased tissue while healing the wound using a diode laser which generates a beam of light having a wavelength in the visible portion of the electromagnetic spectrum (400 nm-700 nm) at a laser power of 0.001 to 1.2 watts, used with intermittent stops to control tissue temperature and biostimulate epithelial regeneration when used with or without substrates. A method of treating diseased tissue using a laser light in the green wavelength range (520-570 nm) at a laser power of 0.001 W to 5 W. A method of treating diseased tissue using a laser light in the IR wavelength range (700-1400 nm) at a laser power of 0.001 W to 5 W.

A method of treating diseased tissue while healing the wound using a diode laser which generates a beam of light having a wavelength in the visible portion of the electromagnetic spectrum (400 nm-700 nm) at a laser power of 0.001 to 1.2 watts, used with intermittent stops to control tissue temperature and biostimulate epithelial regeneration when used with or without substrates. A method of treating diseased tissue using a laser light in the green wavelength range (520-570 nm) at a laser power of 0.001 W to 5 W. A method of treating diseased tissue using a laser light in the IR wavelength range (700-1400 nm) at a laser power of 0.001 W to 5 W.

A method of treatment for mixed carbon dioxide, carbonic acid, saline and optional active additives for treating non-nasal ailments includes delivery of dosage of the treatment at specified flow rates, using a) main housing having a hollow central area containing the dosage; b) a dosage dispenser head located at the distal end of the main housing, and having at least one flow channel for movement of the dosage from the main housing through the dosage dispenser head and to external of the dosage dispenser head; c) a dosage release control component located between the main housing and the dosage dispenser head to permit flow of the dosage through the dosage dispenser head in response to increased pressure against the dosage; and d) a pressure-changing moveable component on the main housing.

A method of treatment for mixed carbon dioxide, carbonic acid, saline and optional active additives for treating non-nasal ailments includes delivery of dosage of the treatment at specified flow rates, using a) main housing having a hollow central area containing the dosage; b) a dosage dispenser head located at the distal end of the main housing, and having at least one flow channel for movement of the dosage from the main housing through the dosage dispenser head and to external of the dosage dispenser head; c) a dosage release control component located between the main housing and the dosage dispenser head to permit flow of the dosage through the dosage dispenser head in response to increased pressure against the dosage; and d) a pressure-changing moveable component on the main housing.

The proposed compositions and methods for preparation thereof relate to pharmacology, medicine, veterinary science and pharmaceutical industry. The compositions can be used for preparing infusion solutions of antimicrobial (antibacterial and antifungal) preparations increasing therapeutic efficiency thereof. The compositions include nanostructured colloidal silica and are efficient when treating overwhelming sepsis of tested animals. The pharmaceutical compositions have a proven and significant clinically important potentiating impact on therapeutic efficiency of the infusion solution, when treating inflammatory diseases, in comparison with traditional solvents.