A dedicated device for detection of vascular shunts can include a first chamber, a second chamber, and a third chamber. The first chamber can be configured to hold liquid, the second chamber to hold gas, and the third chamber can be in communication with the first and second chambers. The third chamber can include small-scale geometric features configured to produce gas bubbles as liquid from the first chamber and gas from the second chamber simultaneously flow into the third chamber. The device can also include a device opening in communication with the third chamber such that a mixture of liquid and gas bubbles can flow out of the device opening. The device can also include a plunger configured to force the liquid and the gas simultaneously from the first and second chambers, through the third chamber to mix with each other and produce bubbles, and further through the device opening.

In a method of treating erectile dysfunction in a patient, a predetermined course of external counter-pulsation treatment is applied to a lower body portion of the patient. After the predetermined course of external counter-pulsation treatment is applied, a predetermined course of low intensity shockwave treatment is applied to a penile area of the patient. After the course of low intensity shockwave treatment, a predetermined course of carboxy therapy is applied to a corpora cavernosa of the patient.

A dedicated device for detection of vascular shunts can include a first chamber, a second chamber, and a third chamber. The first chamber can be configured to hold liquid, the second chamber to hold gas, and the third chamber can be in communication with the first and second chambers. The third chamber can include small-scale geometric features configured to produce gas bubbles as liquid from the first chamber and gas from the second chamber simultaneously flow into the third chamber. The device can also include a device opening in communication with the third chamber such that a mixture of liquid and gas bubbles can flow out of the device opening. The device can also include a plunger configured to force the liquid and the gas simultaneously from the first and second chambers, through the third chamber to mix with each other and produce bubbles, and further through the device opening.

A treatment method that increases circulation and pluripotency of stem and progenitor cells within a patient can be used to fight off or cure various diseases for the patient such as chronic kidney disease or end-stage renal disease. An administrator of the treatment method is provided with a medicinal-administration system such as an intravenous injection system. The treatment method begins by preparing a dosage of oxygen-ozone mixture with the medicinal-administration system. The medicinal-administration system then transfuses the oxygen-ozone mixture in the patient's bloodstream so that the renal system and/or the bone marrow can be targeted by the oxygen-ozone mixture. These steps are repeated as a plurality of treatment session for the patient.

Disclosed is a treatment method to cure diseases within a patient by administering intravenous oxygen-ozone mixture.

A delivery system for the effective, reliable and foolproof delivery of controlled amounts of a medical grade gas to a patient includes a compressed gas unit composed of a vacuum sealed bag to which is secured at least one compressed gas cartridge and a multi-part valve delivery system.

A syringe mechanism for the auto-regeneration of the dermis is provided. The syringe mechanism includes: a liquid syringe filled with liquid in a cylinder thereof, a piston inserted into a top of the cylinder, a discharge portion formed at a bottom portion of the cylinder, and screw threads formed around the discharge portion; and an injecting member having a cylindrical body portion, an inlet portion formed to be inserted and coupled with the discharge portion at a top end of the cylindrical body portion, and a coupling portion formed to be coupled with the screw threads around the inlet portion, the screw threads and the coupling portion rotated and inserted so as to be fastened to the liquid syringe so that liquid is injected into the top portion of the body portion via the liquid syringe.

Described herein is a multiplex platform that uses ultrasmall nanoparticles (e.g., C dots and C dots) to graphically differentiate specific nerves (e.g., sensory nerves vs. motor nerves) for nerve transplants and other surgeries. Also described herein is a multiplex platform that uses ultrasmall nanoparticles (e.g., C dots and C dots) to graphically differentiate between different types of lymph nodes and/or lymphatic pathways, e.g., to safely and effectively perform vascularized lymph node transplantation in the treatment of lymphedema. Also described herein is a multiplex platform that uses ultrasmall nanoparticles (e.g., C dots and C dots) to graphically differentiate parathyroid tissue.

A method for generating microbubbles may include providing a syringe having a barrel defining an interior volume, a plunger, a tip and a check valve assembly. The check valve assembly may have an inlet port; a check valve that is configured to open when the plunger is drawn back by a user; and a nozzle in fluid communication with the interior volume and, when the check valve is open, in fluid communication with the inlet port. The method may include drawing liquid into the interior volume; removing a seal from the inlet port and drawing gas adjacent the inlet ports into the interior volume to form microbubbles in the liquid already drawn in; coupling the tip to an intravenous line associated with a patient undergoing a bubble study; and depressing the plunger to force the liquid and the formed microbubbles into the intravenous line.

The invention relates to a device for treating an individual suffering from cardiac or circulatory arrest or from a stroke, comprising a blood withdrawal device (BE) that is applied to the individual (P), an analysis unit (BA) which is directly or indirectly connected to the blood withdrawal device for detecting a blood analysis result (BAE) providing at least one characteristic of the blood, directly or indirectly connected to a blood return device (BR) that is applied to the individual (P) and is designed to deliver a substance to the individual via the return device (BR).