Abstract: A system and method for transmyocardial laser revascularization (TMLR) in patients in need thereof, such as patients suffering from coronary artery disease. The system includes a Laser unit, an Electrocardiogram (EKG) unit, Vectorcardiography (VCG) unit, an Echocardiography unit, a spectrum Infrared sensor unit, and a control unit. The control unit can receive investigational data from different units and use the same to optimize the laser parameters. The Control unit can further include an AI module that can further analyze patient-related data, such as age and medical condition to further optimize the laser parameters. The laser unit can operate based on the optimized parameters to prevent unnecessary damage to the heart and allow maintaining the patency of the channels made by the laser for a longer duration.

Abstract: Disclosed is a method of treating microbial infections and their associated complications in humans. The method includes administering to a patient, a composition of dextrose and ethanol. The composition can be administered in the form of an infusion. For patients suffering from respiratory complications, the disclosed method also provides for enhancing oxygen uptake by lungs and reducing oxygen resistance through the administration of air having helium gas and excited oxygen atoms.

Abstract: Disclosed is a method of treating microbial infections and their associated complications in humans. The method includes administering to a patient, a composition of dextrose and ethanol. The composition can be administered in the form of an infusion. For patients suffering from respiratory complications, the disclosed method also provides for enhancing oxygen uptake by lungs and reducing oxygen resistance through the administration of air having helium gas and excited oxygen atoms.

Abstract: The embodiments herein relate to an artificial diaphragm made up of a plurality of plates having nanoparticles which move to-and-fro creating a movement similar to a natural diaphragm. The embodiments herein provide an artificial diaphragm that can mimic diaphragmatic movements of a natural diaphragm in a human body. The artificial diaphragm is embedded with intelligent nanomagnetic particles which is used for treatment of diaphragmatic paralysis.

Abstract: The embodiments herein relate to an artificial diaphragm made up of a plurality of plates having nanoparticles which move to-and-fro creating a movement similar to a natural diaphragm. The embodiments herein provide an artificial diaphragm that can mimic diaphragmatic movements of a natural diaphragm in a human body. The artificial diaphragm is embedded with intelligent nanomagnetic particles which is used for treatment of diaphragmatic paralysis.

Abstract: The embodiments herein disclose a non-invasive method of using bursts of energies/electromagnetic field energies from cells to reduce or arrest the growth rate, proliferation of cancer cells/neoplastic cells. The energy from cells induces apoptosis in cancer cells, without harming normal cells beyond their physiologic threshold of survival are provided. The embodiments herein disclose a method for treatment of cancer/neoplastic cell in human or animals within the context of cancer therapeutics. A cell culture plate is incubated. This plate serves as the source of bursts energies/electromagnetic field energies. Further with a device the bursts of energies are targeted to another plate having cells for one week. After one week the microscopic examination is done. The rate of growth of cell is six to seven pulsatile cells per square centimetre. The energy from cells kills cancer cells, induce apoptosis, stimulate growth phase in cell culture and enables harmonics therapy.

Abstract: The present invention is directed to a contractible and expandable jacket configured to encase at least a portion of a patient's heart. The jacket has a plurality of individual contractile cells with each of the cells having a first electrically conductive coil and a second electrically conductive coil spaced from the first coil. The first coil preferably defines at least in part a first periphery of an inner nucleus of the cell and the second coil preferably defining at least in part an outer portion of the cell spaced outwardly from the inner nucleus. When electrical current passes through the first and second coils in opposite directions, the cell contracts and when electrical current passes through the first and second coils in the same direction the cell expands. Each of the individual cells has conductive appendages for conducting information to and from the individual cells.

Abstract: The present invention is directed to a contractible and expandable jacket configured to encase at least a portion of a patient's heart. The jacket has a plurality of individual contractile cells with each of the cells having a first electrically conductive coil and a second electrically conductive coil spaced from the first coil. The first coil preferably defines at least in part a first periphery of an inner nucleus of the cell and the second coil preferably defining at least in part an outer portion of the cell spaced outwardly from the inner nucleus. When electrical current passes through the first and second coils in opposite directions, the cell contracts and when electrical current passes through the first and second coils in the same direction the cell expands. Each of the individual cells has conductive appendages for conducting information to and from the individual cells.

Abstract: The present invention is directed to a contractible and expandable jacket configured to encase at least a portion of a patient's heart. The jacket has a plurality of individual contractile cells with each of the cells having a first electrically conductive coil and a second electrically conductive coil spaced from the first coil. The first coil preferably defines at least in part a first periphery of an inner nucleus of the cell and the second coil preferably defining at least in part an outer portion of the cell spaced outwardly from the inner nucleus. When electrical current passes through the first and second coils in opposite directions, the cell contracts and when electrical current passes through the first and second coils in the same direction the cell expands. Each of the individual cells has conductive appendages for conducting information to and from the individual cells.