The invention relates to a device for neurovascular stimulation, at least comprising: at least one brain activity sensor, at least one cardiovascular sensor, at least one computing unit and at least one output unit. The computing unit comprises at least one task algorithm, wherein signals of at least the brain activity sensor and the cardiovascular sensor can be received by the computing unit, and wherein a task, which is in correlation with at least the signals from at least the brain activity sensor and the signals of the cardiovascular sensor, can be determined by means of the task algorithm and can be output by means of the output unit.

The present disclosure relates to an organism trapping device that includes a vibration wave generator configured to generate frequency ranges from 1.00 to 1.67 Hz (Hertz), an inciting engine communicatively coupled with the vibration wave generator, and configured to generate signals representing vibration parameters based on the generated frequency, a walled container operatively coupled with the inciting engine and adapted to contain fluid and receives the generated signals to simulate flow of blood in human blood vessels based on the vibration parameters to attract number of organisms towards the device, a fumigating agent adapted to compress the number of organisms entering into the device, sensors configured to sense an entry of number of organisms into the device, and a processor communicatively coupled with the sensor and activates the fumigating agent based on the signal received from the sensor. The present disclosure also relates to method of trapping organisms.

A Pranayam Machine disclosed in present invention is a device that facilitates the performance of certain yogic breathing practices without the use of hands, it provides two mechanisms, mechanisms 1 and mechanism 2 in which parts that are common in both the mechanisms, are Servo motor (3), motor to fork coupling (4), Belts (6) and Ear plugs (7). Design of Forehead mounting (2) and Fork (5) differs depending on mechanism 1 and mechanism 2. This Forehead mounting (2) precisely fits on one's Head (1) through adjusting Belts (6). The major difference between Forehead mounting (2) in both the mechanisms, is that in mechanism 1, Servo motor (3) is mounted perpendicular to the surface and the Fork (5) is mounted perpendicular to the Servo motor (3) shaft axis, whereas in mechanism 2 Servo motor (3) is mounted parallel to the surface and the Fork (5) is mounted along the axis of the Servo motor (3).

A system (100) for training a subject such that the subject includes an input unit (102) having a number of sensors (112) that are configured to detect a number of physiological parameters of a user. A processing unit (104) is configured to receive the number of physiological parameters for comparing the number of physiological parameters with a set of predefined physiological parameters to generate a baseline signal (116A). An output unit (106) is configured to generate an instruction signal (118A) upon receipt of the baseline signal (116A) and a regulating unit (108) that is configured to regulate a speed of a game associated with a gamification engine (110) and a speed of an exercising apparatus (200) upon receipt of the instruction signal (118A).

A method for characterizing a brain electrical signal comprising forming a temporo-spectral decomposition of the signal to form a plurality of time resolved frequency signal values, associating each instance of the signal value with a predetermined function approximating a neurological signal to form a table of coefficients collectively representative of the brain electrical signal.

Disclosed herein is a ventilator system and method, for alveolar micro-circulation enhancement using pulse cycle harmonized ventilation pressure modulation of a patient. The system includes a sensor unit, a controller unit and a supply unit. The sensor unit is configured to sense a set of physiological parameters to determine one or more cardiovascular activities of the patient. The controller unit is communicatively coupled to the sensor unit, and is configured to determine a dynamic pattern of an oxygenated air supply for the patient based on the sensed cardiovascular activity. The supply unit is communicatively coupled to the controller unit and is configured to supply the determined pressure wave to create a dynamic alteration in the air flow pattern of the ventilated air to the patient in response to the cardiovascular activity. Some embodiments of the system also represent the system as an air flow controlling apparatus, capable be coupled to any ventilator system internally or externally to control the flow of air in the dynamic pattern.