Abstract: The present invention relates to a vaccine composed of at least one immune stimulant and radiofrequency waves using capacitive coupling and to a method, especially an in-situ and in vivo vaccination method for treatment of primary cancer and its metastases even in disseminated cell-states, which cannot be detected by presently available imaging methods or for prevention of relapse of the cancer disease, and especially for enabling and supporting the patient's own immune system to recognize and kill the cancer cells and to build up a memory to prevent relapse of a cancer disease.
Type:
Grant
Filed:
August 26, 2013
Date of Patent:
October 6, 2020
Assignee:
XAX KFT.
Inventors:
Gabor Andocs, Oliver Szasz, Andras Szasz, Nora Iluri
Abstract: The present invention relates to a radiofrequency (RF) hyperthermia device for personalized treatment and diagnosis using capacitive coupling and without dipole antenna comprising a radiofrequency source, an amplifier, a sensor and a modulation signal input/generator, wherein the radiofrequency source produces a source signal which is modulated by the modulation signal input/generator using the phase information generated by homeostasis of the target to generate a modulated source signal, the modulated source signal is amplified by the amplifier and directed to a target, and the sensor detects the phase information generated by homeostasis of the target to provide a feedback signal, wherein the feedback signal modulates the source signal to generate a personalized modulated signal. This radiofrequency (RF) hyperthermia device is designed for personalized treatment and diagnosis of a target such as a patient or a malignant or tumorous area within a patient.
Abstract: Method and a measuring device for measuring and evaluating a measurable signal emitted by a system being investigated during operation or in response to an external excitation. The device includes a signal receiving unit, an output unit and an evaluating unit. The latter includes elements for Fourier transforming the time dependant signal captured by the receiving unit and characteristic of the system as a whole, the signal is transformed directly in its captured form; elements for calculating the power density function of the Fourier transform; elements for calculating an invariant quantity in the form of the exponent ? of the power density function versus the frequency, as well as elements for providing data indicative of the invariant quantity obtained to the output unit.
Abstract: Method and a measuring device for measuring and evaluating a measurable signal emitted by a system being investigated during operation or in response to an external excitation. The device includes a signal receiving unit, an output unit and an evaluating unit. The latter includes elements for Fourier transforming the time dependant signal captured by the receiving unit and characteristic of the system as a whole, the signal is transformed directly in its captured form; elements for calculating the power density function of the Fourier transform; elements for calculating an invariant quantity in the form of the exponent ? of the power density function versus the frequency, as well as elements for providing data indicative of the invariant quantity obtained to the output unit.