An aspiration system includes a pump and a control system in communication with the pump. The control system includes a microcontroller, an antenna configured to receive a signal, and a pump control board in communication with the microcontroller. The antenna is in communication with the microcontroller. Upon receiving the signal, the pump control board operates the pump to create negative pressure according to the signal.

A pulse control method and apparatus, an ablation device (110) and system (100), and a storage medium. The pulse control method comprises: controlling a pulse generator (112) to output a nanosecond pulse sequence and a millisecond pulse sequence, the amplitude of the nanosecond pulse sequence being greater than a preset first threshold voltage, and the amplitude of the millisecond pulse sequence being less than a preset second threshold voltage. The nanosecond pulse sequence having the amplitude greater than the threshold voltage cooperates with the millisecond pulse sequence having the amplitude less than the threshold voltage, such that the effective ablation range can be enlarged, the ablation is more thorough, the muscle contraction amplitude can be effectively reduced, or the muscle contraction probability is reduced, the treatment experience feeling of a patient can be improved, and the use of anesthetics can be reduced or even not needed.

The present invention relates to the field of biomedical engineering and medical treatment of diseases and disorders. Methods, devices, and systems for in vivo treatment of cell proliferative disorders are provided. In embodiments, the methods comprise the delivery of high-frequency bursts of bipolar pulses to achieve the desired modality of cell death. More specifically, embodiments of the invention relate to a device and method for destroying aberrant cells, including tumor tissues, using high-frequency, bipolar electrical pulses having a burst width on the order of microseconds and duration of single polarity on the microsecond to nanosecond scale. In embodiments, the methods rely on conventional electroporation with adjuvant drugs or irreversible electroporation to cause cell death in treated tumors. The invention can be used to treat solid tumors, such as brain tumors.

An aspiration system includes a pump and a control system in communication with the pump. The control system includes a microcontroller, an antenna configured to receive a signal, and a pump control board in communication with the microcontroller. The antenna is in communication with the microcontroller. Upon receiving the signal, the pump control board operates the pump to create negative pressure according to the signal.

An aspiration system includes a pump and a control system in communication with the pump. The control system includes a microcontroller, an antenna configured to receive a signal, and a pump control board in communication with the microcontroller. The antenna is in communication with the microcontroller. Upon receiving the signal, the pump control board operates the pump to create negative pressure according to the signal.

An aspiration system includes a pump and a control system in communication with the pump. The control system includes a microcontroller, an antenna configured to receive a signal, and a pump control board in communication with the microcontroller. The antenna is in communication with the microcontroller. Upon receiving the signal, the pump control board operates the pump to create negative pressure according to the signal.

A laser system for medical treatment is disclosed which comprises a pump, wherein the laser system is adapted to be operated in pulsed operation so that at least one laser pulse of a temporally limited pulse duration (T.sub.p) is generated. The generated laser pulse irradiates some part of the human or animal body so that a two-dimensional laser spot S is located on the top layer of the irradiated part of the human or animal body. The pump power of the pump of the laser system is modulated in such a way that the cumulative energy E.sub.S(T.sub.p/2) which is delivered by said laser pulse to said laser spot S during the first half of the pulse duration is less than 45% of the energy E.sub.S(T.sub.p) which is delivered by said laser pulse to said laser spot S during the entire pulse duration T.sub.p.

Method for generating a shaped laser pulse in a lithotripter characterized in that if the pulse duration is divided into four intervals of equal length, less than 25% of the energy of the pulse is emitted in the first of those intervals, and in that the maximum intensity of the pulse is first reached in the second, third or fourth time interval, and wherein the intensity reached after the start of the third and/or forth interval is at least once the same as or higher than the maximum intensity reached in the second interval.

An extracorporeal shock wave lithotripter and a charging and discharging circuit for an extracorporeal shock wave lithotripter are disclosed. The charging circuit is formed by a resistor and a capacitor, and the discharging circuit is formed by the capacitor, a high-voltage switch and a shock wave source apparatus. The capacitance of the capacitor is 1.5 F2.5 F, the pressure peak value of the focus of shock waves generated by discharging to the shock wave source apparatus by the capacitor is 6 Mpa30 MPa, a positive pressure period of the bottom pulse width is 3 s and a negative pressure period is 5 s.

An aspiration system includes a pump and a control system in communication with the pump. The control system includes a microcontroller, an antenna configured to receive a signal, and a pump control board in communication with the microcontroller. The antenna is in communication with the microcontroller. Upon receiving the signal, the pump control board operates the pump to create negative pressure according to the signal.