Tailored laser pulses for surgical applications

We claim: 1 . A laser system, comprising: a power supply configured to generate a plurality of electrical pulses; an optical pump configured to generate optical energy in response to the plurality of electrical pulses; a lasing medium optically coupled to the optical pump, the lasing medium configured to output laser pulses in response to the optical energy; and a controller coupled to the power supply, the controller configured to cause the power supply to generate the plurality of electrical pulses, wherein the plurality of electrical pulses comprises: one or more electrical pre-pulses configured to cause the optical pump to generate a first portion of the optical energy, the first portion of the optical energy configured to excite the lasing medium to an energy level below a lasing threshold of the lasing medium, and a plurality of electrical excitation-pulses configured to cause the optical pump to generate a second portion of the optical energy, the second portion of the optical energy to excite the lasing medium above the lasing threshold of the lasing medium and output a plurality of laser pulses. 2 . The laser system of claim 1 , wherein the plurality of laser pulses overlaps to form a quasi-continuous laser pulse. 3 . The laser system of claim 2 , wherein a pulse width of the quasi-continuous laser pulse is between 250 microseconds (μs) to 10 milliseconds (ms). 4 . The laser system of claim 2 , wherein a power of the quasi-continuous laser pulse is between 100 watts (W) and 1 kilowatt (kW). 5 . The laser system of claim 1 , wherein each electrical pulse of the plurality of electrical pulses has a pulse width between 10 microseconds (μs) and 1000 μs. 6 . The laser system of claim 5 , wherein the pulse width of each electrical pulse of the plurality of electrical pulses is the same. 7 . The laser system of claim 1 , wherein a pulse delay between adjacent electrical pulses of the plurality of electrical pulses is between 10 microseconds (μs) and 1000 μs. 8 . The laser system of claim 7 , wherein the pulse delay between each of the adjacent electrical pulses is the same. 9 . The laser system of claim 1 , wherein the plurality of laser pulses has a frequency greater than or equal to 1 kilohertz (kHz). 10 . The laser system of claim 1 , wherein the lasing medium includes Ho:YAG, Tm:YAG, Tm:Ho:YAG, Er:YAG, Er:YLF, Nd:YAG, Tm-fiber, and/or CTH:YAG. 11 . A laser system a power supply configured to generate a plurality of electrical pulses; an oscillator comprising: an optical pump configured to generate optical energy in response to the plurality of electrical pulses, and a lasing medium configured to receive the optical energy; a cooling sub-system configured to cool the oscillator; and a controller coupled to the power supply, the controller configured to cause the power supply to generate the plurality of electrical pulses, wherein the plurality of electrical pulses comprises: one or more electrical pre-pulses configured to cause the optical pump to generate a first portion of optical energy, the first portion of the optical energy configured to excite the lasing medium to an energy level below a lasing threshold of the lasing medium, and a plurality of electrical excitation-pulses configured to cause the optical pump to generate a second portion of the optical energy, the second portion of the optical energy to excite the lasing medium above the lasing threshold of the lasing medium and output a plurality of laser pulses. 12 . The laser system of claim 11 , wherein the plurality of laser pulses overlaps to form a quasi-continuous laser pulse and wherein a pulse width of the quasi-continuous laser pulse is between 250 microseconds (μs) to 10 milliseconds (ms). 13 . The laser system of claim 11 , wherein the plurality of laser pulses overlaps to form a quasi-continuous laser pulse and wherein a power of the quasi-continuous laser pulse is between 100 watts (W) and 1 kilowatt (kW). 14 . The laser system of claim 11 , wherein each electrical pulse of the plurality of electrical pulses has a pulse width between 10 microseconds (μs) and 1000 μs, wherein a pulse delay between adjacent electrical pulses of the plurality of electrical pulses is between 10 microseconds (μs) and 1000 μs, or wherein each electrical pulse of the plurality of electrical pulses has a pulse width between 10 microseconds (μs) and 1000 μs and a pulse delay between adjacent electrical pulses of the plurality of electrical pulses is between 10 microseconds (μs) and 1000 μs. 15 . The laser system of claim 11 , wherein a pulse width of each electrical pulse of the plurality of electrical pulses is the same, wherein a pulse delay between adjacent electrical pulses of the plurality of electrical pulses is the same, or wherein the pulse width of each electrical pulse of the plurality of electrical pulses is the same and the pulse delay between adjacent electrical pulses of the plurality of electrical pulses is the same. 16 . The laser system of claim 11 , wherein the lasing medium includes Ho:YAG, Tm:YAG, Tm:Ho:YAG, Er:YAG, Er:YLF, Nd:YAG, Tm-fiber, and/or CTH:YAG. 17 . The laser system of claim 11 , wherein the plurality of electrical pulses comprises a first set of electrical pulses and a second set of electrical pulses and wherein at least one of (i) a pulse width, (ii) a pulse delay, or (iii) a pulse magnitude of the first set of pulses is different from the second set of pulses. 18 . A method for a controller of a laser system comprising a power supply configured to generate a plurality of electrical pulses, an optical pump configured to generate optical energy in response to the plurality of electrical pulses, and a lasing medium configured to receive the optical energy, the method comprising: sending control signals to the power supply, the control signals configured to cause the power supply to generate a plurality of electrical pulses, wherein the plurality of electrical pulses comprises: one or more electrical pre-pulses configured to cause the optical pump to generate a first portion of optical energy, the first portion of the optical energy configured to excite the lasing medium to an energy level below a lasing threshold of the lasing medium, and a plurality of electrical excitation-pulses configured to cause the optical pump to generate a second portion of the optical energy, the second portion of the optical energy to excite the lasing medium above the lasing threshold of the lasing medium and output a plurality of laser pulses. 19 . The method of claim 18 , wherein each electrical pulse of the plurality of electrical pulses has a pulse width between 10 microseconds (μs) and 1000 μs, wherein a pulse delay between adjacent electrical pulses of the plurality of electrical pulses is between 10 microseconds (μs) and 1000 μs, or wherein each electrical pulse of the plurality of electrical pulses has a pulse width between 10 microseconds (μs) and 1000 μs and a pulse delay between adjacent electrical pulses of the plurality of electrical pulses is between 10 microseconds (μs) and 1000 μs. 20 . The method of claim 18 , wherein a pulse width of each electrical pulse of the plurality of electrical pulses is the same, wherein a pulse delay between adjacent electrical pulses of the plurality of electrical pulses is the same, or wherein the pulse width of each electrical pulse of the plurality of electrical pulses is the same and the pulse delay between adjacent electrical pulses of the pluralit