Lithotripsy is a medical procedure involving the physical destruction of hardened masses like kidney stones, bezoars or gallstones. The term is derived from the Greek words meaning "breaking stones".
Uses
Lithotripy is a procedure involving the physical destruction of hardened masses like kidney stones, bezoars or gallstones.
Surgery was the only method to remove stones too large to pass until Frenchsurgeon and urologistJean Civiale in 1832, invented a surgical instrument to crush stones inside the bladder without having to open the abdomen. To remove a calculus, Civiale inserted his instrument through the urethra and bored holes in the stone. Afterwards, he crushed it with the same instrument and aspirated the resulting fragments or let them flow normally with urine. Lithotripsy replaced lithotrites as the most common treatment beginning in the mid-1980s. In ESWL, external shockwaves are focused at the stone to pulverize it. Ureteroscopic methods use a rigid or flexible scope to reach the stone and direct mechanical or light energy is applied. Endoscopy can use lasers, as well as various modes of energy delivery: ultrasound, electrohydraulic, and lasers. ESWL was first used on kidney stones in 1980, and is also applied to gallstones and pancreatic stones. External shockwaves are focused and pulverize the stone which is located by imaging. The first shockwave lithotriptor approved for human use was the Dornier HM3 derived from a device used for testing aerospace parts. Second generation devices used piezoelectric or electromagnetic generators. American Urological Association guidelines consider ESWL a potential primary treatment for stones between 4 mm and 2 cm. Electrohydraulic lithotripsy is an industrial technique for fragmenting rocks by using electrodes to create shockwaves that was applied to bile duct stones in 1975. It can damage tissue and is mostly used in biliary tract specialty centers. Pneumatic mechanical devices have been used with endoscopes, commonly for large and hard stones. Laser lithotripsy was introduced in the 1980s. Pulsed dye lasers emit 504 nm light that is delivered to the stone by optical fibers through a scope. Holmium:YAG lasers were developed more recently and produce smaller fragments.