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Shock waves induce changes in meningiomas of the brain
The effect of shock waves on biological systems has been extensively researched for its traumatic effects. Few research groups have attempted and successfully harnessed the power of shock waves for therapeutic benefits. In neurosurgical applications, shock waves have been explored as a brain dissection tool. However, the difficulties of controlling the effects of shock waves preclude the safe use of shock waves in neurosurgery. The present study focuses on understanding the effects of shock waves on meningiomas, tumours that arise from the protective layers of the brain. Freshly excised meningioma specimens, subjected to shock waves generated manually using a Reddy tube, were examined.
Keywords
Meningioma, neurosurgery, Reddy tube, shock tube, shock waves.
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- Al-Rodhan, N. R. F. and Laws, E. R., Meningioma: A historical study of the tumor and its surgical management. Neurosurgery, 1990, 26, 832–847.
- Goldwyn, R. M., Bovie: The man and the machine. Ann. Plastic Surg., 1979, 2, 135–153.
- Bulsara, K. R., Sukhla, S. and Nimjee, S. M., History of bipolar coagulation. Neurosurg. Rev., 2006, 29, 93–96; discussion 96.
- Fasano, V. A., Zeme, S., Frego, L. and Gunetti, R., Ultrasonic aspiration in the surgical treatment of intracranial tumors. J. Neurosurg. Sci., 1981, 25, 35–40.
- Goldsmith, M. F., Ultrasonic device wins neurosurgeon praise. JAMA, 1983, 250, 3270–3270.
- Epstein, F. J. and Farmer, J. P., Trends in surgery: laser surgery, use of the cavitron, and debulking surgery. Neurol. Clin., 1991, 9, 307–315.
- Kurokawa, Y., Ishiguro, M. and Kurokawa, T. A., Giant true ossified meningioma removed with surgical ultrasonic aspirator with shear wave technology. Clin. Surg., 2017, 2, 1829.
- Ma, S., Zhang, X., Lian, Y. and Zhou, X., Simulation of high explosive explosion using adaptive material point method. CMES CMES-Comp Model Eng., 2009, 39(2), 101–123.
- Vasu, S. S., Davidson, D. F. and Hanson, R. K., Jet fuel ignition delay times: Shock tube experiments over wide conditions and surrogate model predictions. Combust. Flame, 2008, 152, 125– 143.
- Horvath, T. J., Cagle, M. F., Grinstead, J. H. and Gibson, D. M., Remote observations of reentering spacecraft including the space shuttle orbiter. In 2013 IEEE Aerospace Conference, 2013, pp. 1–15.
- Lin, S. and Fyfe, W. I., Low‐density shock tube for chemical kinetics studies. Phys. Fluids, 1961, 4, 238–249.
- Reddy, K. P. J. and Sharath, N., Manually operated piston-driven shock tube. Curr. Sci., 2013, 104, 5.
- Nightingale, S. L. and Young, F. E., Marketing approval for the lithotripter. Isr. J. Med. Sci., 1986, 22, 519–523.
- Sackmann, M., Pauletzki, J., Sauerbruch, T., Holl, J., Schelling, G. and Paumgartner, G., The Munich Gallbladder Lithotripsy Study. Results of the first 5 years with 711 patients. Ann. Intern. Med., 1991, 114, 290–296.
- Sauerbruch, T., Holl, J., Sackmann, M., Werner, R., Wotzka, R. and Paumgartner, G., Disintegration of a pancreatic duct stone with extracorporeal shock waves in a patient with chronic pancreatitis. Endoscopy, 1987, 19, 207–208.
- Moya, D., Ramón, S., Schaden, W., Wang, C.-J., Guiloff, L. and Cheng, J.-H., The role of extracorporeal shockwave treatment in musculoskeletal disorders. JBJS, 2018, 100, 251–263.
- Iro, H. et al., Shockwave lithotripsy of salivary duct stones. Lancet, 1992, 339, 1333–1336.
- Nakagawa, A. et al., Application of shock waves as a treatment modality in the vicinity of the brain and skull. J. Neurosurg., 2003, 99, 156–162.
- Takayama, K. and Ohtani, K., Applications of shock wave research to medicine. WIT Trans. Modell. Simulat., 2005, 41, 9.
- Kodama, T., Takayama, K. and Uenohara, H., A new technology for revascularization of cerebral embolism using liquid jet impact. Phys. Med. Biol., 1997, 42, 2355–2367.
- Klein, R. M., Wolf, E. D., Wu, R. and Sanford, J. C., Highvelocity microprojectiles for delivering nucleic acids into living cells. Biotechnology, 1992, 24, 384–386.
- Battula, N., Menezes, V. and Hosseini, H., A miniature shock wave driven micro-jet injector for needle-free vaccine/drug delivery. Biotechnol. Bioeng., 2016, 113, 2507–2512.
- Tominaga, T. et al., Application of underwater shock wave and laserinduced liquid jet to neurosurgery. Shock Waves, 2006, 15, 55.
- Nakagawa, A., Kusaka, Y., Hirano, T., Saito, T., Shirane, R., Takayama, K. and Yoshimoto, T., Application of shock waves as a treatment modality in the vicinity of the brain and skull. J. Neurosurg., 2003, 99(1), 156–162.
- Guo, P., Gao, F., Zhao, T., Sun, W., Wang, B. and Li, Z., Positive effects of extracorporeal shock wave therapy on spasticity in poststroke patients: a meta-analysis. J. Stroke Cerebrovasc. Dis., 2017, 26, 2470–2476.
- Oh, J. H., Park, H. D., Han, S. H., Shim, G. Y. and Choi, K. Y., Duration of treatment effect of extracorporeal shock wave on spasticity and subgroup – analysis according to number of shocks and
- application site: a meta-analysis. Ann. Rehabil. Med., 2019, 43, 163–177.
- Rubovitch, V. et al., A mouse model of blast-induced mild traumatic brain injury. Exp. Neurol., 2011, 232, 280–289.
- Bhat, D. I., Shukla, D., Mahadevan, A., Sharath, N. and Reddy, K. P. J., Validation of a blast induced neurotrauma model using modified Reddy tube in rats: A pilot study. Indian J. Neurotrauma, 2014, 11, 91–96.
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