Materials
| Name | Company | Catalog Number | Comments |
| Iscove's Modified Dulbecco's Medium w/ NaHCO3 & 25mM Hepes | Life Technologies | 12440079 | |
| Amphotericin B Solution | Sigma-Aldrich | A2942 | |
| Penicillin/Streptomycin 100x Solution | Life Technologies | 10378-016 | |
| Fetal Bovine Serum | Sigma-Aldrich | 12105 | |
| Branson SLPe 40kHz Cell Disruptor with 3" (25mm) Cuphorn | Branson Ultrasonics | 101-063-726 | sonication device |
| Brisk Heat SDC Benchtop Digital temperature Controler w/ 1000 ml Beaker Heater | Brisk Heat | SDCJF1A-GBH1000-1 | heater used for temperature control |
| Beckman-Coulter Z2 Cell Sizer with AccuComp® Software | Beckman-Coulter | 6605700 | |
| Bio-Rad TC20 Automated Cell Counter | Bio-Rad | 145-0102 | |
| Gentamicin 50 mg/ml | Sigma-Aldrich | G1397 | |
| Trypan Blue Solution | Sigma-Aldrich | T8154 | |
| Falcon 50 ml & 25 ml Vented Culture Flasks | Fisher Scientific | 353082 | |
| Lonza L-Glutamine 200 mM 0.85% NaCl | Lonza | 17-605C | |
| Seal-Rite 1.5 ml Microcentrifuge Tubes | USA Scientific | 1615-5510 | |
| Beckman-Coulter Accuvette ST 25 ml Vials and caps | Beckman-Coulter | A35473 | |
| AccuJet Pro Auto Pipet | BrandTech Scientific | 26330 | |
| USA Scientific 10 ml Disposable Serological Pipets | USA Scientific | 1071-0810 | |
| Tip One 100 μl and 1,000 μl Filter Tips | USA Scientific | 1120-1840, 1126-7810 | |
| 100 μl Micropipette | Wheaton | 851164 | |
| 1,000 μl Micropipette | Wheaton | 851168 | |
| BioRad Dual Chamber Counting Slides | Bio-Rad | 145-0015 | |
| Forma Scientific Dual chamber water jacketed Incubator | Forma Scientific | 3131 | |
| Tektronix DPO 2002B Digital Phosphor Oscilloscope | Tektronix | DPO2002B | used to measure the ultrasonic waveform |
| PPB MegaSonics Model PB-500 Ultrasonic Energy Meter | PPB Megasonics | PB-500 | used to assess the sound intensity in W/cm2 |
| Teledyne RESON TC4013-1 Hydrophone | Teledyne | TC4013-1 | connects to the oscilloscope |
| Wheaton 250 ml Flasks | Sigma-Aldrich | Z364827 | |
| 20 ml Glass Scintillation Vials | Sigma-Aldrich | Z190527 | |
| Beckman-Coulter Isotonic Saline Solution | Beckman-Coulter | N/A | diluent for Z2 counter |
| Chloroform 99% | Sigma-Aldrich | C2432 | |
| Ethanol 200 Proof Anhydrous | Sigma-Aldrich | 459836 | |
| Mineral Oil | N/A | ||
| XTT Cell Proliferation Assay Kit | ATCC | 30-1011K | |
| 96-Well Microplate Reader | Cole-Palmer | EW-13055-54 | |
| U937 Human Monocytic Leukemia Cells | ATCC | CRL1593.2 | |
| THP1 Human Monocytic Leukemia Cells | ATCC | TIB-202 |
References
- Trendowski, M.
- Semins, M. J., Trock, B. J., Matlaga, B. R. The effect of shock wave rate on the outcome of shock wave lithotripsy: A meta-analysis. J Urol. 179 (1), 194-197 (2008).
- Pace, K. T., Ghiculete, D., Harju, M., Honey, R. J. Shock Wave Lithotripsy at 60 or 120 shocks per minute: A randomized, double-blind trial. J Urol. 174 (2), 595-599 (2005).
- McClain, P. D., Lange, J. N., Assimos, D. G. Optimizing shock wave lithotripsy: a comprehensive review. Rev Urol. 15 (2), 49-60 (2013).
- Mitragotri, S. Healing sound: the use of ultrasound in drug delivery and other therapeutic applications. Nat Rev Drug Discov. 4 (3), 255-260 (2005).
- Cordeiro, E. R., Cathelineau, X., Thüroff, S., Marberger, M., Crouzet, S., de la Rosette, J. J. High-intensity focused ultrasound (HIFU) for definitive treatment of prostate cancer. BJU Int. 110 (9), 1228-1242 (2012).
- Li, P. Z., et al. High-intensity focused ultrasound treatment for patients with unresectable pancreatic cancer. Hepatobiliary Pancreat Dis Int. 11 (6), 655-660 (2012).
- Xiaoping, L., Leizhen, Z. Advances of high intensity focused ultrasound (HIFU) for pancreatic cancer. Int J Hyperthermia. 29 (7), 678-682 (2013).
- Lukka, H., et al. High-intensity focused ultrasound for prostate cancer: a systematic review. Clin Oncol (R Coll Radiol). 23 (2), 117-127 (2011).
- So, A. I. HIFU ablation is not a proven standard treatment for localized prostate cancer). Can Urol Assoc J. 5 (6), 424-426 (2011).
- Crouzet, S., et al. Whole-gland ablation of localized prostate cancer with high-intensity focused ultrasound: oncologic outcomes and morbidity in 1002 patients. Eur Urol. 65 (5), 907-914 (2014).
- Tezel, A., Mitragotri, S. Interactions of inertial cavitation bubbles with stratum corneum lipid bilayers during low-frequency sonophoresis. Biophys J. 85, 3502-3512 (2003).
- Tang, H., Wang, C. C., Blankschtein, D., Langer, R. An investigation of the role of cavitation in low-frequency ultrasound-mediated transdermal drug transport. Pharm Res. 19 (8), 1160-1169 (2002).
- Ueda, H., Mutoh, M., Seki, T., Kobayashi, D., Morimoto, Y. Acoustic cavitation as an enhancing mechanism of low-frequency sonophoresis for transdermal drug delivery. Biol Pharm Bull. 32 (5), 916-920 (2009).
- Trendowski, M., Yu, G., Wong, Y., Aquafondata, C., Christen, T., Fondy, T. P. The real deal: Using cytochalasin B in sonodynamic therapy to preferentially damage leukemia cells. Anticancer Res. 34 (5), 2195-2202 (2014).
- Sonifier Cell Disrupter Model SLPeEDP. , Branson Ultrasonics Corporation. Available from: http://www.emersonindustrial.com/en-US/documentcenter/BransonUltrasonics/Sonifier_Brochure.pdf (2010).
- Lagneaux, L., et al. Ultrasonic low-energy treatment: A novel approach to induce apoptosis in human leukemic cells. Exp Hematol. 30 (11), 1293-1301 (2002).
- Krasovitskia, B., Frenkelb, V., Shohama, S., Kimmel, K. Intramembrane cavitation as a unifying mechanism for ultrasound-induced bioeffects. Proc Natl Acad Sci USA. 108 (8), 3258-3263 (2011).
- Sundaram, J., Mellein, B. R., Mitragotri, S. An experimental and theoretical analysis of ultrasound-induced permeabilization of cell membranes. Biophys J. 84 (5), 3087-3101 (2003).
- Mizrahi, N., et al. Low intensity ultrasound perturbs cytoskeleton dynamics. Soft Matter. 8 (8), 2438-2443 (2012).
- Chen, X., Leow, R. S., Hu, Y., Wan, J. M., Yu, A. C. Single-site sonoporation disrupts actin cytoskeleton organization. J R Soc Interface. 11 (95), 20140071 (2014).
- Trendowski, M., et al. Preferential enlargement of leukemia cells using cytoskeletal-directed agents and cell cycle growth control parameters to induce sensitivity to low frequency ultrasound. Cancer Lett. In press, (2015).
- Dumontet, C., Sikic, B. I. Mechanisms of action of and resistance to antitubulin agents: Microtubule dynamics, drug transport, and cell death. J Clin Oncol. 17 (3), 1061-1070 (1999).
- Verrills, N. M., Kavallaris, M. Improving the targeting of tubulin-binding agents: lessons from drug resistance studies. Curr Pharm Des. 11 (13), 1719-1733 (2005).
- Trendowski, M. The inherent metastasis of leukaemia and its exploitation by sonodynamic therapy. Crit Rev Oncol Hematol. In press, (2014).
- Trendowski, M., Wong, V., Wellington, K., Hatfield, S., Fondy, T. P. Tolerated doses in zebrafish of cytochalasins and jasplakinolide for comparison with tolerated doses in mice in the evaluation of pre-clinical activity of microfilament-directed agents in tumor model systems in vivo. In Vivo. 28 (6), 1021-1031 (2014).
