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Literatur über den Effekt von niederenergetischem gepulstem Ultraschall bei Pseudarthrosen (Non-Union):
  1. Choffie, M., Duarte, L.R.: Low-intensity ultrasound and effects on ununited fractures. Read at the Orthopaedic Health Conference, University Hospital, University of Sâo Paulö, Brazil, June 15, 1994.

  2. Duarte, L.R., Xavier, C.A., Choffie, M., McCabe, J.M.: Review of nonunions treated by pulsed low-intensity ultrasound. Société Internationale de Chirurgie Orthopedique et de Traumatologie (SICOT), P2.110:PDS80, 1996.

  3. Duarte, L.R.: The stimulation of bone growth by ultrasound, Arch. Orthop. and Trauma Surg., 101:153-159, 1983.

  4. Duarte, L.R.: The response of metallic implants in physiological medium exposed to pulsed, low-intensity ultrasound. Presented at the Annual meeting of the Biomechanics Department at Sâo Carlo campus of the University of Sâo Paulo, November, 1985.

  5. Frankel, V.H.: The effects of low-intensity pulsed ultrasound on the healing of fractures. Société Internationale de Chirurgie Orthopedique et de Traumatologie (SICOT), P1.230, 1996.

  6. Frankel, V.H., Koval,K.J., Kummer, F.J.: Ultrasound treatment of tibial nonunions. American Academy of Orthopaedic Surgeons 66th Annual Meeting, February 4-8, Anaheim, CA, 1999.

  7. Frankel, V.H.: Results of prescription use of pulsed ultrasound therapy in fracture management. In: Azabo, Z., Lewis, J.E., Fantini, G.A., Savalgi, R.S. (eds), Surgical Technology International VII, Universal Medical Press, San Francisco, pp. 389-393, 1998.

  8. Gersten, J.W.: Effect of metallic objects on temperature rises produced in tissue by ultrasound. Amer. J. Phys. Med., 37:75-82, 1988.

  9. Goodship, A.E., Kenwright, J.: The influence of induced micromovement upon the healing of experimental tibial fractures. J. of Bone and Joint Surg., 67-B,(4):650-655, 1985.

  10. Heppenstall, R.B., Frey, J.J., Ryaby, J.P., McCabe, J.M.: Noninvasive nonunion treatment by pulsed low-intensity ultrasound. 21st Triennial World Congress Société Internationale de Chirurgie Orthopédique et de Traumatologie, Sydney, Australia, 1999.

  11. Lehman, J., et al.: Ultrasonic effects as demonstrated in live pigs with surgical metallic implants. Arch. Phys. Med. And Rehabil., 483-488, 1979.

  12. Lotsova, E.I.: Effect of ultrasound on the strength of metal fixing pins for fractures and joint injuries. Mekh. Kompoz Mat., No. 3, 548-549, 1979.

  13. Xavier, C.A.M. and Duarte, L.R.: Treatment of Non-unions by Ultrasound Stimulation: First Clinical Application. Read at the meeting of the Latin-American Orthopedic Association, at the Annual Meeting of the American Academy of Orthopaedic Surgeons, San Francisco, California, January 25, 1987.

  14. Mayr, E., Rüter, A.: Fracture healing and ultrasound - Basics and first experience, Actualités en Biomatériau, ed. by Mainard, D., Merle, M., Delgoutte, J.P., Louis, J.P., Editions Romillat, (3)355-360, 1998.

  15. Mayr, E., Wagner, S., Rüter, A: Treatment of Nonunions by Means of Low-Intensity Ultrasound. Der Unfallchirurg, 268: 958-962, 1997.

  16. Mayr, E., Wagner, S., Ecker, M., Rüter, A.: Ultrasound Therapy for Nonunions (Pseudarthrosis) - 3 Case Reports. Der Unfallchirurg, 102: 191-196, 1999.

  17. Mayr, E., Frankel, V.H., Rüter, A.: Ultrasound - an alternative healing method for nonunion. Arch. Orthop. Trauma Surg., 120 (1-2): 1-8, 2000.

  18. Mcleod, K.: Fracture healing using low-level ultrasound. Presented at the IEEE International Ultrasonic Workshop, Seattle, 1995.

  19. Meani, E., Romano, C.L.: Low-intensity pulsed ultrasound for the treatment of septic nonunion. Third Congress of the European Federation of National Associations of Orthopaedics and Traumatology, Barcelona 1997.

  20. Pilla, A.A., Figueiredo, M., Nasser, P.R., Alves, J.M., Ryaby, J.T., Klein, M., Kaufmann, J.J., Siffert, R.S.: Acceleration of bone-repair by pulsed sine wave ultrasound: animal. Clinical and mechanistic studies. In Electromagnetics in Biology and Medicine, ed. by C.T. Brighton and S.R. Pollock, San Francisco Press, 331-341, 1991.

  21. Romano, C., Messina, J., Meani, E.: Low-intensity ultrasound for the treatment of infected nonunions. In Guarderni di Infezione Osteoarticolari, Masson Periodical Division, 83-93, 1999.

  22. Rubin, C.T., et al.: Regulation of bone formation by applied dynamic loads. J. of Bone and Joint Surg., 66-A, 397-402, 1984.

  23. Skoubo-Kristensen, E., Sommer, J.: Ultrasound influence on internal fixation with a rigid plate in dogs. Arch. Phys. Med. Rehabil., 63, 371-373, 1982.

  24. Wang, S.J., Lewallen, D.G., Bolander, M.E., Chao, E.Y.S., Ilstrup, D.M., Greenleaf, J.F.: Low-intensity ultrasound treatment increases strength in a rat femoral fracture model. J. of Orthop. Res., 12:40-47, 1994.

  25. Wolff, J.: The law of bone remodeling (Das gesetz der transformation der knochen). Originally published by Verlag von August Hirshwald, Berlin, 1892)- English translation by Maquet, P. and Fulong, R., published by Springer Verlag, Berlin,

  26. Xavier, C.A.M., Duarte, L.R.: Ultrasonic Stimulation of Bone Callus: Clinical Application. Rev. Brazil Orthop. 18:73-80, 1983.

  27. Ziskin, M.C.: Report on the Safety of the SAFHS device. Presented at the 10th Annual Meeting of the Orthopaedic Technician Society. Baltimore, MD, 1998.

  28. The Use of Low-Intensity Ultrasound to Accelerate the Healing of Fractures Clinton Rubin, PHD, Mark Bolander, MD, John P. Ryaby, BS, and Michael Hadjiargyrou, PHD: The Journal Of Bone & Joint Surgery83-A, No 2, February 2001

  29. Mayr E., Wagner S., Rüter A. (1997): Die niedrig intensive Ultraschalltherapie zur Behandlung von Pseudarthrosen. Hefte zu Der Unfallchirurg 268: 958-962

  30. Mayr E., Wagner S., Ecker M., Rüter A. (1999): Die Ultraschalltherapie bei Pseudarthrosen - 3 Fallbeschreibungen. Der Unfallchirurg 102: 191-196

  31. Mayr E., Frankel V., Rüter A. (2000): Ultrasound - An Alternative Healing Method for Nonunions? Arch Orthop Trauma Surg 120: 1-8

  32. Mayr E., Rüter A.: Niedrig intensiver, gepulster Ultraschall zur Beeinflussung der frischen Frakturheilung. Trauma und Berufskrankh 2000 - 2 (Suppl 4): 431-434

  33. Mayr E, Möckl Ch., Lenich A., Ecker M., Rüter A.: Ist niedrig intensiver Ultraschall bei der Behandlung von Frakturheilungsstörungen wirksam? Der Unfallchirurg (im Druck)

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Literatur über den Effekt von niederenergetischem gepulstem Ultraschall bei frischen Frakturen:
  1. Ziskin, M. C.: Report on the Safety of the Therasonics Medical Systems (Exogen. Inc.) SAFHS Unit, Model 2A. PMA P900009, Vol.3,VI.A.,-234, 1989.

  2. SAFHS Pre Market Approval (PMA) P900009-Summary of the Safety and Effectiveness, October 5, 1994.

  3. Heckman, J.D., Ryaby J. P., McCabe, J.M., Frey, J.J. and Kilcoyne, R. F.: Acceleration of Tibial Fracture-Healing by Non-Invasive, Low-Intensity Pulsed Ultrasound. J.Bone and joint Surg., 76-A:, No.1 26-34, January,1994.

  4. Kristiansen, T.K.: The Effect of Low Power Specifically Programmed Ultrasound on the Healing Time of Fresh Fractures Using a Colles' Model, Journal of Orthop. Trauma, Vol.4, No.2: 227-228 (1990)

  5. Kristiansen, T.K., Ryaby, J.P., Frey, J.J., Roe, L.R.: Accelerated Healing of Distal Radius `Fractures Using Specific Low Intensity Ultrasound: A Multi-Center, Prospective, randomized, Double-Blind and Placebo-Controlled Study, J. Bone and Joint Surg. Vol. 79-A, no.7 July 1997.

  6. Xavier, C.A.M., Duarte, L.R.: Ultrasonic Stimulation of Bone Callus: Clinical Application. Rev. Brazil Orthop., 18:73-80,1983.

  7. Duarte, L.R..: The Stimulation of Bone Growth by Ultrasound. Arch. Orthop. And Trauma Surg., 101: 153-159, 193.

  8. Pilla, A.A., Mont, M..A., Nasser, P.R., Khan, S.A., Figuieredo, M., Kaufman, J.J., Siffert, R.S.: Non-Invasive Low-Intensity Pulsed Ultrasound Accelerates Bone Healing in the Rabbit: J.Orthop. Trauma, 4: 246-253, 1990.

  9. Niedrigintensive Ultraschallbehandlung bei Frakturheilungsproblemen Edgar Mayr, Klinik für Unfall- und Wiederherstellungschirurgie, Zentralklinikum Augsburg: Trauma und Berufskrankheit 2001 - 3 (Suppl 2)
    (PDF-Datei 146 KB)

  10. Niedrig intensiver, gepulster Ultraschall zur Beeinflussung der frischen Frakturheilung Edgar Mayr, Klinik für Unfall- und Wiederherstellungschirurgie, Zentralklinikum Augsburg: Trauma und Berufskrankheit 2000 - 2 (Suppl 4)

  11. Pilla, A.A., Mont, M.A., Nasser, P.R., Khan, S.A., Figueiredo, M., Kaufman, J.J., Siffert, R.S.: Non-invasive low-intensity pulsed ultrasound accelerates bone healing in the rabbit. J. Orthop. Trauma, 4:246-253, 1990.

  12. Strauss, E., Oppenheim, W., Petrucelli, R.C.: Accelerated fracture healing with pulsed low-intensity ultrasound. Société Internationale de Chirurgie Orthopedique et de Traumatologie (SICOT), P2.111:PDS30, 1996.

  13. Warden, S.J., Bennell, K.L., McMeeken, J.M., Wark, J.D.: Acceleration of fresh fracture repair using the sonic accelerated fracture healing system: A review. Calcif. Tissue Int., 66:157-163, 2000.

  14. Mayr E., Rudzki M.-M., Rudzki M., Borchardt B., Rüter A. (2000): Beschleunigt niedrig intensiver, gepulster Ultraschall die Heilung von Skaphoidfrakturen? Handchir Mikrochir Plast Chir 32: 115-122

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Literatur über den Effekt von niederenergetischem gepulstem Ultraschall bei Kallusdistraktion:
  1. Erfahrungen mit niederenergetisch gepulstem Ultraschall bei der Knochenregeneration Andreas Schmelz, Abteilung für Unfallchirurgie, Hand-, Plastische- und Wiederherstellungschirurgie, Chirurgische Universitätskliniken Ulm: Trauma und Berufskrankheit 2000 - 2 (Suppl 4)

  2. Regenerate maturation aided by low-intensity ultrasound in callus distraction Mayr, E., Laule, A., Suger, G., Claes, L., Rüter, A.: SIROT 99, publ. By Fruend Publishing House, Ltd., 257-262, 1999.

  3. Mayr E., Laule A., Suger G., Claes L., Rüter A.: Radiographic Results of Callus Distraction Aided by Pulsed Low-Intensity Ultrasound. Jornal of Orthopaedic Trauma, August 2001

  4. Shimazaki A., Inui K., Azuma Y., Nishimura N., Yamano Y.: Low-intensity pulsed ultrasound accelerates bone maturation in distraction osteogenesis in rabbits. Journal of Bone & Joint Surgery, Sept. 2000.

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Literatur über die Grundlagenforschung zum Wirkmechanismus von niederenergetischem gepulstem Ultraschall:
  1. Hadjiargyrou, M., McLeod, K., Halsy, M., Rubin, C.T.: The temporal expression of osteopontin mRNA in the fracture callus is altered by low-intensity ultrasound. J. Bone and Miner. Res., 12: S-290, 1997.

  2. Nolte, P.A., Klein-Nuland, J., Albers, G.H.R/., Marti, R.K., Semeins, C.M., Goei, S.W., Burger, E.H.: Low-intensity ultrasound stimulates in vitro endochondral ossification. Calcif. Tissue Int., 64(suppl 1),:S62, 1999.

  3. Parvizi, J., Wu, C.C., Lewallen, D.G., Greenleaf, J.F., Bolander, M. E.: Low-intensity ultrasound stimulates synthesis of proteoglycans in rat chondrocytes by increasing expression of aggrecan gene. Journal of Orthopaedics, 17:448-494, 1999.

  4. Ryaby, J.T., Matthew, J., Pilla, A.A., Duarte-Alves, P.: Low-intensity pulsed ultrasound modulates adenylate cyclase activity and transforming growth factor beta synthesis. Electromagnetics in Biology and Medicine, ed. by C.T. Brighton and S.R. Pollock, San Francisco Press, 95-100, 1991.

  5. Ryaby, J.T., Matthew, Duarte-Alves, P.: Low-intensity pulsed ultrasound affects adenylate cyclase and TGF-ß synthesis in osteoblastic cells. Trans. Orthop. Res. Soc., 17:590, 1992.

  6. Ryaby, J.T., Bachner, E.J., Bendo, J.A., Dalton, P.F., Tannenbaum, S., Pilla, A.A.: Low-intensity pulsed ultrasound increases calcium incorporation in both differentiating cartilage and bone cell cultures. Trans. Orthop. Res. Soc., 14:15, 1989.

  7. Ryaby, J.T., Duarte-Alves, P., Pilla, A.A.: Clinically effective ultrasound affects second messenger activity in bone cell cultures. Trans BRAGS, 9:42, 1989.

  8. Ryaby, J.T., Duarte-Alves, P., Pilla, A.A.: Ultrasound and static mechanical force affect second messenger activity in bone cell cultures. Trans. Orthop. Res. Soc., 15:131, 1990.

  9. Wallace, A.L., et al.: The vascular response to fracture micromovement. Clin. Orthop. and Rel. Res., (301):281-290, 1994.

  10. Wu, C., Lewallen, D.G., Bolander, M.E., Bronk, J., Kinnick, R., Greenleaf, J.F.: Exposure to low-intensity ultrasound stimulates aggrecan gene expression by cultured chondrocytes. Trans. Orthop. Res. Soc., 21:622, 1996.

  11. Yang, K.H., Parvizi, J., Wang, S.J., Lewallen, D.G., Kinnick, R., Greenleaf, J.F., Bolander, M.E.: Exposure to low-intensity ultrasound stimulates aggrecan gene expression in a rat femur fracture model. J. of Orthop. Res., 14(5):802-809, 1996.

  12. Yang, K.H., Wang, S.J., Lewallen, D.G., Greenleaf, J.F., Oles, K., Bronk, J., Bolander, M.E.: Low-intensity ultrasound stimulates fracture healing in a rat model: biomechanical and gene expression analysis. Trans. Orthop. Res. Soc., 19:519, 1994.

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