Aaron, R. K.; Ciombor, D. M.; Jolly, G. Stimulation of endo-chondml ossification by low-energy pulsing electromagnetic fields. J. Bone Mineral Res. 4:227-233; 1989.
Adey, R.W. (1992). ELF magnetic fields and promotion of cancer: experimental studies. Interaction Mechanisms of Low-Level Electromagnetic Fields in Living Systems (eds. B. Norden and C. Ramel). Oxford University Press, Oxford, pp 23-46.
Adey, R.W. (1993). Electromagnetics in biology and medicine. Modern Radio Science (ed. H. Matsumoto). Oxford University Press, Oxford, pp. 277-245.
Adey, R.W. (1991). Signal functions of brain electrical rhythms and their modulation by external electromagnetic fields. Induced Rhythms of the Brain (eds. E. Basar and T. Bullock). Birkauser, Boston, pp 323-351.
Adey, W. R. Some fundamental aspects of biological effects of extremely low frequency (ELF). In: Grandolfo, M.; Michaelson, S. M., eds. Biological effects and dosimetry of ionizing electromagnetic fields. New York: Plenum Publish-lng; 1983:561-580.
Anderson, J. C.; Eriksson, C. Piezoelectric properties of dry and wet bone. Nature 227:491--492; 1970.
Auerbach, G. D.; Marx, S. J.; Spiegel, A.M. Parathyroid hormone, calcitonin and the calciferols. In: Wilson, J. D.; Foster, W. D., eds. Williams' textbook of endocrinology. 7th ed. New York: Saunders; 1985:1137-1217.
Bassett, C. A. L. Pulsing electromagnetic fields: A new method to modify cell behavior in calcified and noncalcified tissues. Calc. Tiss. Res. 34:1-8; 1982.
Bassett, C. A. L. Biomedical implications of pulsing electromagnetic fields. Surg. Rounds 1983:22-31; 1983.
Bassett, C. A. L.; Becker, R. O. Generation of electric potentials in bone in response to mechanical stress. Science 137:1063-1064; 1962.
Bassett, C. A. L.; Hermann, I. The effect of electrostatic fields on macromolecular synthesis by fibroblasts in vitro. J. Cell Biol. 39:9a; 1968.
Bassett, C. A. L.; Mitchell, S. N.; Gaston, S. R. Pulsing electromagnetic field treatment in ununited fractures and failed arthrodeses. JAMA 247:623-628; 1982.
Bassett, C. A. L.; Pawluk, R. J.; Becker, R. O. Effect of electric currents on bone in vivo. Nature 204:652-654; 1964.
Bassett, C. A. L.; Pawluk, R. J.; Pilla, A. A. Acceleration of fracture repair by electromagnetic fields. A surgically non-invasive method. Ann. N Y Acad. Sci. 238:242-262; 1974.
Bassett, C. A. L.; Pilla, A. A.; Pawluk, R. J. A non-operative salvage of surgically-resistant pseudarthroses and non-unions by pulsing electromagnetic fields. Clin. Orthop. Rel. Res. 124: 128-143; 1977.
Becker, R. O. The significance of bioelectric potentials. Bioelectrochem. Bioenerget. 1:187-199; 1978.
Berridge, M. The molecular basis of communication within the cell. Sci. Am. 253:142-150; 1985.
Borgens, R. B. Endogenous ionic currents traverse intact and damaged bone. Science 225:478--482; 1984.
Brighton, C. T.; Black, J.; Friedenberg, Z. B.; Esterhai, J. L.; Day, L. J.; Cormoily, J. F. A multicenter study of the treatment of non-union fractures with constant direct current. J. Bone and Joint Surg. 63A:2-12; 1981.
Brighton, C. T.; Friedenberg, Z. B. Electrical stimulation and oxygen tension. Ann. N Y Acad. Sci. 238:314-320; 1974.
Brighton, C. T. Bone reaction to varying amounts of direct current. Surg. Gynecol. Obstet. 131:894; 1970.
Brighton, C. T.; Friedenberg, Z. B.; Black, J. Evaluation of the use of constant direct current in the treatment of non-union. In:
Brighton, C. T., ed. Electrical properties of bone and cartilage. New York: Plenum Press; 1979:519-545.
Brighton, C. T.; Unger, A.; Starebough, J. In vitro growth of bovine articular cartilage chondrocytes in various capacitatively coupled electrical fields. J. Orthop. Res. 2:15-22; 1984.
Cain, C. D. Pulsed electromagnetic field modifications on bone metabolism in vitro: Influences on cyclic AMP ornithine decarboxylase and bone resorption. Riverside University of California, Department of Biochemistry; 19 Ph.D. dissertation.
Cain, C. D.; Adey, W. R.; Luben, R. A. Evidence that. puI: electromagnetic fields inhibit coupling of adenylate cyel,, by parathyroid hormone in bone cells. J. Bone Min. Res.I 437-441; 1987.
Cain, C. D.; Luben, R. A. Pulsed EMF effects on PTH stimulated cAMP accumulation and bone resorption in mouse calvariae. In: Anderson, L. E.; Kelman, B. J.; Weigel, R. J., eds. Interaction of biological systems with ELF. Richland, WA: Battelle Laboratories Press; Conference Publication No. 24; 1987, 269-278.
Canalis, E. Regulation of bone remodeling. In: M. J. Fayus, Primer on metabolic bone diseases. Kelseyville, CA: American Society for Bone and Mineral Research; 1990:23-25.
Cheng, N., The effects of electric currents on ATP Generation, Protein Synthesis, and membrane transport in rat skin. Orth Surg. 1982
Cochran, G. V. B.; Pawluk, R. J.; Bassett, C. A. L. Electrum chanical characteristics of bone under physiologic moist conditions. Clin. Orthop. Rel. Res. 58:250-269; 1968.
Colacicco, G.; Pilla, A. A. Chemical, physical and biological correlations in the Ca-uptake by embryonal chick tibia in vitro. Biochem. and Bioenerget. 10:119-131; 1983.
Compere, C. L. Electromagnetic fields and bones. JAMA 247: 669; 1982.
Cone, C. D. Unified theory on the basic mechanism of normal mitotic control and oncogenesis. J. Theor. Biol. 30:151-181; 1971.
Cook, I.; Bassett, C. A. L. Effects of tissue type and orientation of electromagnetically induced voltages. J. Bone Joint Surg. 7:361-366; 1983.
Czech, M. Signal transmission by the insulin-like growth factors. Cell 59:235-238; 1989.
Darnell, J.; Lodish, H.; Baltimore, D. Cell-to-cell signaling. Hormones and receptors. Molecular cell biology. Second ed. New York: W. H. Freeman; 1990:709-763.
Dealler, S. F. Electrical phenomena associated with bones and fractures and the therapeutic use of electricity in fracture healing. J. Meal. Engin. Technol. 5:73-79; 1981.
De Loecker. W.. and Stas. M. L.: Effect or cortisol treatment on free amino acid Icvels in rats. J. En-docrinol. 59:57. 1973.
De Loecker. W.. Stas. M. L.. De Wever. F.. and Juliet, R.: The effects of coalsol and amino acids on the metabolic activity of rat skin stored in di-methylsulfoxide buffer at -196°C. Cryobiology 15: 59. 1978.
Dietrich, J. W.; Canalis, E. M.; Maina, D. M.; Raisz, L. G. Hormonal control of bone collagen synthesis in vitro: Effects of parathyroid hormone and calcitonin. Endocrinology 98:943-949; 1976.
DoMman, H. G.; Caron, M. G.; Lefkowitz, R. J. A family of receptors coupled to guanine nucleotide regulatory proteins. Biochem. 26:2657-2664; 1987.
Epstein, S. Bone-derived proteins. Trends Endocr. Metab. 1:9-13; 1990.
Eriksson. C.: Streaming potentials and other water-dependent effects in mlneralized tissues. Ann. N.Y. Acad. Sci. 238:321, 1974.
Eriksson. C.: Electrical properties o£bone. In Bourne. G. H. (ed.): Biochemistry and Physiology of Bone. vol. 4. New York. Academic Press, 1976, pp. 329-384.
Fitton-Jackson, S.; Bassett, C. A. L. The response of skeletal tissues to pulsed magnetic fields. In: Richards, R. J.; Rajah K. T., eds. Use of tissue culture in medical research. Oxford Pergamon Press; 1980:21-46.
Florey. W., and Neuhaus, O. W.: Induced transport of amino acids in rat liver after wholebody 'r irradiation. Radial. Res. 68:138, 1976.
Friedenberg, Z. B.; Brighton, C. T. Bioelectric potentials in bone. J. Bone Joint Surg. 48A:915-923; 1966.
Friedenberg, Z. B.; Brighton, C. T. Bioelectricity and fracture healing. Plast. Reconst. Surg. 68:435-443; 1981.
Friedenberg, Z. B.; Harlow, M. C.; Brighton, C. T. Healing of non-union of the medial malleolus by means of direct current: A case report. J. Trauma 11:883-885; 1971a.
Friedenberg, Z. B.; Harlow, M. C.; Heppenstali, R. B.; Brighton, C. T. The cellular origin of bioelectric potentials in bone. Calc. Tiss. Res. 13:53; 1973.
Friedenberg, Z. B.; Roberts, P. G.; Didizian, N.H.; Brighton, C. T. Stimulation of fracture healing by direct current in the rabbit fibula. J. Bone Joint Surg. 53A: 1400-1408; 1971b.
Friedenberg, Z. B.; Zemsky, L. M.; Pollis, R. P.; Brighton, C. T. The response of non-traumatized bone to direct current. J. Bone Joint Surg. 56A: 1023-1040; 1974.
Fukuda, E.; Yasuda, I. On the piezoelectric effect of bone. J. Phys. Soc. Japan 10:1158-1162; 1957.
Fukada, E.: Piezoelectric properties of organic polymers. Ann. N.Y. Acad. Scl. 238:7. 1974.
Gensler. W.: Bioelectric potentials and their relation to growth in higher plants. Ann. N.Y. Acad. Scl. 238:280. 1974.
Goodman, R.; Henderson, A. S. Sine waves enhance cellular transcription. Bioelectromagnetics 7:23-29; 1986.
Goodman, R.; Henderson, A. S. Exposure of salivary glands to low-frequency electromagnetic fields alters polypeptide synthesis. Proc. Nat. Acad. Sci. U.S.A. 85:3928-3932; 1988.
Hamblen, D. L. Scientific basis of present day fracture treatment. J. Roy. Col. Surg. of Ed. 24:340-351; 1979.
Harrington, D. B.. and Becker. R. O.: Electrical stimulation of RNA and protein synthesis in the frog erylhrocyte. Exp. Cell Res. 76:95. 1973.
Harrington, D. B., Meyer. R.. and Klein, R. M.: Effects of small amounts of electric current at Ihe cellular level. Ann. N.Y. Acad. Sci. 238:300, 1974.
Hartshorne. On the causes and treatment of pseudoarthroses and especially that form of it sometimes called supernumary joint. Am. J. Med. Sci. 1:143; 1840.
Hassler, C. R.; Rykicki, E. F.; Diegle, R. B.; Clark, L. C. Studies of enhanced bone healing via electrical stimuli. Clin. Orthop. Rel. Res. 124:9-19; 1977.
Heffernan, M. (1995). The effect of a single cranial electrotherapy stimulation on multiple stress measures. The Townsend Letter for Doctors and Patients. 147:60-64.
Heffernan, M. (1996). Comparative effects of microcurrent stimulation on EEG spectrum and correlation dimension.
Integrative Physiology and Behavioral Science. 31 (3):202-209.
Heffernan, M. (1996b). Measurement of electromagnetic fields in the healing response. Epress, pp 1-6.
Henry, H. L.; Norman, A. W. Vitamin D: Metabolism and mechanism of action. In:
Favus, M. J., ed. Primer on metabolic bone disease. Kelseyville, CA: American Society of Bone and Mineral Research; 1990:47-52.
Hubel, K. A.: The effects of electrical field stimulation and tetrodotoxin on ion transport by isolated rabbit ileum. J. Clin. Invest. 62:1039. 1977.
Jagendorf. A. T., and Uribe. E.: ATP formation caused by acid-base transition of spinach chloroplasts. Proc. Natl. Acad. Sci. U.S.A. 55:170. 1966.
Jahn, T. L. A possible mechanism for the effect of electrical potential on apatite formation in bone. Clin. Orthop. Rel. Res. 56:261-273; 1968.
Karpf, D. B.; Bambino, T.; Arnaud, C. D.; Nissenson, R. A. Molecular determinants of parathyroid hormone receptor function. In: Cohn, D. V.; Glorieux, F. H.; Martin, T. J., eds. Calcium regulation and bone metabolism, vol. 10. Amsterdam: Elsevier; 1990:15-23. "·
Kaziro. Y.: The role of guanosinc-5'-triphosphate in polypepfide chain elongation. Blochim. Biophys. Acta 505:95. 1978.
Keller. F. B.. and Zamecnik. P. D.: The effects of guanosine diphosphate and triphosphate on the incorporation of labeled amino acids into proteins. J. Biol. Chem. 221:45, 1956.
Korostoff. E.: Stress generated potentials in bone: Relationship to plezoelectricity of collagen. J. Bio-mech. 10:41. 1977.
Krukowski, M.; Simmons, D. J.; Summerfield, A.; Osdoby, P. Charged beads: Generation of bone and giant cells. J. Bone Min. Res. 2:165-171; 1988.
Levy, D. D.; Rubin, B. Inducing bone growth in vivo by pulse stimulation. Clin. Orthop. Rel. Res. 88:218-222; 1972.
Liboff, A. R.; Williams, T.; Strong, D. M.; Wistar, R. Time-varying magnetic fields: Effect on DNA synthesis. Science 223:818-820; 1984.
Lanyon. L. E.. and Hartman. W.: Strain related electrical potentials recorded in vitro and i, viro. Calcif. Tissue Res. 22:315. 1977.
Lavine. L. S.. Lustfin, 1.. and Shamos. M. H.: Treat C~cal Onnopaeocs and nelate~ Rescaeca men: of congenital pseudanhrosis of the tibia with direc: current. Clin. Orthop. 124:69. 1977.
Liss, S. (1996). Neurochemical profiles following electrocranial stimulation. Presented at the Hans Selye Eighth International Conference on Stress. Montreux, Switzerland.
Lubar, J., et al. (1995). EEG spectrum in neurofeedback treatment of attention deficit disorder. Journal of Psycho-educational Assessment. Special issue, Dec.
Luben, R.A. (1991). Effects of low-energy electromagnetic fields (pulsed and dc) on membrane signal transduction processes in biological systems. Health Physics. 61(1): 15-28.
Luben, R. A. Comparison of electromagnetic effects on para-thyroid hormone receptors and beta-adrenergic receptors in bone cells. J. Cell Biol. 109:172a; 1989.
Luben, R. A.; Cain, C. D. Use of hormone receptor activities to investigate the membrane effects of low energy electromagnetic fields. In: Adey, W. R.; Lawrence, A. F., eds. Nonlinear electrodynamics in biological systems. New York: Plenum Press; 1984:23-34.
Luben, R. A.; Cain, C. D.; Chen, M. C. Y.; Rosen, D. M.; Adey, W. R. Inhibition of parathyroid hormone actions on bone cells in culture by induced low energy electromagnetic fields. Proc. Nat. Acad. Sci. U.S.A. 79:4180-4184; 1982.
Luben, R. A.; Cobh, D. V. Effects of parathormone and ealci-tonin on citrate and hyaluronate metabolism in cultured bone. Endocrinology 98:413-419; 1976.
Luben, R. A.; Huynh, D.; Weinshank, R. L.; Smith, L. E. Molecular cloning of candidate sequences for the mouse osteo-blast parathyroid hormone receptor. In: Cohn, D. V.;
Glo-rieux, F. H.; Martin, T. J., eds. Calcium regulation and bone metabolism, vol. 10. Amsterdam: Elsevier; 1990:39-44.
Luben, R. A.; Wong, G. L.; Cohn, D. V. Biochemical characterization with parathormone and caicitonin ofisolated bone cells: Provisional identification of osteoclasts and osteoblasts. Endocrinology 99:526-534; 1976. Lundin. A.. and Thore. A.: Analytical information obtainable by evaluation of the tlme course of firefly biolumincscence in the assay of ATP. Anal. Blo-chem. 66:47. 1975.
Marsland, T. P. Biophysical studies of pulsed electromagnetic field interaction with biological systems. London: Plenum Press; NATO ASI Series 97; 1985:547-595.
Martin, R. B.; Gutman, W. The effect of electric fields on osteoporosis of disuse. Calc. Tiss. Res. 25:23-27; 1978.
McClanahan, B. J.; Phillips, R. D. The influence of electric field exposure on bone growth and fracture repair in rats. Bioelec-tromagnetics 4:11-19; 1983.
McComb, R. B.; Bowers, G. N., Jr.; Posen, S. Alkaline phos-phatase. New York: Plenum Press; 1979.
Mitchell. P.: Chemiosmotic coupling in oxidative and photosynthetic phosphorylation. Biol. Rev. 41:445 1966.
Mitchell. P.: Vectorial chemistry and the molecular mechanism of chemiosmotic coupling: Power transmission by proticity. Biochem. Soc. Trans. 4:400. 1976.
Nair, I.; Morgan, G.; Florig, H. K. Biological effects of power frequency electric and magnetic fields. Washington, DC: U.S. Government Printing Office; Office of Technology Assessment, Document OTA-BP-E-53; 1989.
Neuman, W. F.; Ramp, W. K. The concept of a bone membrane: Source implication. In:
Nichols, G.; Wasserman, R. H., eds. Cellular mechanisms for calcium transfer and homeostasis. New York: Academic Press; 1971:197-199.
Norton, L. A.; Rodan, G. A.; Bourret, L. A. Epiphyseal cartilage cAMP changes produced by electrical and mechanical perturbations. Clin. Orthop. Rel. Res. 124:59-68; 1977.
O'Malley, B. The steroid hormone receptor superfamily: More excitement predicted for the future. Mol. Endocrinol. 4:363-369; 1990.
Oxender. D. L.. and Christensen. H. N.: Distinct mediating systems for the transport of neutral amino acids by the Ehrlich cell. J. Biol. Chem. 238:3686, 1963.
Pilla, A. A.. and Margules. G. S.: Dynamic interfacial electrochemical phenomena at living cell membranes: Application to the toad urinary bladder membrane system. J. Electrochem. Soc. 124:1697, 1977.
Pilla, A. A. Electrochemical information transfer at cell surfaces and junctions--application to the study and manipulation of cell regulation. In: Keyzer, H.; Gutman, F.
Bioelectro-chemistry. New York: Plenum Publishing; 1980:353-396.
Raisz, L. G. Bone metabolism and calcium regulation. Metabolic Bone Dis. 1:1-48; 1977.
Rappaport, M. S.; Stern, P. H. Parathyroid hormone and cal-citonin modify inositol phospholipid metabolism in fetal rat limb bones. J. Bone Min. Res. 1:173-179; 1986.
Rodan, G. A.; Bourret, L. A.; Norton, L. A. DNA synthesis in cartilage cells is stimulated by oscillating electric fields. Science 199:690--692; 1978.
Rodan, G. A.; Martin, T. J. Role ofosteoblasts in the hormonal regulation of bone resorption--a hypothesis. Calcif. Tiss. Intl. 33:349-351; 1981.
Rodan, S. B.; Wesolowski, G.; Rodan, G. A. Cional differences in prostaglandin synthesis among osteosarcoma cell lines. J. Bone Min. Res. 1:213-220; 1986.
Romero-Sierra. 12.. and Tanner. J. A.: Biological effects of nonionizing radiation: An outline of fun-damenlal laws. Ann. N.Y. Acad. Sci. 238:263, 1974.
Rowley. B. A.. McKenna, J. M.. Chase, G. R., and Wolcott, L. E.: The influence of electrical current on an infecting microorganism in wounds. Ann. N.Y. Acad. Sci. 238:543, 1974.
Sansen. W., and De Dijcker, F.: The four-point probe technique to measure bio-impedances. Elec-tromyogr. Ciin. Neurophyslol. 16:509. 1976.
Savitz, D. A.; Calle, E. Leukemia and occupational exposure to electromagnetic fields: Review of epidemiological surveys. J. Med. 29:47-51; 1987.
Schlessinger, J. The epidermal growth factor receptor as a mul-tifunctional allosteric protein. Biochem. 27:3119-3123; 1986.
Schmukler, R.; Pilla, A. A. A transient impedance approach to nonfaradaic electrochemical kinetics at living cell membranes. J. Electrochem. Soc. 129:526-528; 1982.
Shamos. M. H., and Layinc. L. S.: Piezoelectricity as a fundamental property of biological tissues. Nature 213:267, 1967.
Sibley, D. R.; Benovic, J. L.; Caron, M. G.; Lefkowitz, R. J. Phosphorylation of cell surface receptors: A mechanism for regulating signal transduction pathways. Endocrine Rev. 9: 38-56; 1988.
Spafaro. J. A.: Electrically stimulated bone growth in animals and man. Review of the literature. Clin. Orthop. 122:325. 1977.
Stan. S.. Muller, J. C.. Sansen. W.. and Dewaele. P.: Effect of direct current on the healing of fractures. In Burney. F.. Herbst, E.. and Hinsenkamp. M. (eds): Electric
Stimulation of Bone Growth and Repair. Berlin. Heidelberg. New York, Springer-Verlag. 1978, pp. 47-53.
Stryer, L.; Bourne, H. R. G proteins: A family of signal transducers. Ann. Rev. Cell Biol. 2:391-420; 1986.
Tabrah, F.; Hoffmeier, M.; Gilbert, F.; Batkin, S.; Bassett, C. A. L. Bone density changes in osteoporosis-prone women exposed to pulsed electromagnetic fields (PEMFs). J. Bone Min. Res. 5:437-442; 1990.
Tam, C. S.; Heersche, J. N.M.; Murray, T. M.; Parsons, J. A. Parathyroid hormone stimulates the bone apposition rate independently of its resorptive action. Endocrinology 110:506-512; 1982.
United States Environmental Protection Agency. Evaluation of the potential carcinogenicity of electromagnetic fields. July 1991, Volume 61, Number I
Van der Schueren. B.. Doms, D., and De Loecker. W.: Storage damage in ratskln preset'ca at -3'C. Cryobiology 11:526, 1974.
Washington, D.C.: U.S. Government Printing Office; EPA document 600/6-90/005A; 1991.
Wahlstrom, O. Stimulation of fracture healing with electromagnetic fields of extremely low frequency. Clin. Orthop 186:293-298; 1984.
Watson, J. The electrical stimulation of bone healing. Proc. IEEE 67:1339-1351; 1979.
West, B.J. (1990). Fractal Physiology and Chaos in Medicine. World Scientific, New Jersey.
Witt. H. T.. Schlodder, E., and Graber. P.: Membrane-bound ATP synthesis generated by an external electrical field. FEBS Left. 69:272, 1976.
Wolcott. L. E.. Wheeler, P. C., Hardwicke. H. M.. and RowIcy. B.: Accelerated healing of skin ulcers by electrotherapy: Prelimlnary clinical results. South. Med. J. 62:795. 1969.
Wolff, J. Studies of bone transformation. Berlin: Publisher unknown; 1892.
Wu. K. T., Go, N.. Dennis, C.. Enquist, I.. and Sawyer. er. P. N.: Effects of electric currents and interfacial potentials on wound healing. J. Surg. Res. 7:122. 1967.
Yamaguchi, D. T.; Hahn, T. J.; lida-Klein, A.; Kleeman, C. R Muallemm, S. Parathyroid hormone activated calciun channels in an osteoblast-like clonal osteosarcoma cell line. J. Biol. Chem. 262:7711-7718; 1987.
Yarden, Y.; Ullrich, A. Growth factor receptor tyrosine kinases Ann. Rev. Biochem. 57:443-478; 1988.
