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(2) Burgudjiev ., Lyochkova M, Stefanova DI, Koleva I. (1976): Use of characteristic of modern photographic materials in spectral determination of trace elements.  Mikrochim Acta., 1:441-449

[1]. 1. Barnes RM. (1978): Emission -spectroscopy. Anal. Chem. 50:100-120 (IF=5.450)

[2]. 2. Zimmer K, Heltai G. (1979): Influence of photographic and photometric effects on spectrographic evaluation. 1. Problems in the evaluation of emission-spectra-effect of the micro-densitometer type on the results of density-measurements. Acta Chim Acad Sci Hung 100:319-339

[3]. 3. Zimmer K, Heltai G. (1979): Effect of photographic and photometric effects on the evaluation in spectrography. Magy. Kem. Foly 85:170-180

 

(3) Stephanova DI, Dimitrov GV. (1982): Mathematical modeling of ionic processes in human skeletal muscle fibers. Electromyogr. Clin. Neurophysiol., 22:329-347

[4]. 1. Kleinpenning P, A. van Oosterom (1990): On the relation between axonal resistance and conductivity in linear cable models. Mathematical Biosciences. 99:1-10

[5]. 2. Kleinpenning PH., Gootzen T., van Oosterom A, Stegeman A. (1990): The equivalent source description representing the extinction of an action potential at a muscle fibre ending. Mathematical Biosciences. 101(1):41-61 (IF=1.699)

[6-8]. 3-5. Kleinpenning P. (1991): The electrical potential field of single nerve cell: A model study. Den Haag, Ph.D. Thesis, Chapter II, 7-15 ; Chapter III, 17-33; Chapter IV, 34-55, Nijmegen, Proefschrift, the Nederlands

[9]. 6. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

[10]. 7. Dimitrova N. (2005): Biophysical bases of the electrophysiological valuation of the functional condition of the neuro-muscular system. DSc Thesis, Sofia, Bulgaria

[11]. 8. Тарасов  (2003): Имитационное моделирование состояние рефлекторной дуги человека – лекция към Факултет электроники и приборостроение. Катедра электрогидроакустической и медицинской техники, Таганский государственный радиотехнический университет; www2.fer.tsure.ru/win/egamt

/learn/model/PZ_1.pdf

[12]. 9. Fortune E, Lowery MM. (2007): The effect of extracellular potassium concentration on muscle fibre conduction velocity examined using model simulation. Engineering in Medicine and Biology Society (EMBS), 29th Annual International Conference of the IEEE Engineering in Medicine and Biology-Proceedings, art. No 4352892, pp. 2726-2729.

[13]. 10. Fortune E, Lowery MM. (2009): Effect of extracellular potassium accumulation on muscle fiber conduction velocity: A simulation study. Annals of Biomedical engineering 37(10):2105-2117

[14]. 11. Fortune E, Lowery MM. (2011): Simulation of the interactions between muscle fibre conduction velocity and instantaneous firing rate. Annals of Biomedical Enginneering 39(1):96-109

[15]. 12. Fortune E, Lowery MM. (2012): Effect of membrane properties on skeletal muscle fiber excitability: a sensitivity analysis. Med. Bio. Eng. Comput., 50(6):617-629.

ISSN: 0140-0118

(4) Стефанова Д. (1983): Математично моделиране на процесите протичащи в клетъчните мембрани на скелетни мускулни влакна. Кандидатска дисертация

[16]. 1. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

 

(5) Stephanova DI, Dimitrov GV. (1983): Mathematical analysis of the mechanisms of conductance along excitable fibres in the recovery cycle. Electromyogr. Clin. Neurophysiol., 23:35-47

[17]. 1. Dimitrova N. (1987): Mathematical modelling of intra and extracellular potentials generated by active structures: Effects of a step change in structure diameter, Gen. Physiol. Biophys., 6(1):19-34   (IF=0.736)

[18]. 2. Латева З.Х. (1990): Интегрални и спектрални характеристики на извънкле-тъчните потенциали на възбудими влакна, Кандидатска дисертация, София

[19]. 3. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

 

(6) Stephanova DI, Dimitrov GV. (1984): Mathematical analysis of the changes in the intracellular potentials, generated by human skeletal muscle fiber under the effect of temperature. Electromyogr. Clin. Neurophysiol., 24:377-386

[20]. 1. Tackmann W., Vogel P. (1987): Dependence of the muscle-potential duration on the intramuscular temperature (Zur Abhangigkeit der Muskelaktion- spotentialdauer von der intramuskularen temperature). Z. EEG-EMG 18:72-75

[21]. 2. Латева ЗХ. (1990): Интегрални и спектрални характеристики на извънкле-тъчните потенциали на възбудими влакна. Кандидатска дисертация, София

[22]. 3. Kleinpenning P, Gootzen T, van Oosterom A, Stegeman A. (1990): The equivalent source description representing the extinction of an action potential at a muscle fibre ending. Mathematical Biosciences. 101:41-61 (IF=1.699)

[23]. 4. Kleinpenning P. (1991): The electrical potential field of single nerve cell: A model study. Den Haag, PhD Thesis, Chapter IV, 34-55

[24]. 5. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

 

(7) Stephanova DI. (1984): Mathematical analysis of the changes in the action potentials, generated by a frog skeletal muscle fibre under the effect of temperature. Electromyogr. Clin. Neurophysiol., 24:369-376

[25]. 1. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

 

(8) Stephanova DI. (1984): Mathematical analysis of the changes in the intracellular potentials, generated by a human skeletal muscle fiber in the recovery cycle at the different temperatures. Electromyogr Clin Neurophysiol, 24:107-115

[26]. 1. Dimitrov G., Lateva Z., Dimitrova N.(1988): Effects of changes in asymmetry, duration and propagation velocity of the intracellular potential on the power spectrum of extracellular potentials produced by an excitable fiber. Electromyogr. Clin. Neurophysiol., 28:93-100

[27]. 2. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

 

(9) Stephanova DI. (1984): Mathematical analysis of the changes in the action potential and ionic currents of the frog muscle fibres at different temperatures. Electromyogr. Clin. Neurophysiol., 24:599-610

[28]. 1. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

[29]. 2. Radicheva NI., Kolev VB., Peneva NE (1993): Influence of intracellular potential and conduction-velocity on extracellular muscle-fiber potential. Journal of Electromyography and Kinesiology, 3:95-102, (IF=2.102)

 

(10) Dimitrov DS, Stoicheva N, Stefanova. D (1984): A simple interpolation formula for the rate of approach of particles or cells with tension-controlled shapes at arbitrary separations. J Colloid Interf Sci., 98:269-271

[30]. 1.Hammer DA, Lauffenburger DA. (1987): A dynamical model for receptor-mediated cell-adhesion to surfaces. Biophys. J., 52:475-487 (IF=4.585)

[31]. 2. Ivanov IB (1988) Thin Liquid Films: Fundamentals and Applications CRC Press, Chapter 7, pp. 454,491.

[32]. 3. Hammer DA., Lauffenburger DA. (1989): A dynamical model for receptor-mediated cell-adhesion to surfaces in viscous shear-flow. Cell Biophys., 14:139-173

[33]. 4. André P, Bongrand P. (1990): Cell-cell contacts, Biophysics of the Cell Surface, Springer Series in Biophysics 5:287-321.

[34]. 5. Tissot O, Foas C, Capo C, Brailly H, Delaage M, Bongrand P. (1991): Influence of adhesive bonds and surface rugosity on the interaction between rat thymcytes and flat surfaces under laminar shear-flow. J. Dispersion Sci. Technol. 12:1445-160

[35]. 6. Tissot O, Pierres A, Foa C, Delaage M, Bongrand P. (1992): Motion of cells sedimenting on a solid-surface in a laminar shear-flow. Biophys. J, 61:204-215 (IF=4.585)

[36]. 7. Kumar S, Kumar R, Gandhi KS. (1993): A new model for coalescence efficiency of drops in stirred dispersions. Chem. Eng. Sci. 48:2025-2038 (IF=1.655)

[37]. 8. Basu S, Gandhi KS, Kumar R. (1997): Flow of liquid/liquid dispersions in a Hele-Shaw cell. J. Chem. Eng. JP. 30:852-866 (IF=0.515)

[38]. 9. Mohamed N, Rainier TR, Ross JM. (2000): Novel experimental study of receptor-mediated bacteria adhesion under the influence of fluid shear. Biotechnol. Bioeng. 68:628-636, (IF=2.216)

[39]. 10. Mascari L, Ymele-Leki P, Eggleton CD, Speziale P, Ross JM. (2003): Fluid shear contributions to bacteria cell detachment initiated by a monoclonal antibody. Biotechnol. Bioeng., 83:65-74  (IF=2.216)

 

(11) Stephanova D., Gydikov A. (1985): Mathematical modelling of the changes in the parameters of the action potential of frog muscle fibre at different temperatures. Electromyogr. Clin. Neurophysiol 25:223-232

[40]. 1. Basgoze Osman, Gokce Kutsal Yesim, Narman Sabri, (1987): Effects of ice on the amplitude of M wave in distal latency, Electromyogr. Clin. Neurophysiol, 26:729-734

[41]. 2. Syndulko K, Jafari, Woldanski A, Baumhefner RW, Tourtellotte W. (1996): Effects of temperature in multiple sclerosis: A review of the literature, Neurorehabilitation and Neural Repaier, 10:23-34

[42]. 3. Radicheva N, Mileva K, Vukova T, Georgieva B, Kristev I. (2002): Effect of microwave electromagnetic field on skeletal muscle fibre activity. Archives of Physiology and Biochemestry, 110(3): 203-214

 

(12) Stephanova DI. (1987): Mathematical analysis of the changes in the parameters of the action potentials, membrane and ionic currents of the frog muscle fibre during the recovery cycle. Biol. Cybern., 57:207-211

[43]. 1. Gydikov A. (1992): Biophysics of the skeletal muscle extracellular potentials. Kluwer Academic Publishers, Dordrecht/Boston/London and Publishing House of the Bulgarian Academy of Sciences, Sofia

[44]. 2. Pour-Ghaz I. (2002): Mechanical and Electrical Stimulation of the frog gastronemius skeletal muscle: Studying the response Pattern and Formation of fatigue. Frog Musle Response Pattern

 

(13) Stephanova DI. (1988): The effect of temperature on a simulated systematically paranodally demyelinated nerve fiber. Biol Cybern, 60:73-77

[45]. 1. Cianfrone G, Turchetta R, Mazzei F, Bartolo M, Parisi L. (2006): Temperature-dependent auditory neuropathy: Is it an acoustic Uhthoff-like phenomenon? A case report. Annals of Otology, Rhinology and Laryngology 115 (7):518-527

 

(14) Stephanova DI. (1988): Reorganization of the axonal membrane in a demyelinated nerve fibre: computer simulation. Electromyogr. Clin Neurophysiol., 28:101-105

[46]. 1. Brusa A, Jones SJ, Plant GT. (2001): Long-term remyelination after optic neuritis -A 2-year visual evoked potential and psychophysical serial study. Brain 124:468-479

[47]. 2. Christova LG, Alexandrov AS, Krampfl K, Bufler J, Kossev AR, Ishpekova BA. (2005): Electrophysiological Characteristics of Hereditary Motor and Sensory Neuropathy of the LOM Type (HMSN-L). Klin Neurophysiol 36:86-74

 

(15) Stephanova DI. (1988): Systematic paranodal demyelination of nerve fibers: computer simulations. Elecromyogr. Clin. Neurophysiol., 28:107-110

[48]. 1. Christova LG, Alexandrov AS, Krampfl K, Bufler J, Kossev AR, Ishpekova BA. (2005): Electrophysiological Characteristics of Hereditary Motor and Sensory Neuropathy of the LOM Type (HMSN-L). Klin Neurophysiol 36:86-74

 

(17) Stephanova D, Trayanova N, Gydikov A, Kossev A. (1989): Extracellular potentials of a single myelinated nerve fibre in an unbounded volume conductor. Biol Cybern., 61:205-210

[49]. 1. Schoonhoven R, Stegeman D. (1991): Models and Analysis of Compound Nerve Action Potentials. Critical Reviews in Biomedical Engineering. 19(1):47-111

[50-51]. 2-3. Benno Klass, van Veen (1992): Single fiber action potentials in inhomogeneously conducting skeletal muscle: Influence of inhomogeneities in muscle tissue upon single fiber action potentials a finite element model study. PhD Thesis, Chapter IV, 59-88; Chapter V, 91-114, Enschede, the Netherlands

[52]. 4. Rutten WC, van Veen BK, Stroeve SH, Boom HBK, Wallinga W. (1997): Influence of inhomogeneities in muscle tissue on single-fibre action potentials: a model study. Med & Biol Eng & Comput, 35:91-95

[53]. 5. Struijk JJ. (1997): The extracellular potential of a myelinated nerve fiber in an unbounded medium and in nerve cuff models. Biophys. J., 72:2457-2469   (IF=4.585)

[54]. 6. Meier JH, Rutten WLC, Boom HBK. (1998): Extracellular potentials from active myelinated fibres inside insulated and noninsulated peripheral nerve. IEEE Trans.  Biomed. Eng., 45(9):1146-1153   (IF=1.815)

[55]. 7. Holt GR. (1998): A critical reexamination of some assumption and implications of cable theory in neurobiology. PhD Thesis, Chapter II (19), California, Institute of Technology, Pasadena

[56]. 8. Kallesoe K. (1998): Implantable transducers for neurokinesiological research and neural prostheses. Ph.D.Thesis, Simon Fraser University, Canada (pp. 120, 194)

[57]. 9. Bennett MR, Farnell L, Gibson WG. (1999): Cable analysis of a motor-nerve terminal branch in a volume conductor. Bulletin of Math., Biol. 61 (1):1-17   (IF=1.485)

[58]. 10. Bennett MR, Farnell L, Gibson G, Macleod GT, Dickens P. (2000): Quantal potential fields around individual active zones of amphibian motor-nerve terminals. Biophysical J., 78 (3):1106-1118   (IF=4.585)

[59]. 11. Mizumori SJY, Leutgeb S. (2001): Directing place representation in the hippocampus. Reviews in the Neuroscience 12:347-363   (IF=3.240)

[60]. 12. Aronsson P, Liljeström H. (2001): Effects of non-synaptic neuronal interaction in cortex on synchronization and learning. BioSystems 63:43-56   (IF=1.016)

[61]. 13. Bennett MR. (2003): The formation and function of single transmitter release sites at mature amphibian motor-nerve terminals. J. Neurocytol. 32:447-472   (IF=1.669)

[62]. 14. Bennett MR. (2003): The formation and function of single transmitter release sites at mature amphibian motor-Nerve terminals. Brain Cell Biology 32:447-472

[63]. 15. Qiao S, Odoemene O, Yoshida K. (2012): Determination of electrode to nerve fibre distance and nerve conduction velocity through spectral analysis of the extracellular action potentials recorded from earthworm giant fibres. Med. Biol. Eng. Comp., 50(8):867-875

[64]. 16. Qiao S, Yoshida K. (2013): Influence of unit distance and conduction velocity on the spectra of extracellular action potentials recorded with intrafascicular electrodes. Medical Engineering & Physics., 35(1):116-124, IF=1.179

 

(18) Stephanova DI. (1989): Conduction along myelinated and demyelinated nerve fibers during the recovery cycle: model investigations. Biol. Cybern., 62:83-87

[65]. 1. Quandt FN and Davis FA. (1992): Action potential refractory period in axonal demyelination: a computer simulation. Biol. Cybern., 67:545-552   (IF=2.142)

[66]. 2. Reutskiy S, Rossoni E, Tirozzi B. (2003): Conduction in bundles of demyelinated nerve fibers: computer simulation. Biol. Cybern., 89:439-448   (IF=2.142)

[67]. 3. Christova LG, Alexandrov AS, Krampfl K, Bufler J, Kossev AR, Ishpekova BA. (2005): Electrophysiological Characteristics of Hereditary Motor and Sensory Neuropathy of the LOM Type (HMSN-L). Klin Neurophysiol 36:86-74

 

(19) Gydikov A, Kossev A, Trayanova N, Stephanova D. (1990): Electrotonic potentials of myelinated nerve fibres. Electromyogr. Clin. Neurophysiol., 30:47-51

[68]. 1. Benenett MR., Farnell L, Gibson WG. (1999): Cable analysis of a motor-nerve terminal branch in a volume conductor. Bulletin of Math. Biol. 61:1-17 (IF=1.485)

[69]. 2. Bennett MR. (2003): The formation and function of single transmitter release sites at mature amphibian motor-Nerve terminals. J. Neurocytol. 32:447-472   (IF=1.669)

[70]. 3. Bennett MR. (2003): The formation and function of single transmitter release sites at mature amphibian motor-Nerve terminals. Brain Cell Biology 32:447-472

 

(21) Stephanova DI. (1990): Conduction along myelinated and demyelinated nerve fibres with a reorganized axonal membrane during the recovery cycle: model investigations. Biol. Cybern., 64:129-134

[71]. 1. Christova LG, Alexandrov AS, Krampfl K, Bufler J, Kossev AR, Ishpekova BA. (2005): Electrophysiological Characteristics of Hereditary Motor and Sensory Neuropathy of the LOM Type (HMSN-L). Klin Neurophysiol 36:86-74   (IF=0.183)

[72]. 2. Cianfrone G, Turchetta R, Mazze F, Bartolo M, Parisi L. (2006): Temperature-dependent auditory neuropathy: Is it an acoustic Uhthoff-like phenomenon? A case report. Annals of Otology, Rhinology and Laryngology 115(7): 518-527

[73]. 3. Bucher D, Goaillard JM. (2011): Beyond faithful conduction: Short-term dynamics, neuromodulation, and long-term regulation of spike propagation in the axon. Progress in Neurobiology, 94(4):307-346   IF= 11.33

[74]. 4. Nicolas G, Le Peillet ML, Rivron B. (2011): Managemen of patients in the Angers ALS Center. Annals of Physical and Rehabilitation Medicine, 54(1), pp.e173-e173

 

(22) Stephanova DI, Bostock H. (1995): A distributed-parameter model of the myelinated human nerve fibre: temporal and spatial distributions of action potentials and ionic currents. Biol. Cybern. 73:275-280

[75]. 1. Wegner B. (1996): Zentralblatt für Mathematik und ihre Grenzgebiete by Heidelberger Akademie der Wissenschaften. Akademie der Wissenschaften der DDR. Vol. 828, Page 574

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[77]. 3. McIntyre C, Grill W. (1998): Sensitive analysis of a model of mammalian neural membrane. Biol. Cybern., 79:29-37   (IF=2.142)

[78]. 4. Williamson R (1999): A new generation neural prosthesis. PhD Thesis. Edmonton, Alberta. Pp. 1-223 (pp. 22, 35)

[79]. 5. Richardson AG, McIntyre CC, Grill WM. (2000): Modelling the effects of electric fields on nerve fibres: influence of the myelin sheath. Med Biol Eng Comput 38 (4): 438-446   (IF=1.070)

[80]. 6. Grill WM, Richardson AG, McIntyre CC. (2000): Influence of the myelin sheath on excitation properties of nerve fibres. Engineering in Medicine and Biology Society, Proceedings of the 22nd Annual International Conference of the IEEE, 22(1-4):1605-1607

[81]. 7. Dimitrov AG. (2000): The effect of a near-membrane volume on generation of action potentials in myelinated nerve fibres. Neurophysiology. 32(3):228-228   (IF=2.357)

[82]. 8. Jun Kimura (2001): Electrodiagnosis in diseases on nerve and muscle: principles and practice: Nerve Conduction Studies. Oxford, University Press, pp. 230, 236

[83]. 9. McIntyre CC, Richardson AG, Grill WM. (2002): Modeling the excitability of mammalian nerve fibres: Influence of afterpotentials on the recovery cycle. J Neurophysiol 87(2):995-1006   (IF=3.592)

[84]. 10. Dimitrova N. (2005): Biophysical bases of the electrophysiological valuation of the functional condition of the neuro-muscular system. DSc Thesis, Sofia, Bulgaria

[85]. 11. Dimitrov AG (2005): Internodal sodium channels ensure active processes under myelin manifesting in depolarizing afterpotentials. J. Theor. Biol. 234(4):451-462

[86]. 12. Farzad Towhidkhah (2005): Modeling the effects of electric fields on nerve fibres: influence of the myelin sheath. Biomedical Engineering Faculty, Amirkabir University of Technology 1-37, Tehran, Iran

[87]. 13. Dimitrov AG. (2009): A possible mechanism of repetitive firing of myelinated axon. Pflügers Archiv European Journal of Physiology 458(3):547-561 (IF=3.842)

[88]. 14. Dimitrov AG. (2009): Axonal Hyperactivity. Internodal mechanisms. PhD Thesis, Sofia, Bulgaria

[89]. 15. Goldfinger MD. (2009): Probability distributions of markovian sodium channel states during propagating axonal impulses with or without recovery supernormality. Journal of Integrative Neuroscience 8(2): 203-221

[90]. 16. Schiefer MA. (2009): Optimized design of neural interfaces for femoral nerve clinical neuroprostheses:anatomically-based modelling and intraoperative evaluation. PhD Thesis, Department of Biomedical Engineering, Case Western Reserve University, pp 49, 395

[91]. 17. Zlochiver S. (2010): Persistent reflection underlies ectopic activity in multiple sclerosis: a numerical study. Biol Cybern 102 (3):181-196

[92]. 18. Angel N. (2011): Equivalent circuit implementation of demyelinated human neuron in spice. PhD Thesis, California Polytechnic State University, San Luis Obispo, USA, 1-95

[93]. 19. Babbs CF, Shi R. (2013): Subtle paranodal injury slows impulse in a mathematical model of myelinated axons. PLoS one 8(7):e67767. doi:10.1371/journal.pone.0067767 –x.plos.org

[94]. 20. Dimitrov AG, Dimitrova NA. (2013): Chapter 3, Axonal Afterdischarges: Problems and Mechanisms. In: Axons: Cell Biology, Molecular Dynamics and Roles in Neural Repair and Rehabilitation, H. Yamamoto and A. Oshiro (eds.), Nova Science Publishers Inc., New York, pp.187-240, ISBN: 978-1-62948-051-0.

[95]. 21. Howells J. (2013): Biophysical determinants of the behaviour of human myelinated axons, PhD Thesis, The faculty of Medicine, The University of Sydney.

[96]. 22. Dimitrov AG, Dimitrova N. (2014): Internodal mechanism of pathological afterdischarges in myelinated axons. Muscle & Nerve, 49(1):47-55

[97]. 23. Dekker DMT., Briaire JJ., Frijns JHM. (2014): The impact of internodal segmentation in biophysical nerve fiber models. Journal of Computational Neuroscience, 37:307-315

[98]. 24. Volman V, Ng LJ. (2014): Primary paranode demyelination modulates slowly developing axonal depolarization in a model of axonal injury. J Comput Neurosci, 37(3): 439-457

 

(23) Stephanova DI, Bostock H. (1996): A distributed-parameter model of the myelinated human nerve fibre: temporal and spatial distributions of electrotonic potentials and ionic currents. Biol. Cybern., 74: 543-547

[99]. 1. McIntyre C, Grill W. (1998): Sensitive analysis of a model of mammalian neural membrane, Biol. Cybern. 79(1):29-37   (IF=2.142)

[100]. 2. McIntyre C, Grill W. (1999): Excitation of central nervous system neurons by nonuniform electric fields. Biophysical. J. 76(2):878-888 (IF=4.585)

[101]. 3. Jun Kimura (2001): Electrodiagnosis in diseases on nerve and muscle: principles and practice: Nerve Conduction Studies. Oxford, University Press, pp. 230, 236

[102]. 4. Farzad Towhidkhah (2005): Modeling the effects of electric fields on nerve fibres: influence of the myelin sheath. Biomedical Engineering Faculty, Amirkabir University of Technology 1-37, Tehran, Iran

[103]. 5. Zhang G, Huo X, Yin Z. (2007): A model study of nerve fibers. Beijing Biomedical Engineering 26(6):663-666

[104]. 6. Gow A, Devaux J. (2008): A model of tight junction function in central nervous system myelinated axons, Neuron Glia Biology. Department of Biomedical Engineering, Case Western Reserve University, 4(4):307-317

[105]. 7. Dimitrov AG. (2009): A possible mechanism of repetitive firing of myelinated axon. Pflügers Arch-Eur J Physiology 458:547-561 (IF=3.842)

[106]. 8. Dimitrov AG. (2009): Axonal Hyperactivity. Internodal mechanisms. PhD Thesis, Sofia, Bulgaria

[107]. 9. Schiefer MA (2009): Optimized design of neural interfaces for femoral nerve clinical neuroprostheses:anatomically-based modelling and intraoperative evaluation, PhD Thesis

[108]. 10. Angel N. (2011): Equivalent circuit implementation of demyelinated human neuron in spice. PhD Thesis, California Polytechnic State University, San Luis Obispo, USA, 1-95

[109]. 11. Jun Kimura (2013): Chapter 10, Other Techniques to Assess the Peripheral Nerve. In: Electrodiagnosis in diseases of Nerve & Muscle, Jun Kimura (ed.), (fourth edition), Oxford, University Press, pp: 235-273,   ISBAN 978-0-19-973868-7.

[110]. 12. Dimitrov AG., Dimitrova NA. (2013): Chapter 3, Axonal Afterdischarges: Problems and Mechanisms. In: Axons: Cell Biology, Molecular Dynamics and Roles in Neural Repair and Rehabilitation, H. Yamamoto and A. Oshiro (eds.), Nova Science Publishers Inc., New York, pp.187-240, ISBN: 978-1-62948-051-0.

[111]. 13. Howells J. (2013): Biophysical determinants of the behaviour of human myelinated axons. PhD Thesis, The faculty of Medicine, The University of Sydney.

[112]. 14. Tani J, Chen C-I, Sung J-Y. (2014):  Nerve Excitability Changes in Chronic Inflammatory Demyelinating Polyneuropathy: A New Clinical Diagnostic Biomarker. Review Article, Journal of Experimental and Clinical Medicine, 49(1): 47-55, ISSN: 1097-4598.

 

(24) Stephanova DI and Chobanova M. (1997): Action potentials and ionic currents through paranodally demyelinated human motor nerve fibres: computer simulations. Biol Cybern, 76:311-314

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[115]. 3. Smith KJ. (2002): Neurophysiology of inflammatory demyelinating disease, Part 8 In Brain Disease: Therapeutic Strategies and Repair, Abramsky O, Compston S, Miller A, Said G (Eds) pp. 97, 456, ISBN 1841840408.

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[119]. 7. Christova LG, Alexandrov AS, Krampfl K, Bufler J, Kossev AR, Ishpekova BA. (2005): Electrophysiological Characteristics of Hereditary Motor and Sensory Neuropathy of the LOM Type (HMSN-L). Klin Neurophysiol 36:86-74   (IF=0.183)

[120]. 8. Cianfrone, G., Turchetta, R., Mazzei, F., Bartolo, M., Parisi, L. (2006): Temperature-dependent auditory neuropathy: Is it an acoustic Uhthoff-like phenomenon? A case report. Annals of Otology, Rhinology and Laryngology 115 (7):518-527

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