Références bibliographiques et scientifiques sur le sujet de l'influence de la musique sur les plantes.
Cette liste n'est pas compète, car depuis que j'ai réalisé cette liste principalement vers 1998 il y a eu des dizaines autres recherches qui ont été réalisées et publiées.
Vu le nombre de recherches scientifiques sur le sujet, on peut bien dire que ceux qui ignorent l'influence de la musique sur les plantes sont simplement ignorant ou de mauvaise volonté.
References about Music and plants
Some Science Articles
Find several science articles in pdf you can download on bottom of the page "music and plants" http://musique-pour-soigner-les-plantes.weebly.com/music-and-plants.html
Braam, J. and R. W. Davis. 1990. Rain induced, wind-induced, and touch-induced expression of calmodulin and calmodulin-related genes in Arabidopsis. Cell 60: 357-367. [Talking Heads music at 60 db for 1 minute did not induce expression of touch-sensitive genes] Daedalus. 1991. Green music. Nature 351: 104. [explains fancifully how music might be used as an herbicide, claims Charles Darwin played the bassoon for Mimosa pudica]
Davis, R. and P. Scott. 2000. Groovy plants; the influence of music on germinating seedlings and seedling growth. J. Exp. Bot. 51: 73. [sketchy abstract-only that concludes that music does make seedlings grow faster, but the response is quite species-specific]
Subramanian, S. et al. 1969. A study on the effect of music on the growth and yield of paddy. Madras Agr. J. 56: 510-516. (Paddy is indifferent to daily 30-minute exposures to recorded South Indian oboe music)
Van Doorne Yannick, 1998-2000, Effects of Variable Sound Frequencies on plant Growth and Development. 111 p. Thesis. University and High School of Gent, Belgium.
Weinberger, P. and M. Measures. 1979. Effects of the intensity of audible sound on the growth and development of Rideau winter wheat. Can. J. Bot. 57: 1036-1039. [a variety of sounds at 90 db had some effects, but plants subjected to 105-120 db showed reduced growth]
Collins ME, Foreman JEK. The effect of sound on the growth of
plants. Cana Acoustics 2001;29:3–8.
CURRIER, H. B., AND D. H. WEBSTER. 1964. Callose formation and subsequent disappearance: studies in ultrasound stimulation. Plant Physiology 39: 843–847.
Creath K, Schwartz GE. Effects of intention, musical sound and
noise on the germination of seeds: Evidence of entanglement between
human and plant systems. In: Quantum Mind 2003: Consciousness,
Quantum Physics and the Brain. Tucson, AZ: University
of Arizona, Center for Consciousness Studies, 2003;
30–31.
Creath K, Schwartz GE. Effects of music on the growth of plants:
Evidence of info-energy resonance effects? In: Tucson 2002: Towards
a Science of Consciousness. Tucson, AZ: University of
Arizona, Center for Consciousness Studies, 2002;119.
EDWARDS, K. L., AND B. G. PICKARD. 1987. Detection and transduction of physical stimuli in plants. In E. Wagner, H. Greppin, and B. Millet
[eds.], The cell surface in signal transduction, 41–66. Springer-
Verlag, Berlin, Germany.
R. Goodman, A.S. Henderson, Transcription and translation
in cells exposed to extremely low frequency electromagnetic
fields, Bioelectrochem. Bioenerg. 25 (1991) 335_/355.
Gnanam A. Activation of photosynthesis in Spirogyra by sound
waves of electric bell. In: Proceedings of the Symposium on Algology.
New Delhi: Indian Council of Agricultural Research;
1960;144–146.
Muir T.G., Cartensen E.L., Prediction of non linear acoustical effects at biological frequencies and intensities. Ultrasound Med. Biol. 6 (1980) 345.
Ponniah, S. 1955. On the effect of musical sounds of stringed instruments on the growth of plants. Proc. Indian Sci. Congr. Assoc., 42 (3): 255.
Retallack D, Broman F. Response of growing plants to the manipulation
of their environment. In: The Sound of Music and
Plants. Santa Monica, CA: DeVorss & Co, 1973;82–94.
SINGH, T. C. N., AND S. PONNIAH. 1955a. Effect of musical sound of veena on balsam. Proceedings of the Behar Academy of Agricultural Science 4: 122-125.
SINGH, T. C. N., AND S. PONNIAH. 1955b. On the response of structure of the leaves of balsam and mimosa to musical sound of violin. Proceedings of the Indian Scientific Congressional Association 42: 254.
Singh, T. C. N., and S. Ponniah. 1953. On the effect of sound on protoplasmic streaming in the cells of Hydrilla verti- cillata. Proc. Indian Sci. Congr. (Luck- now), 3: 119.
Singh, T. C. N., and S. Ponniah. 1954. On the effect of musical sound of violin on the growth of Mimosa pudica L. Rapp. et Cornmiun. 8th Intern. Bot. Congr., 11/12: 195-196.
Singh, T. C. N., and S. Ponniah. 1963. On the effect of music and dance on plants. Behar Agric. Coll. Mag., 13 (1): 19-22.
Spillane, M. Brave new waves. TCl for plants. No. 6: 36, 1991
S.Y. Qiu, R.H. Yao, M.H. Zong, The appliance of supersonic in bioengineering, Dev. Bioeng. 3 (1999) 45_/48.
T. Li, Y. Hou, G. Cai, Analysis of the effect of strong sound wave on plant cells cycles using flow cytometry, Acta Biophys. Sin. 17 (1) (2001) 195/198.
Q.C. Wang, Q.B. Liao, Effect of ultrasonic radiation on
the fatty acid composition in Phaeodactylum tricornutum,
J. Xia men University (Natural Science Edition) 39 (2000) 32-35.
W.-C. Lee, The plants growing with music, Korea Agrofood 6
(1997) 41–43.
Y.-C. Qin, W.-C. Lee, Y.-C. Choi, M.-Y. Ahn, Preliminary study on the relationship among sonic, Chinese cabbage growth and aphids injury, J. China Agri. University 6 (3) (2001) 85–89.
Y.-C. Qin, W.-C. Lee, C.C. Young, Study on sonic influence upon crop yield and insect pest damage, Int. J. Ind. Entomol. 3 (1) (2001) 97–99.
Xiao, Hai. Vegetables and music. Pictorial Science, 6: 36, 1991
Z. Sheng, K. Sun, J. Yang, et al., The secondary structure
changes of plant cell wall proteins aroused by strong sound
waves using FT-IR, Acta Photons Sin. 28 (7) (1999) 600-602.
Z. Hucheng, Mechanism of the effects of sound stimulation
on the growth behaviors of chrysanthemum callus,
Ph.D. Dissertation, Chongqing University, 4 (2001) 21_/
40.
Y.Y. Liu, B.C. Wang, The study of alternative stress influencing the nutrition elements absorption on chrysanthemum callus, J. Appl. Biomech. 15 (4) (2000) 199 – 203 Chinese.
R.W. Wood, A.L. Loomis, The physical and biological effects of high frequency sound waves of great intensity, Phil. Mag. 4 (1927) 417.
K.S. Suslick, in: Ultrasound: its Chemical Physical and Biological
Effects, VCH Publishers, Weinheim, FRG, 1988, pp. 287–303.
D. Miller, The botanical effects of ultrasound: a review, Env. Exp. Bot. 23 (1983) 1–27.
X.F. Long, Effect of mechanical vibration on the growth
of Chrysanthemum callus and relevant mechanism studies,
Master’s thesis, Chongqing University, China, 1999.
Galston AW, Slayman CL (1979) The not-so-secret life of plants. Am Sci 67:337–344
K. Shen, B. Xi, The research of thermodynamic phasebehavior of tobacco cell under the alternative stress, Acta Biophys. Sin. 15 (1999) 579 –583.
K.L. Sun, The effects of alternative stress on the thermodynamical properties of cultured tobacco cells, Acta Biophysica Sinica 15 (1999) 579-584
Z.W. Shen, The secondary structure changes of plant cell wall proteins aroused by strong sound waves using FT-IR. Acta Photonica Sinica 18 (1999) 600 – 602 (in Chinese).
G.Y. Cai, The effects of alternative stress on the membrane
protein conformations of tobacco cells by circular dichroism, Acta Photonica Sinica 29 (2000) 289 – 297
M. Blank, R. Goodman, Do electromagnetic fields interact directly with DNA?, Bioelectromagnetics 18 (1997) 111-115
E.M. Goodman, B. Greenebaum, M.T. Marron, Effects of electromagnetic fields on molecules and cells, International Review of Cytology 158 (1995) 279-338.
for treating plants. 26/05/1989.
Joersbo, M. and Brunstedt, J. (1992). Sonication: A new method for gene transfer to
plants. Physiologia Plantarum. 85: 230-234.
Sternheimer, J. (1999). How ethical principles can aid research. Nature. 9 December 1999.
Vol 402. N°6762: p576.
Sternheimer, J. (1993). Epigenetic Regulation of Proteïn Biosynthesis by Scale Resonance.
Conférence à Kanagawa Science Academy and Teikyo Hospital (Tokyo). 20/05/1993.
Sternheimer, J. (1994-1995). Ondes d’échelle. Séminaire donné à l’ Université Européenne de
la Recherche. Paris.
Sternheimer, J. (1992). Titre d’invention: Procédé de régulation épigénétique de la
biosynthèse des protéines par résonance d’échelle. Brevet n° FR 92-06765. INPI: Institut
National de la propriété Industrielle.
Un livre “grand public” sur le sujet, Tampakushitsu-no ongaku (“Qu'est-ce que la musique
des protéines”), écrit par un physicien, Yoichi Fukagawa, publié au Japon (éd. Chikuma,
Tokyo, 1999).
Davis, R. and P. Scott (2000) Groovy plants; the influence of music on germinating seedlings and seedling growth. J. Exp. Bot. 51: 73.
Mirtskhulava, M. B. (1991) The primary mechanism of the biological action of weak magnetic fields of sound frequency Soobshcheniya Akademi Nauk Gruzii. 144(2-3): 313-315.
Norris, V. and Hyland, G. J. (1997) Do bacteria sing? Molec. Micro-biol., 24, 879–880.
Grundler, W., Keilmann, F., and Fröhlich, H. (1977) Resonant growth rate response of yeast cells irradiated by weak microwaves. Phys. Lett., 62A, 463–466.
Kaiser, D. and Losick, R. (1993) How and why bacteria talk to each other. Cell, 73, 873–885.
Adey W.R. (1990) Electromagnetic fields and the essence of living systems. “modern radio science”, Oxford university press pp1-37.
Growth Promotion by Vibration at 50 Hz in Rice and Cucumber Seedlings Plant and Cell Physiology, 1991, Vol. 32, No. 5 729-732
Hideyuki Takahashi1, Hiroshi Suge1 and Tadashi Kato2 1Institute of Genetic Ecology, Tohoku University, Katahira Aoba-ku Sendai, 980 Japan, 2Tohoku Pioneer Co., Kunomoto Tendo, 994 Japan
Vibration at 50 Hz significantly stimulated seed germinationand root elongation in both rice and cucumber plants. The vibrationbarely affected the elongation of cucumber hypocotyls but stimulated the elongation of rice coleoptiles. Thus, plants' responses to vibration at a particular frequency differ from those toother mechanical stimuli.
Find several science articles in pdf you can download on bottom of the page "music and plants" http://musique-pour-soigner-les-plantes.weebly.com/music-and-plants.html
Braam, J. and R. W. Davis. 1990. Rain induced, wind-induced, and touch-induced expression of calmodulin and calmodulin-related genes in Arabidopsis. Cell 60: 357-367. [Talking Heads music at 60 db for 1 minute did not induce expression of touch-sensitive genes] Daedalus. 1991. Green music. Nature 351: 104. [explains fancifully how music might be used as an herbicide, claims Charles Darwin played the bassoon for Mimosa pudica]
Davis, R. and P. Scott. 2000. Groovy plants; the influence of music on germinating seedlings and seedling growth. J. Exp. Bot. 51: 73. [sketchy abstract-only that concludes that music does make seedlings grow faster, but the response is quite species-specific]
Subramanian, S. et al. 1969. A study on the effect of music on the growth and yield of paddy. Madras Agr. J. 56: 510-516. (Paddy is indifferent to daily 30-minute exposures to recorded South Indian oboe music)
Van Doorne Yannick, 1998-2000, Effects of Variable Sound Frequencies on plant Growth and Development. 111 p. Thesis. University and High School of Gent, Belgium.
Weinberger, P. and M. Measures. 1979. Effects of the intensity of audible sound on the growth and development of Rideau winter wheat. Can. J. Bot. 57: 1036-1039. [a variety of sounds at 90 db had some effects, but plants subjected to 105-120 db showed reduced growth]
Collins ME, Foreman JEK. The effect of sound on the growth of
plants. Cana Acoustics 2001;29:3–8.
CURRIER, H. B., AND D. H. WEBSTER. 1964. Callose formation and subsequent disappearance: studies in ultrasound stimulation. Plant Physiology 39: 843–847.
Creath K, Schwartz GE. Effects of intention, musical sound and
noise on the germination of seeds: Evidence of entanglement between
human and plant systems. In: Quantum Mind 2003: Consciousness,
Quantum Physics and the Brain. Tucson, AZ: University
of Arizona, Center for Consciousness Studies, 2003;
30–31.
Creath K, Schwartz GE. Effects of music on the growth of plants:
Evidence of info-energy resonance effects? In: Tucson 2002: Towards
a Science of Consciousness. Tucson, AZ: University of
Arizona, Center for Consciousness Studies, 2002;119.
EDWARDS, K. L., AND B. G. PICKARD. 1987. Detection and transduction of physical stimuli in plants. In E. Wagner, H. Greppin, and B. Millet
[eds.], The cell surface in signal transduction, 41–66. Springer-
Verlag, Berlin, Germany.
R. Goodman, A.S. Henderson, Transcription and translation
in cells exposed to extremely low frequency electromagnetic
fields, Bioelectrochem. Bioenerg. 25 (1991) 335_/355.
Gnanam A. Activation of photosynthesis in Spirogyra by sound
waves of electric bell. In: Proceedings of the Symposium on Algology.
New Delhi: Indian Council of Agricultural Research;
1960;144–146.
Muir T.G., Cartensen E.L., Prediction of non linear acoustical effects at biological frequencies and intensities. Ultrasound Med. Biol. 6 (1980) 345.
Ponniah, S. 1955. On the effect of musical sounds of stringed instruments on the growth of plants. Proc. Indian Sci. Congr. Assoc., 42 (3): 255.
Retallack D, Broman F. Response of growing plants to the manipulation
of their environment. In: The Sound of Music and
Plants. Santa Monica, CA: DeVorss & Co, 1973;82–94.
SINGH, T. C. N., AND S. PONNIAH. 1955a. Effect of musical sound of veena on balsam. Proceedings of the Behar Academy of Agricultural Science 4: 122-125.
SINGH, T. C. N., AND S. PONNIAH. 1955b. On the response of structure of the leaves of balsam and mimosa to musical sound of violin. Proceedings of the Indian Scientific Congressional Association 42: 254.
Singh, T. C. N., and S. Ponniah. 1953. On the effect of sound on protoplasmic streaming in the cells of Hydrilla verti- cillata. Proc. Indian Sci. Congr. (Luck- now), 3: 119.
Singh, T. C. N., and S. Ponniah. 1954. On the effect of musical sound of violin on the growth of Mimosa pudica L. Rapp. et Cornmiun. 8th Intern. Bot. Congr., 11/12: 195-196.
Singh, T. C. N., and S. Ponniah. 1963. On the effect of music and dance on plants. Behar Agric. Coll. Mag., 13 (1): 19-22.
Spillane, M. Brave new waves. TCl for plants. No. 6: 36, 1991
S.Y. Qiu, R.H. Yao, M.H. Zong, The appliance of supersonic in bioengineering, Dev. Bioeng. 3 (1999) 45_/48.
T. Li, Y. Hou, G. Cai, Analysis of the effect of strong sound wave on plant cells cycles using flow cytometry, Acta Biophys. Sin. 17 (1) (2001) 195/198.
Q.C. Wang, Q.B. Liao, Effect of ultrasonic radiation on
the fatty acid composition in Phaeodactylum tricornutum,
J. Xia men University (Natural Science Edition) 39 (2000) 32-35.
W.-C. Lee, The plants growing with music, Korea Agrofood 6
(1997) 41–43.
Y.-C. Qin, W.-C. Lee, Y.-C. Choi, M.-Y. Ahn, Preliminary study on the relationship among sonic, Chinese cabbage growth and aphids injury, J. China Agri. University 6 (3) (2001) 85–89.
Y.-C. Qin, W.-C. Lee, C.C. Young, Study on sonic influence upon crop yield and insect pest damage, Int. J. Ind. Entomol. 3 (1) (2001) 97–99.
Xiao, Hai. Vegetables and music. Pictorial Science, 6: 36, 1991
Z. Sheng, K. Sun, J. Yang, et al., The secondary structure
changes of plant cell wall proteins aroused by strong sound
waves using FT-IR, Acta Photons Sin. 28 (7) (1999) 600-602.
Z. Hucheng, Mechanism of the effects of sound stimulation
on the growth behaviors of chrysanthemum callus,
Ph.D. Dissertation, Chongqing University, 4 (2001) 21_/
40.
Y.Y. Liu, B.C. Wang, The study of alternative stress influencing the nutrition elements absorption on chrysanthemum callus, J. Appl. Biomech. 15 (4) (2000) 199 – 203 Chinese.
R.W. Wood, A.L. Loomis, The physical and biological effects of high frequency sound waves of great intensity, Phil. Mag. 4 (1927) 417.
K.S. Suslick, in: Ultrasound: its Chemical Physical and Biological
Effects, VCH Publishers, Weinheim, FRG, 1988, pp. 287–303.
D. Miller, The botanical effects of ultrasound: a review, Env. Exp. Bot. 23 (1983) 1–27.
X.F. Long, Effect of mechanical vibration on the growth
of Chrysanthemum callus and relevant mechanism studies,
Master’s thesis, Chongqing University, China, 1999.
Galston AW, Slayman CL (1979) The not-so-secret life of plants. Am Sci 67:337–344
K. Shen, B. Xi, The research of thermodynamic phasebehavior of tobacco cell under the alternative stress, Acta Biophys. Sin. 15 (1999) 579 –583.
K.L. Sun, The effects of alternative stress on the thermodynamical properties of cultured tobacco cells, Acta Biophysica Sinica 15 (1999) 579-584
Z.W. Shen, The secondary structure changes of plant cell wall proteins aroused by strong sound waves using FT-IR. Acta Photonica Sinica 18 (1999) 600 – 602 (in Chinese).
G.Y. Cai, The effects of alternative stress on the membrane
protein conformations of tobacco cells by circular dichroism, Acta Photonica Sinica 29 (2000) 289 – 297
M. Blank, R. Goodman, Do electromagnetic fields interact directly with DNA?, Bioelectromagnetics 18 (1997) 111-115
E.M. Goodman, B. Greenebaum, M.T. Marron, Effects of electromagnetic fields on molecules and cells, International Review of Cytology 158 (1995) 279-338.
for treating plants. 26/05/1989.
Joersbo, M. and Brunstedt, J. (1992). Sonication: A new method for gene transfer to
plants. Physiologia Plantarum. 85: 230-234.
Sternheimer, J. (1999). How ethical principles can aid research. Nature. 9 December 1999.
Vol 402. N°6762: p576.
Sternheimer, J. (1993). Epigenetic Regulation of Proteïn Biosynthesis by Scale Resonance.
Conférence à Kanagawa Science Academy and Teikyo Hospital (Tokyo). 20/05/1993.
Sternheimer, J. (1994-1995). Ondes d’échelle. Séminaire donné à l’ Université Européenne de
la Recherche. Paris.
Sternheimer, J. (1992). Titre d’invention: Procédé de régulation épigénétique de la
biosynthèse des protéines par résonance d’échelle. Brevet n° FR 92-06765. INPI: Institut
National de la propriété Industrielle.
Un livre “grand public” sur le sujet, Tampakushitsu-no ongaku (“Qu'est-ce que la musique
des protéines”), écrit par un physicien, Yoichi Fukagawa, publié au Japon (éd. Chikuma,
Tokyo, 1999).
Davis, R. and P. Scott (2000) Groovy plants; the influence of music on germinating seedlings and seedling growth. J. Exp. Bot. 51: 73.
Mirtskhulava, M. B. (1991) The primary mechanism of the biological action of weak magnetic fields of sound frequency Soobshcheniya Akademi Nauk Gruzii. 144(2-3): 313-315.
Norris, V. and Hyland, G. J. (1997) Do bacteria sing? Molec. Micro-biol., 24, 879–880.
Grundler, W., Keilmann, F., and Fröhlich, H. (1977) Resonant growth rate response of yeast cells irradiated by weak microwaves. Phys. Lett., 62A, 463–466.
Kaiser, D. and Losick, R. (1993) How and why bacteria talk to each other. Cell, 73, 873–885.
Adey W.R. (1990) Electromagnetic fields and the essence of living systems. “modern radio science”, Oxford university press pp1-37.
Growth Promotion by Vibration at 50 Hz in Rice and Cucumber Seedlings Plant and Cell Physiology, 1991, Vol. 32, No. 5 729-732
Hideyuki Takahashi1, Hiroshi Suge1 and Tadashi Kato2 1Institute of Genetic Ecology, Tohoku University, Katahira Aoba-ku Sendai, 980 Japan, 2Tohoku Pioneer Co., Kunomoto Tendo, 994 Japan
Vibration at 50 Hz significantly stimulated seed germinationand root elongation in both rice and cucumber plants. The vibrationbarely affected the elongation of cucumber hypocotyls but stimulated the elongation of rice coleoptiles. Thus, plants' responses to vibration at a particular frequency differ from those toother mechanical stimuli.