DOI: 10.14704/nq.2017.15.3.1033

A Note on Possible Healing Effects of Conch Shell Frequencies

Y. V. Suseela, J. Shashi Kiran Reddy

Abstract


The conch shell as a music tool with its innumerable uses has occupied a singular place in almost all ancient traditions and cultures across the globe. It could be considered as the sole musical instrument designed by Nature herself into a fascinating piece of art. However, studies aimed at understanding the acoustical attributes of a conch shell received very less attention in modern times. None of the previous studies on conch shell aimed at looking into a few aspects for which it is usually adored and considered sacred. In general, the sound radiated from a conch shell is believed to hold a healing aspect, and that is the underlying reason why different cultures used it during ritual practices, special ceremonies and at acoustically designed sacred sites. The present concept seminates from the observation that we have an additional ultrasonic component in the sound spectrum of a conch shell along with other harmonic frequencies. Since the low-range ultrasonic frequencies are known for their beneficial and healing effects, it’s obvious to relate them to such component existing in the conch shell spectrum. In this respect, the present note serves as a starting step in analyzing the fundamental grounds for its healing aspect.

Keywords


Conch Shell, Ultrasonic, Spectral Analysis, Sound Healing, Frequency

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References


Akiyama K and Sutoo D. Effect of different frequencies of music on blood pressure regulation in spontaneously hypertensive rats. Neuroscience Letters 2011; 487: 58-60.

Ang ES, Gluncic V, Duque A, Schafer ME, Rakic P. Prenatal exposure to ultrasound waves impacts neuronal migration in mice. Proceedings of the National Academy of Sciences 2006;103(34):12903-10.

Bhat RB. Spectrum Analysis of Conch Shell Sound. National Seminar on Acoustic and Its Biological Effects, December 1985, IIT Madras.

Bhat RB. Acoustics of conch shell. Journal of Sound Vibration 1992; 157(1):190-91.

Bennet A and Bennet D. The Human Knowledge System: Music and Brain Coherence, The Journal of the Monroe Institute 2008; 38(3), 277-95.

Bernardi L, Porta C, Casucci G, Balsamo R, Bernardi NF, Fogari R, Sleight P. Dynamic interactions between musical, cardiovascular, and cerebral rhythms in humans. Circulation 2009; 119: 3171-80.

Conrad C, Niess H, Jauch KW, Bruns CJ, Hartl W, Welker L. Overture for growth hormone: Requiem for interleukin-6? Critical Care Medicine 2007; 35: 2709-13.

Cook IA, Pajot SK, Leuchter AF. Ancient Architectural Acoustic Resonance Patterns and Regional Brain Activity. Time and Mind 2008; 1(1): 95-104.

Cook PR, Abel JS, Kolar MA, Huang P, Huopaniemi J, Rick JW, Chafe C, Chowning JM. Acoustic Analysis of the Chavín Pututus (Strombus Galeatus Marine Shell Trumpets). The Acoustical Society of America 2010; 128 (4): 2359.

Gaona JM, Rouleau N, Caswell JM, Tessaro LWE, Burke RC, Schumacher DC. Archaeoacoustic Investigation of a Prehistoric Cave Site: Frequency-Dependent Sound Amplification and Potential Relevance for Neurotheology. NeuroQuantology 2014; 12(4): 455-63.

Hill DR and Saroka KS. Sonic Patterns, Spirituality and Brain Function: The Sound Component of Neurotheology. NeuroQuantology 2010; 8(4): 509-16.

Huang ST, Good M, Zauszniewski JA. The effectiveness of music in relieving pain in cancer patients: A randomized controlled trial. International Journal of Nursing Studies 2010; 47: 1354-62.

Kodlady N and Patgiri BJ. Varieties in Shankha Vati - An Ayurvedic classical formulation for GIT disorders. Annals of Ayurvedic Medicine 2012; 1(3): 102-08.

Lemmer B. Effects of music composed by Mozart and Ligeti on blood pressure and heart rate circadian rhythms in normotensive and hypertensive rats. Chronobiology International 2008; 25: 971-86.

Lestard N, Valente RC, Lopes AG, Capella MA. Direct effects of music in non-auditory cells in culture. Noise and Health 2013; 15(66), 307-14.

Lin LC, Lee WT, Wu HC, Tsai CL, Wei RC, Mok HK, Weng CF, Lee MW, Yang RC. The long‑term effect of listening to Mozart K.448 decreases epileptiform discharges in children with epilepsy. Epilepsy & Behavior 2011; 21(4): 420-24.

Livio M. The Golden Ratio: The Story of Phi, the World’s Most Astonishing Number. Random House LLC, 2006.

Nguyen TN, Nilsson S, Hellström AL, Bengtson A. Music therapy to reduce pain and anxiety in children with cancer undergoing lumbar puncture: A randomized clinical trial. Journal of Pediatric Oncology Nursing 2010; 27(3): 146-55.

O'Brien Jr. WD. Ultrasound-biophysics mechanisms. Progress in Biophysics and Molecular Biology 2007; 93(1-3): 212–55.

Pouraghdam RM and Bhat RB. Spectrum analysis and directionality pattern of a Transducer-driven conch shell. Canadian Acoustics 2015;43(3): 1-4.

Prasad MG, Tailor LR, Bhat RB. Geometric Modeling and Spectral Analysis of a conch shell trumpet. Third international congress on Air and Structure-Borne Sound and Vibration, June 1994, Canada.

Prasad MG and Rajavel B. Acoustical studies on conch shell. The Journal of the Acoustic Society America 2010; 127 (3).

Raman U et al. Low-intensity ultrasound promotes neurite out growth in cultured cortical Neurons University of Arizona Health Sciences Poster Forum, October 30, 2013.

Rath SK and Naik PC. Fibonacci structure in conch shell. Current Science 2005; 88 (4): 555-57.

Rath SK and Naik PC. A Study on Acoustics of conch shell. Current Science 2009; 97(4): 521-28.

Rath SK and Naik PC. On Acoustic theory of conch shell. Current Science 2010; 99(6): 790-95.

Rauscher FH, Shaw GL, Ky KN. Listening to Mozart enhances spatial-temporal reasoning: Towards a neurophysiological basis. Neuroscience Letters 1995; 185: 44-47.

Rick JW and Lubman D. Characteristics and speculations on the uses of Strombus trumpets found at the ancient Peruvian center Chavín de Huántar. The Journal of the Acoustical Society of America 2002; 112(5): 2366.

Thompson BM and Andrews SR. An Historical Commentary on the Physiological Effects of Music: Tomatis, Mozart and Neuropsychology, Integrative Physiological and Behavioral Sciences 2000; 35(3), 174-188.

Tufail Y, Yoshihiro A, Pati S, Li MM, Tyler WJ. Ultrasonic Neuromodulation by Brain Stimulation with Transcranial Ultrasound. Nature Protocols 2011; 6(9): 1453-70.


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