Materials Science

Evaluation of the Impact of Biofield Treatment on Physical and Thermal Properties of Casein Enzyme Hydrolysate and Casein Yeast Peptone

Written by Trivedi Effect | Jul 6, 2015 4:00:00 AM

Journal: Clinical Pharmacology & Biopharmaceutics PDF  

Published: 06-Jul-15 Volume: 4 Issue: 2

DOI: 10.4172/2167-065X.1000138 ISSN: 2167-065X

Authors: Trivedi MK, Nayak G, Patil S*, Tallapragada RM, Jana S and Mishra R

Citation: Trivedi MK, Nayak G, Patil S, Tallapragada RM, Jana S, et al (2015) Evaluation of the Impact of Biofield Treatment on Physical and Thermal Properties of Casein Enzyme Hydrolysate and Casein Yeast Peptone. Clin Pharmacol Biopharm 4: 138. doi:10.4172/2167-065X.1000138

 

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Abstract

In the present study, the influence of biofield treatment on physical and thermal properties of Casein Enzyme Hydrolysate (CEH) and Casein Yeast Peptone (CYP) were investigated. The control and treated samples were characterized by Fourier transform infrared (FT-IR) spectroscopy, differential scanning calorimetry (DSC), Thermo Gravimetric Analysis (TGA), particle size and surface area analysis. The FTIR results revealed that biofield treatment has caused reduction of amide group (amide-I and amide-II) stretching vibration peak that is associated with strong intermolecular hydrogen bonding in treated CEH as compared to control. However, no significant changes were observed in FTIR spectrum of treated CYP. The TGA analysis of treated CEH showed a substantial improvement in thermal stability which was confirmed by increase in maximum thermal decomposition temperature (217°C) as compared to control (209°C). Similarly, the treated CYP also showed enhanced thermal stability as compared to control. DSC showed increase in melting temperature of treated CYP as compared to control. However the melting peak was absent in DSC of treated CEH which was probably due to rigid chain of the protein. The surface area of treated CEH was increased by 83% as compared to control. However, a decrease (7.3%) in surface area was observed in treated CYP. The particle size analysis of treated CEH showed a significant increase in average particle size (d50) and d99 value (maximum particle size below which 99% of particles are present) as compared to control sample. Similarly, the treated CYP also showed a substantial increase in d50 and d99 values which was probably due to the agglomeration of the particles which led to formation of bigger microparticles. The result showed that the biofield treated CEH and CYP could be used as a matrix for pharmaceutical applications.

Conclusion

This study showed the influence of biofield treatment on the physical and thermal properties of the CEH and CYP. Biofield treatment did cause a significant change in structure characterization, along with an increase in particle size, melting temperature and maximum decomposition temperature as compared to control sample, which were analyzed by standard techniques. Hence we postulate that the biofield treated organic protein products (CEH and CYP) could be used either as an interesting matrix for drug delivery or as a medium for cell culture research.