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Impact of Biofield Treatment on Chemical and Thermal Properties of Cellulose and Cellulose Acetate | OMICS International
ISSN: 2155-9538
Journal of Bioengineering & Biomedical Science

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Impact of Biofield Treatment on Chemical and Thermal Properties of Cellulose and Cellulose Acetate

Mahendra Kumar Trivedi, Gopal Nayak, Shrikant Patil*, Rama Mohan Tallapragada and Rakesh Mishra

Trivedi Global Inc., 10624 S Eastern Avenue Suite A-969, Henderson, NV 89052, USA

*Corresponding Author:
Shrikant Patil
Trivedi Global Inc.
10624 S Eastern Avenue Suite A-969
Henderson, NV 89052, USA
Tel: +1 602-531-5400
E-mail: [email protected]

Received Date: June 03, 2015; Accepted Date: July 27, 2015; Published Date: August 07, 2015

Citation: Trivedi MK, Nayak G, Patil S, Tallapragada RM, Mishra R (2015) Impact of Biofield Treatment on Chemical and Thermal Properties of Cellulose and Cellulose Acetate. J Bioengineer & Biomedical Sci 5:162. doi:10.4172/2155-9538.1000162

Copyright: © 2015 Trivedi MK, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

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Abstract

Cellulose being an excellent biopolymer has cemented its place firmly in many industries as a coating material, textile, composites, and biomaterial applications. In the present study, we have investigated the effect of biofield treatment on physicochemical properties of cellulose and cellulose acetate. The cellulose and cellulose acetate were exposed to biofield and further the chemical and thermal properties were investigated. X-ray diffraction study asserted that the biofield treatment did affect the crystalline nature of cellulose. The percentage of crystallite size was found increased significantly in treated cellulose by 159.83%, as compared to control sample. This showed that biofield treatment was changing the crystalline nature of treated cellulose. However treated cellulose acetate showed a reduction in crystallite size (-17.38%) as compared to control sample. Differential Scanning Calorimetry (DSC) of treated cellulose showed no improvement in melting temperature as compared to control sample. Contrarily cellulose acetate showed significant improvement in melting temperature peak at 351.91ºC as compared to control (344ºC) polymer. Moreover percentage change in latent heat of fusion (ΔH) was calculated from the DSC thermogram of both treated and control polymers. A significant increase in percentage ΔH of both treated cellulose (59.09%) and cellulose acetate (105.79%) polymers indicated that biofield treatment enhanced the thermal stability of the treated polymers. CHNSO analysis revealed a significant change in percentage hydrogen and oxygen of treated cellulose (%H-17.77, %O-16.89) and cellulose acetate (%H-5.67, %O-13.41). Though minimal change was observed in carbon percentage of both treated cellulose (0.29%) and cellulose acetate (0.39%) polymers as compared to their respective control samples. Thermo gravimetric analysis and Differential thermo gravimetric (TGA-DTG) analysis of treated cellulose acetate (353ºC) showed increased maximum thermal decomposition temperature as compared to control polymer (351ºC). This showed the higher thermal stability of the treated cellulose acetate polymer; although the maximum thermal decomposition temperature of treated cellulose (248ºC) was decreased as compared to control cellulose (321ºC). These outcomes confirmed that biofield treatment has changed the physicochemical properties of the cellulose polymers.

Keywords

Biofield treatment; Cellulose; Cellulose acetate; XRD; DSC; TGA; CHNSO

Introduction

Polymer based materials; especially naturally occurring biopolymers have been widely used as biomaterials for tissue engineering, artificial skin, wound healing, sutures, tissue constructs, gene delivery, and drug delivery [1]. Cellulose is one of the most abundant naturally occurring biopolymer on earth [2-3]. Several naturally occurring fibers including cotton; and higher plants contain cellulose as their main constituent [4-5]. It consists of long chains of anhydro-D-glucopyranose units (AGU); each cellulose molecule possesses three hydroxyl groups per AGU, with an exception of terminal ends. Cellulose is insoluble in water and in most commonly used organic solvents [3], the poor solubility of cellulose is attributed to strong inter and intra-molecular hydrogen bonding between the individual chains [2].

Cellulose based materials are being employed as components of scaffolds for bone regeneration (Gengiflex®), artificial blood vessel (BASYC®), temporary skin substitutes (Biofill®), hemodialysis membranes (Cuprophan® and Fresenius Polysulfone®) and controlled drug release systems [6-10]. In chronic wound dressing, it has provided the moist environment for optimal wound healing due to its ability to absorb water directly into its fibers (AQUACEL® and Cellstick® ) [11]. Recently, cellulose has been proposed to be used as a dialysis membrane for bio artificial pancreas and immuno-isolation of islet transplantation [12].

Cellulose acetate is the ester of cellulose, which is utilized in the production of high-quality fiber mats. Cellulose acetate confers excellent thermal and mechanical properties, which make it an excellent material for diverse applications in engineering, plastics, and biomaterials [13-15]. Ye et al. attempted to prove that the proper surface modification of cellulose acetate can make it fascinating for biomaterial applications [16]. Chemical modification of cellulose was performed to improve processability and to produce cellulose derivatives (cellulosic), which can be tailored to specific industrial applications [17].

Biofield is a cumulative effect, induced by particular human body on external surroundings. Mr. Trivedi is well known to transform the physical and structural properties at the atomic level of the various living and non-living things through his unique biofield. We have previously reported that Mr. Trivedi’s biofield, herein referred as Biofield treatment, has significantly enhanced the structural, atomic and thermal properties of transition metals, metal oxides, ceramics and carbon allotropes [18-26].

It was observed that in various ceramic and metal powders, the biofield exposure had substantially changed the lattice parameter, unit cell volume, density, crystallite size and molecular weight. For example, the biofield treatment had increased the particle size by 21.1% in zirconium oxide which was never been observed in case of ceramics and it was postulated that biofield had caused deformation of the crystals without activating the fracture paths [24]. Additionally, biofield has significantly enhanced the yield and quality of various agriculture products [27-30]. Moreover, Mr. Trivedi’s biofield has caused changes in the antibiotic susceptibility patterns as well as produced biochemical reactions that induced changes in the characteristics of pathogenic microbes [31-33]. Furthermore biofield has significantly improved the growth and anatomical characteristics of herb Pogostemon cablin [34].

Having inspired by excellent properties of cellulose and cellulose acetate, we put an attempt to modify the physicochemical parameters of cellulose polymers through biofield treatment, which were characterized for their physicochemical properties by X-ray Diffraction (XRD), Differential Scanning Calorimetry (DSC), Thermo Gravimetric Analysis (TGA) and CHNSO analysis.

Materials and Methods

The powdered sample of cellulose and cellulose acetate were procured from Sigma Aldrich, USA. The procured samples of both the polymers were divided into two parts; one was kept as a control sample, while the other was subjected to Mr. Trivedi’s biofield treatment and coded as treated sample.

Characterization of Physicochemical Parameters

CHNSO analysis

The control and treated cellulose and cellulose acetate samples were analyzed using CHNSO Analyzer, Model Flash EA 1112 series, Thermo Finnigan, Italy.

X-ray diffraction (XRD) study

The XRD study of both the cellulose and cellulose acetate powder (control and treated) samples were analyzed by using a Phillips Holland PW 1710 X-ray diffractometer system. A copper anode with nickel filter was used. The wavelength of the radiation was 1.54056 ?. The obtained data was used for calculation of crystallite size using the following formula.

Crystallite size=kλ/b cos θ

Where λ is the wavelength and k is the equipment constant (0.94).

Differential scanning calorimetry (DSC)

The DSC data of cellulose and cellulose acetate (control and treated) samples were analyzed by using Pyris-6 differential scanning calorimeter (DSC) (Perkin Elmer, USA), at a heating rate of 10ºC/min with a nitrogen flow of 5 mL/min.

Thermo gravimetric analysis (TGA)

The thermal stability of the cellulose and cellulose acetate samples (control and treated) were analyzed by using a Metller Toledo simultaneous thermo gravimetric analyzer and differential thermal analysis (DTA). The samples were heated from room temperature to 400°C with a heating rate of 5°C/min under oxygen atmosphere.

Results

CHNSO analysis

The control and treated polymer samples were subjected to CHNSO analysis and data are summarized in (Table 1). The control cellulose sample showed the similar amount of carbon, hydrogen and nitrogen as reported previously [35]. The treated cellulose polymer showed a very minimal increase in the percentage of carbon (0.27%) as compared to control sample. Whereas the significant amount of increased percentage of hydrogen (17.77%) and oxygen (16.89%) was observed in treated cellulose as compared to control polymer. However, no nitrogen trace was observed in treated cellulose and cellulose acetate, which showed purity of the samples. The treated cellulose acetate showed an increased (0.39%) percentage of carbon as compared to control. The hydrogen and oxygen percentage in treated cellulose acetate increased significantly by 5.67% and 13.41% as compared to control polymer. This showed that biofield had changed the elemental composition (C, H and O) of the treated cellulose and cellulose acetate polymers.

Parameter Cellulose Cellulose Acetate
Nitrogen control
Nitrogen treated
%change in nitrogen
0.00
0.00
-
0.00
0.00
-
Carbon control
Carbon treated
%change in Carbon
41.85
41.97
0.27
47.56
47.75
0.39
Hydrogen control
Hydrogen treated
%change in hydrogen
5.96
7.01
17.77
5.66
5.98
5.67
Oxygen control
Oxygen treated
%change in Oxygen
32.49
37.97
16.89
29.29
33.22
13.41

Table 1: CHNSO analysis of cellulose and cellulose acetate.

X-ray diffraction (XRD) analysis

The XRD studies were conducted on both the control and treated polymers (cellulose and cellulose acetate), and the data are illustrated in [Figure 1 (1a, 1b, 1c and 1d)]. The XRD diffractogram of control cellulose showed well-defined crystalline peaks (Figure 1a) at 2θ equals to 16.69° and 34.37°, which corroborated its crystalline nature. Similarly, the treated cellulose also showed (Figure 1b) two crystalline peaks at 2θ equals to 16.27° and 22.53°, which supported the crystalline nature of treated cellulose. According to Wada et al. the peak at 2θ equals to 16.27°, and 22.53° reflection could be assigned to (110) and (200) crystallographic plane, respectively [36].

bioengineering-biomedical-science-diffractogram

Figure 1a: XRD diffractogram of cellulose (Control).

bioengineering-biomedical-science-cellulose

Figure 1b: XRD diffractogram of cellulose (Treated).

bioengineering-biomedical-science-acetate

Figure 1c: XRD diffractogram of cellulose acetate (Control).

bioengineering-biomedical-science-acetate

Figure 1d: XRD diffractogram of cellulose acetate (Treated).

Contrarily, cellulose acetate (control) showed (Figure 1c) more semi-crystalline nature [37,38] as evidenced from two peaks at 2θ equals to 10.50° and 13.13°. However, XRD diffractogram of treated cellulose acetate have not showed (Figure 1d) any significant change in peak position.

Differential scanning calorimetry (DSC)

DSC thermogram of control and treated polymers (cellulose and cellulose acetate) are presented in [Figure 2]. (Figure 2a and 2b) showed a sharp endothermic inflection at 328.51°C and 328.32°C due to the melting temperature peak of control (Figure 2a) and treated cellulose (Figure 2b), respectively. The higher melting temperature of cellulose material correlated to its high thermal stability. Figure 2c and 2d showed endothermic peaks at 344.14°C and 351.91°C, which was ascribed to melting temperature of control and treated cellulose acetate, respectively. These observed endothermic peak of control (Figure 2c) and treated cellulose acetate (Figure 2d) were much higher than melting temperature reported by Scott [39], Valente et al. [40], and Kee et al. for cellulose acetate polymer [41]. The high melting peak of the treated cellulose acetate was mainly due to excellent thermal stability as compared to control cellulose acetate.

bioengineering-biomedical-science-thermogram

Figure 2a: DSC thermogram of cellulose (Control).

bioengineering-biomedical-science-cellulose

Figure 2b: DSC thermogram of cellulose (Treated).

bioengineering-biomedical-science-thermogram

Figure 2c: DSC thermogram of cellulose acetate (Control).

bioengineering-biomedical-science-acetate

Figure 2d: DSC thermogram of cellulose acetate (Treated).

Thermo gravimetric analysis/differential thermal analysis (TGA/DTA):

The TGA/DTA thermogram of control and treated cellulose samples are illustrated in (Figures 3a and 3b), respectively. TGA thermogram of control cellulose exhibited (Figure 3a) single step thermal degradation pattern at 280-360°C where sample lost 69.71% of its original polymer weight. The maximum decomposition temperature (Tmax) of control cellulose was observed at 321.22°C, which was relatively higher than previously reported value by Rescignano et al. [42]. However, after biofield exposure, a decrease was observed in maximum decomposition temperature of treated cellulose (248°C) as compared to the control sample (Figure 3b).

bioengineering-biomedical-science-thermogram

Figure 3a: TGA thermogram of cellulose (Control).

bioengineering-biomedical-science-cellulose

Figure 3b: TGA thermogram of cellulose (Treated).

bioengineering-biomedical-science-control

Figure 3c: TGA thermogram of cellulose acetate (Control).

bioengineering-biomedical-science-treated

Figure 3d: TGA thermogram of cellulose acetate (Treated).

Figures 3c and 3d showed the TGA thermogram of control and treated cellulose acetate. The control cellulose acetate (Figure 3c) sample showed multi-step thermal degradation pattern: polymer started to degrade at 230°C and ended at 290°C, with sample loss of 24.99%; the second thermal decomposition event started at 310°C and terminated at 370°C with sample loss of 68.08% from its original polymer weight. Differential thermo gravimetric (DTG) of control cellulose acetate showed maximum decomposition temperature (Tmax) at 351°C. Contrarily, the biofield exposed cellulose acetate showed (Figure 3d) single step thermal decomposition pattern (320-390°C) with 87% of weight loss.

Discussion

It was previously suggested that the degree of cellulose crystallinity is one of the most important crystalline structure parameters. The rigidity of cellulose increases with tight inter crystalline packing and their flexibility decreases with increasing ratio of crystalline to amorphous form. Moreover, the free –OH group along the macromolecule chain of cellulose are involved in a number of inter/intra molecular hydrogen bonding, which may assist in the formation of various long range ordered crystalline planes [43]. The crystalline cellulose is mainly present in four different polymorphic forms (I, II, III, and IV) in nature. On the basis of different investigations, previously it was suggested that cellulose Iα has one chain triclinic structure, and cellulose Iβ has two chains monoclinic structure.

In the present work, the crystallite size was calculated from the X-ray diffractogram of the control and treated cellulose sample (Table 2). The calculated crystallite size for control cellulose was 10.72 nm, which was increased up to 27.85 nm in treated cellulose. This increase in crystallite size enhanced the crystallinity indices because the crystalline surface corresponding to amorphous cellulose regions disappeared. The percentage crystallite size in treated cellulose was significantly increased by 159.83% as compared to control polymer which confirmed that biofield was significantly alleviating the crystalline pattern of cellulose. It was previously demonstrated that cellulose can be converted into a more crystalline stable form by a variety of treatments.

Polymer Powder Crystallite size (nano meter) Percentage change in crystallite size
  Control Treated
Cellulose 10.72 27.85 159.83
Cellulose acetate 21.91 18.1 -17.38

Table 2: Percentage crystallite size of cellulose and cellulose acetate.

DSC analysis is an important technique to measure the glass transition, melting temperature and change in latent heat of fusion of different materials. The DSC result of treated cellulose showed similar melting temperature (328.51ºC) as showed by the control polymer (328.32ºC). However treated cellulose acetate showed a marked increase (7.77°C ± 1ºC) in melting peak as compared to control polymer. These findings clearly showed that exposing cellulose acetate to biofield treatment enhanced the thermal stability of the polymer. We presume that biofield has improved the long-range order or regular pattern of atoms, present in the polymer, which lead to improvement in crystallinity. Hence, more thermal energy was required to disturb the crystalline pattern, which increased the thermal stability of treated cellulose acetate. The treated cellulose showed substantially increased percentage latent heat of fusion (ΔH) 59.09% as compared to control cellulose sample. The increased percentage ΔH of treated cellulose was may be associated with biofield energy absorption by the polymer. The treated cellulose acetate also showed a significant elevation in percentage ΔH of treated cellulose acetate by 105.79%. It was postulated that biofield had caused significant changes in both polymers at the atomic level.

TGA was used to get further insights about the thermal stability of cellulose and cellulose acetate. The maximum decomposition temperature was observed at 353°C based on DTG, which corroborated the improved thermal stability of the treated cellulose acetate as compared to control polymer (351°C); this was well supported by our DSC results.

Cellulose based polymers have been used commonly for wound dressing and tissue regeneration applications. The wound dressing and skin repair materials should have excellent ability to absorb exudates, prevent bacterial infection, inhibit bleeding and maintain proper water, electrolyte balance [44]. Nevertheless, due to low strength and elasticity some commercial wound dressings did not satisfy ideal healing requirements as they tend to stick to wound surface or crushed under high stress [45]. The cellulose acetate polymer is a hydrophilic polymer with good liquid transport and water absorption abilities. However, poor mechanical and resistance properties limit its applications as a wound dressing material. Hence, in present work cellulose acetate and cellulose were treated with biofield to improve its physicochemical properties. Our XRD and DSC result demonstrated the significant increase in crystalline and thermal properties of these polymers (cellulose and cellulose acetate) after biofield exposure. It was expected that increased crystalline nature and high temperature stability may confer excellent mechanical properties that will be crucial for its wound healing applications.

Conclusion

The present work reports the effect of Mr. Trivedi’s biofield on chemical and thermal properties of cellulose based polymers (cellulose and cellulose acetate). The XRD studies revealed well-defined crystalline behavior for both control cellulose and biofield treated sample.

Biofield treated sample showed greater crystallite size as compared to control cellulose, which was quite unexpected, and we hypothesize that biofield was inducing more long range order between the atoms alleviating its crystalline nature. Though a decrease in crystallite size was observed in treated cellulose acetate as compared to control sample.

The DSC thermogram of control cellulose showed no change in melting behavior, on the other hand, treated cellulose acetate showed enhanced melting temperature peak, which revealed the high thermal stability of the respective polymer. CHNSO results corroborated substantial increase in percentage hydrogen and oxygen of treated polymers (cellulose and cellulose acetate) as compared to control sample. TGA analysis confirmed the higher thermal stability of treated cellulose acetate as compared to control; however thermal stability was decreased in treated cellulose as compared to control. Energy from the Biofield treatment that was absorbed by the treated samples might have played an important role that caused a substantial increase in the latent heat of fusion of both the treated samples. Based on the results achieved, we conclude that the biofield treated polymers could play an important role in the applications of wound dressing materials.

Acknowledgements

The authors thank to staff of various laboratories for their constant support in instrumental handling. We also extend our gratitude to Dr. Cheng Dong of NLSC, Institute of Physics, and Chinese academy of Sciences for allowing us to use Powder X software for analyzing XRD data.

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