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Antimicrobial Susceptibility, Biochemical Characterization and Molecular Typing of Biofield Treated Klebsiella pneumoniae

Journal:

Journal of Health & Medical Informatics
Received: September 15, 2015; Accepted: September 22, 2015; Published: September 25, 2015

Citation:

Trivedi MK, Branton A, Trivedi D, Gangwar M, Jana S (2015) Antimicrobial Susceptibility, Biochemical Characterization and Molecular Typing of Biofield Treated Klebsiella pneumoniae. J Health Med Inform 6: 206. doi:10.4172/2157-7420.1000206

Title:

Antimicrobial Susceptibility, Biochemical Characterization and Molecular Typing of Biofield Treated Klebsiella pneumoniae

Manuscript Link:

http://www.omicsonline.org/open-access/antimicrobial-susceptibility-biochemical-characterization-and-moleculartyping-of-biofield-treated-klebsiella-pneumoniae-2157-7420-1000206.pdf

 

Abstract:

Pathogenic isolates of Klebsiella pneumoniae (K. pneumoniae), particularly the extended-spectrum β-lactamase (ESBL) producing strains, are mostly associated with the failure of antibiotic therapy in nosocomial infections. The present work was designed to evaluate the impact of Mr. Trivedi’s biofield energy treatment on phenotypic and genotypic characteristics of K. pneumoniae. The strain of K. pneumoniae bearing ATCC 15380 (American Type Culture Collection) was procured from the Bangalore Genei, in sealed pack and divided into control and treated groups. Treated group was subjected to Mr. Trivedi’s biofield energy treatment and analyzed for the antimicrobial susceptibility, minimum inhibitory concentration (MIC), biochemical reactions, and biotyping using automated MicroScan Walk-Away® system. Further, the effect of biofield treatment was also evaluated using Random Amplified Polymorphic DNA (RAPD) in order to determine their epidemiological relatedness and genetic characteristics of biofield treated K. pneumoniae samples. The antimicrobial susceptibility results showed an improve sensitivity (i.e. from intermediate to susceptible) of ampicillin/sulbactam and chloramphenicol, while altered sensitivity of cephalothin (i.e. from susceptible to intermediate) was also reported as compared to the control sample. The MIC value showed two-fold decrease in MIC value of ampicillin/sulbactam (i.e. 16/8 to ≤8/4 μg/mL) and chloramphenicol (i.e. 16 to ≤ 8 μg/mL) as compared to the control. The cephalothin showed two-folds change (i.e. ≤ 8 to 16 μg/mL) in the MIC value as compared with the control. Biofield treatment showed 9.09% alterations in biochemical reactions followed by a change in biotype number (7774 4272) in the treated group with respect to the control (7774 4274). Genetic fingerprinting was performed on control and treated samples using RAPD-PCR biomarkers, which showed an average range of 11 to 15% of polymorphism among the treated samples with respect to the control. These results suggested that Mr. Trivedi’s biofield energy treatment has a significant impact on K. pneumoniae.

Keywords: Klebsiella pneumoniae; Biofield energy treatment; Antibiogram, Biochemical reactions, Polymorphism; Random Amplified Polymorphic DNA.

Abbreviations:

CAM: Complementary and Alternate Medicine; NHIS: National Health Interview Survey; NCHS: National Center for Health Statistics; ATCC: American Type Culture Collection; MIC: Minimum Inhibitory Concentration; MEGA: Molecular Evolutionary Genetics Analysis; NBPC 30: Negative Breakpoint Combo Panel 30; RAPD: Random Amplified Polymorphic DNA; PCR: Polymerase chain reaction; ESBL: Extended Spectrum β-Lactamase

Introduction

The increased medical practice for antibiotic usage creates selection pressure and results emergence of nosocomial pathogens. Klebsiella pneumoniae (K. pneumoniae ) is a Gram-negative, facultative anaerobic and rod-shaped bacterium of the Enterobacteriaceae family. It is regarded as an opportunistic pathogen that is associated with the hospital-acquired urinary tract infections, septicemia, pneumonia, and soft tissue infections [1]. K. pneumoniae is responsible for the nosocomial outbreaks worldwide, due to its ability to spread rapidly in the hospital environment [2], and results in high morbidity and mortality [3]. It has acquired resistance against extended-spectrum cephalosporins and penicillins, due to the production of extendedspectrum β-lactamases (ESBLs) [4].

Multidrug combination therapy and some alternate treatment options are required to control the infections associated with this microorganism. Due to the associated side effects and failure of drug treatment therapy, alternate and complementary therapy approach are the preferred treatment strategies. Recently, an alternate treatment approach using healing therapy or therapeutic touch known as biofield energy treatment, which has been widely reported in various research field. The biofield therapies (putative energy fields) were reported to alter the sensitivity of antimicrobial against treated microorganism [5], inhibits the growth of bacterial cultures [6], effect on in vitro cells, tissues [7], animals [8], and the clinical effects such as hematologic [9], immunologic effects [10], healing rates of wounds [11], etc. Biofield is the name given to the electromagnetic field that permeates and surrounds living organisms [12]. It is referred as the biologically produced electromagnetic and subtle energy field that provides regulatory and communication functions within the human organism. Specific environmental frequencies, are absorbed by the different biomolecules, due to changes in the movements of component parts. Therefore, the human or any living object, not only radiate but also absorb and respond to these frequencies [13]. Mr. Mahendra Kumar Trivedi is well known biofield treatment practitioners, and his unique biofield energy treatment is known as The Trivedi Effect®. Mr. Trivedi’s biofield energy treatment has been well known and studied in the field of materials science research [14 -16], agricultural science research [17,18], and microbiology research [19,20].

Due to the clinical importance of K. pneumoniae and outstanding results of biofield treatment, the present study was designed to evaluate the impact of Mr. Trivedi’s biofield energy treatment on K. pneumoniae with respect to the antimicrobial susceptibility, biochemical study, and biotype number. Further, in order to study the phenotypic characteristics of biofield treated K. pneumoniae , molecular typing using arbitrary amplification of polymorphic DNA sequences, termed as random amplified polymorphic DNA (RAPD) analysis was used [21]. RAPD is a preferred technique used in different studies for typing and discriminating the epidemiology of microorganism [22]. RAPD has an advantage over other traditional phenotypic typing methods as it is rapid, relatively inexpensive and technically feasible [23]. The aim of this study was to evaluate the impact of Mr. Trivedi’s biofield energy treatment on K. pneumoniae with respect to antibiogram characteristics and genotyping using RAPD of the organism.

Materials and Methods

K. pneumoniae ATCC 15380 [American Type Culture Collection] was procured from Bangalore Genei, in sealed pack, and stored as per the recommended storage conditions for further use. The antimicrobial susceptibility, minimum inhibitory concentration (MIC), biochemical reactions, and biotype number were evaluated using automated MicroScan Walk-Away® system (Dade Behring Inc., West Sacramento, CA) using Negative Breakpoint Combo 30 (NBPC 30) panel. RAPD was carried out using Ultrapure Genomic DNA Prep Kit; Cat KT 83 (Bangalore Genei, India). All the tested antimicrobials, biochemicals, media, and reagents were procured from Sigma-Aldrich, India.

Biofield treatment modalities

K. pneumoniae strain was divided into two groups i.e. control and treated. The treated group was in sealed pack and handed over to Mr. Trivedi for the biofield energy treatment under laboratory conditions. Mr. Trivedi provided the treatment through his energy transmission process to the treated group that includes bioenergy emission of certain wavelength, which has the ability to do the changes in the microbes without touching the sample. Mr. Trivedi’s unique energy treatment is known as The Trivedi Effect®. Mr. Trivedi visited the laboratory individually over a period of treatment and for control experiments, nobody entered the experimental room during the treatment period. Whilst handing over these cultures to Mr. Trivedi for treatment purposes, optimum precautions were taken to avoid contamination. After treatment, control and treated groups were assessed on day 10 for the antimicrobial susceptibility, minimum inhibitory concentration (MIC), biochemical reactions, biotype, and genotyping using RAPD analysis. The result of treated sample was compared with respect to the control.

Investigation of antimicrobial susceptibility assay

Investigation of antimicrobial susceptibility of K. pneumoniae was carried out with the help of automated instrument, MicroScan Walk- Away® using Negative Breakpoint Combo 30 (NBPC30) panel as per the manufacturer’s instructions. The panel was allowed to equilibrate to room temperature prior to rehydration. All opened panel were used on the same day. The tests were carried out on MicroScan, which were miniaturized of the broth dilution susceptibility test that had been dehydrated. Briefly, 100 μL of the standardized suspension of K. pneumoniae was pipetted into 25 mL of inoculum water using pluronic and inverted 8-10 times and inoculated, rehydrated, and then subjected to incubation for 16 hours at 35°C. Rehydration and inoculation were performed using the RENOK® system with inoculators-D (B1013-4). The detailed experimental procedures and conditions were followed as per the manufacturer’s instructions. Briefly, after inoculation and rehydration with a standardized suspension of K. pneumoniae , it was incubated at 35°C for 16 hours. MIC and a qualitative susceptibility like susceptible (S), intermediate (I), and resistant (R) were determined by observing the lowest antimicrobial concentration showing growth inhibition [24].

Biochemical studies

The biochemical reactions of K. pneumoniae were determined by MicroScan Walk-Away® where, interpretation of biochemical reactions for microbial identification of Gram-negative organisms [24].

Biotype number

The biotype number of K. pneumoniae was determined by MicroScan Walk-Away® processed panel data utilizing data of biochemical reactions [24].

Random Amplified Polymorphic DNA (RAPD) analysis

Three series of inoculums (one for control and other two for treatment named as treated A and B) were prepared from K. pneumoniae sample. Two inoculums (treated samples A and B) were subjected to Mr. Trivedi’s biofield energy treatment. Whilst handing over treated groups to Mr. Trivedi for biofield treatment, optimum precautions were taken to avoid the contamination. After that, the treated samples (A and B) were sub-cultured by taking 1% inoculum and inoculated to fresh 5 mL medium and labeled as treatment A-1 and treatment B-1 respectively. Control and treated samples were incubated at 37°C with 160 rpm for 18 h. Subsequently, the cultures were spun down, and genomic DNA was isolated for control and treated samples using the genomic DNA Prep Kit (Bangalore Genei, India). The RAPD was performed with all samples of K. pneumoniae using five RAPD primers, which were labelled as RBA 5A, RBA 10A, RBA 15A, RBA 21A, and RBA 22A. The PCR mixture contained 2.5 μL each of buffer, 4.0 mM each of dNTP, 2.5 μM each of primer, 5.0 μL each of genomic DNA, 2U each of Taq polymerase, 1.5 μL of MgCl2 and 9.5 μL of nuclease-free water in a total of 25 μL mixture. PCR amplification protocol was followed with initial denaturation at 94ºC for 7 min, followed by 8 cycles of denaturation at 94ºC for 1 min, annealing at 35ºC for 1 min, and extension at 72ºC for 2 min; and 35 cycle of denaturation at 94ºC for 1 min, annealing at 38ºC for 1 min, and extension at 72ºC for 1.5 min; and the final extension at 72ºC for 7 min. Amplified PCR products (12 μL) from all the samples (control and treated) were separated on 1.5% agarose gels at 75 volts, stained with ethidium bromide and visualized under UV illumination [25].

The percentage of polymorphism was calculated using following equation-

Percent polymorphism = A/B×100;

Where, A = number of polymorphic bands in treated sample; and B = number of polymorphic bands in control.

Results and Discussion

Antimicrobial susceptibility assay

The results of biofield treatment on K. pneumoniae with respect to antimicrobials susceptibility pattern and MIC are summarized in Table 1 and 2, respectively.

The antimicrobial sensitivity result of three antimicrobials namely ampicillin/sulbactam, cephalothin, and chloramphenicol showed the alteration after biofield treatment with respect to control among twenty-eight tested antimicrobials. The sensitivity of ampicillin/sulbactam and chloramphenicol was improved i.e. from intermediate (I) to susceptible (S), while cephalothin showed an altered sensitivity nature from S to I. Other tested antimicrobials did not show any alterations of sensitivity pattern as compared to the control.

MIC results were well supported with antimicrobial sensitivity data, as ampicillin/sulbactam and chloramphenicol showed decrease value of MIC after the biofield treatment. Ampicillin/sulbactam (i.e. 16/8 to ≤8/4 μg/mL) and chloramphenicol (i.e. 16 to ≤8 μg/mL) showed two folds change in MIC values as compared to the control. Cephalothin showed an alteration in MIC value i.e . from ≤8 to 16 μg/mL after biofield treatment. The rest of the tested antimicrobials did not show any alteration in MIC values with respect to the control.

Efficacy of sulbactam, a β-lactamase inhibitor, in combination with ampicillin, was well reported and a preferred treatment option against β-lactam-resistant K. pneumoniae infections. According to Hoffman et al. the combination of ampicillin/sulbactam was found to have synergistic effects, which significantly decreased the severity of pneumonia. Bronchoalveolar lavage cytologic findings, and extent of macroscopic lesions in lung tissue of the noninoculated regions were reported as compared to the individual ampicillin or sulbactam [26]. The resistance pattern of ampicillin against K. pneumoniae is because of two types of chromosomal β-lactamase enzymes being SHV-1 and LEN-1 [27], and results suggest that biofield treatment might alter these enzymes and alter the sensitivity pattern. Biofield treatment on K. pneumoniae has improved the sensitivity profile of ampicillin/ sulbactam and showed decreased MIC value by two-folds, which might be useful in the future treatment strategy against pneumoniae lung infection. Multi-drug therapies are another approach against β- lactamase producing strain of K. pneumoniae , as synergy has been frequently reported in vitro between β-lactams and aminoglycosides. According to Jones, a synergistic effect was frequently reported in a combination of ertapenem and ciprofloxacin [28]. Besides synergistic effect, antibiotics such as amikacin, gatifloxacin, gentamicin, and chloramphenicol are the preferred drug of choice with respect to cost, side effects and many other factors in K. pneumoniae associated infections [29]. Mr. Trivedi’s biofield energy treatment on K. pneumoniae showed improved sensitivity pattern of chloramphenicol and simultaneously decreased the MIC value as compared to the control. β-lactamases are enzymes that inactivates the β-lactam containing antibiotic which is present in almost all Gram-negative bacilli such as E. coli and Klebsiella spp. [30]. Biofield treatment might alter the production of these enzymes which may result in the improved sensitivity of antimicrobials.

S. No. Antimicrobial

Control

Treated

 1 Amikacin

S

S

 2 Amoxicillin/k-clavulanate

S

S

3 Ampicillin/sulbactam

I

S

4 Ampicillin

R

R

5 Aztreonam

S

S

6 Cefazolin

S

S

7 Cefepime

S

S

8 Cefotaxime

S

S

9 Cefotetan

S

S

10 Cefoxitin

S

S

11 Ceftazidime

S

S

12 Ceftriaxone

S

S

13 Cefuroxime

S

S

14 Cephalothin

S

I

15 Chloramphenicol

I

S

16 Ciprofloxacin

S

S

17 Gatifloxacin

S

S

18 Gentamicin

S

S

19 Imipenem

S

S

20 Levofloxacin

S

S

21 Meropenem

S

S

22 Moxifloxacin

S

S

23 Piperacillin/tazobactam

S

S

24 Piperacillin

I

I

25 Tetracycline

S

S

26 Ticarcillin/k-clavulanate

S

S

27 Tobramycin

S

S

28 Trimethoprim/sulfamethoxazole

S

S

R: Resistant; I: Intermediate; S: Susceptible
Table 1: Effect of biofield treatment on K. pneumoniae for its antimicrobial susceptibility

S. No. Antimicrobial Control Treated
 1 Amikacin ≤16 ≤16
2 Amoxicillin/k-clavulanate ≤8/4 ≤8/4
3 Ampicillin/sulbactam 16/8 ≤8/4
4 Ampicillin >16 >16
5 Aztreonam ≤8 ≤8
6 Cefazolin ≤8 ≤8
7 Cefepime ≤8 ≤8
8 Cefotaxime ≤8 ≤8
9 Cefotetan ≤16 ≤16
10 Cefoxitin ≤8 ≤8
11 Ceftazidime ≤8 ≤8
12 Ceftriaxone ≤8 ≤8
13 Cefuroxime ≤4 ≤4
14 Cephalothin ≤8 16
15 Chloramphenicol 16 ≤8
16 Ciprofloxacin ≤1 ≤1
 17 ESBL-a Scrn ≤4 ≤4
18 ESBL-b Scrn ≤1 ≤1
19 Gatifloxacin ≤2 ≤2
20 Gentamicin ≤4 ≤4
21 Imipenem ≤4 ≤4
22 Levofloxacin ≤2 ≤2
23 Meropenem ≤4 ≤4
24 Moxifloxacin ≤2 ≤2
25 Nitrofurantoin ≤32 ≤32
26 Norfloxacin ≤4 ≤4
27 Piperacillin/tazobactam ≤16 ≤16
28 Piperacillin 64 64
29 Tetracycline ≤4 ≤4
30 Ticarcillin/k-clavulanate ≤16 ≤16
31 Tobramycin ≤4 ≤4
32 Trimethoprim/sulfamethoxazole ≤2/38 ≤2/38

MIC values are presented in μg/mL; ESBL: Suspected extended-spectrum β-lactamases a, b screen
Table 2: Minimum inhibitory concentration (MIC) of tested antimicrobials against K. pneumoniae

Organism identification by biochemical reactions

Biochemical study results of control and biofield treated groups are summarized in Table 3.

S. No. Code Biochemical Control Treated
1 ACE Acetamide
 2 ADO Adonitol + +
3 ARA Arabinose + +
4 ARG Arginine
5 CET Cetrimide
6 CF8 Cephalothin +
7 CIT Citrate + +
8 CL4 Colistin +
9 ESC Esculin hydrolysis + +
10 FD64 Nitrofurantoin
11 GLU Glucose + +
12 H2S Hydrogen sulfide
13 IND Indole
14 INO Inositol + +
15 K4 Kanamycin
16 LYS Lysine + +
17 MAL Malonate + +
18 MEL Melibiose + +
19 NIT Nitrate +
20 OF/G Oxidation-fermentation/glucose + +
21 ONPG Galactosidase + +
22 ORN Ornithine
23 OXI Oxidase
24 P4 Penicillin + +
25 RAF Raffinose + +
26 RHA Rhamnose + +
27 SOR Sorbitol + +
28 SUC Sucrose + +
29 TAR Tartrate
30 TDA Tryptophan deaminase
31 TO4 Tobramycin
32 URE Urea + +
33 VP Voges-Proskauer

Table 3: Effect of biofield treatment on K. pneumoniae to the vital processes occurring in living organisms -: negative; +: positive.

The results showed overall 9.09% of tested biochemical altered reactions as compared to the control. The colistin and nitrate biochemical showed negative reaction i.e. from (+) positive to (-) negative as compared to the control. Cephalothin showed positive reaction i.e. from (-) negative to (+) positive reaction. The rest of tested biochemicals did not show any alteration in their reaction pattern after biofield treatment. The biochemical reactions of control K. pneumoniae were well supported with literature data [31].

Organism identification by biotype number

Based on the biochemical results, alteration in biotype number was also observed in the biofield treated K. pneumoniae as compared to the control. The control group showed biotype number as 7774 4274, while after treatment altered biotype number was reported as 7774 4272. However, no change in organism was reported after biofield treatment with respect to the control. Our research group recently reported the significant alterations in biochemical reactions followed by the change in biotype number that was also supported with published data [19,20]. Biofield treatment might alter some enzymatic reactions in K. pneumoniae , which resulted in alterations in characteristic biochemical reactions and biotype number.

Random Amplified Polymorphic DNA (RAPD) analysis

RAPD has been used as a genotyping tool to that is being used to correlate the genetic similarity or mutations between species of K. pneumoniae [32]. DNA fingerprinting analysis of the control and treated K. pneumoniae was identified on the basis of their different and discriminative RAPD patterns. The simplicity and wide applicability of RAPD analysis mainly depend on the use of short nucleotide primers, which were unrelated to known DNA sequences of the target organism [21]. DNA polymorphism can be efficiently detected using the PCR primers and identify the inter-strain variations among species in the treated samples. The degree of relatedness and genetic mapping can be correlated between similar or different treated sample species [33].

In this experiment, DNA fingerprinting of control and treated samples using RAPD are shown in Figure 1.

Fi-1

Figure 1: Random amplified polymorphic-DNA fragment patterns of K. pneumoniae generated using five RAPD primers, RBA 5A, RBA 10A, RBA 15A, RBA 21A and RBA 22A. 1: Control; 2: Treated A; 3: Treated A-1; 4: Treated B; 5: Treated B-1; M: 100 bp DNA Ladder.

The polymorphic bands are marked by arrows in the gel image. The RAPD patterns of treated samples showed some unique, dissimilar, common, and polymorphic patterns. DNA polymorphism among the different treated samples compared with the control were analyzed and presented in Table 4.

S. No.

 

Primer

Nucleotide sequence (5’-3’)

Total no. of polymorphic bands

Common bands in control and treated

Unique band

Control

TSA

TSA-1

TSB

TSB-1

1 RBA 5A

GTTTCGCTCC

18

11

1

2

1

1

2

2

RBA 10A

GTGGATCCGA

15

5

3

1

0

0

0

3

RBA 15A

GCGATCCCCA

12

8

1

1

0

0

0

4

RBA 21A

CCGCAGCCAA

15

13

0

0

0

0

0

5

RBA 22A

AAGAGCCCGT

14

5

1

1

0

2

0

Table 4: DNA polymorphism of K. pneumoniae analyzed by random amplified polymorphic DNA (RAPD) analysis, TSA: treated sample A; TSA-1: treated sample A-1; TSB: treated sample B; TSB-1: treated sample B-1.

The level of polymorphism between control and treated samples (A, A1, B, and B1) are summarized in Table 5.

 

Primer

C and TSA C and TSA-1 C and TSB C and TSB-1 TSA and TSA-1 TSB and TSB-1 TSA and TSB TSA-1 and TSB-1
RBA 5A 18% 12% 12% 18% 18% 18% 6% 6%
RBA 10A 30% 15% 15% 23% 10% 0% 15% 8%
RBA 15A 18% 27% 27% 9% 11% 0% 9% 15%
RBA 21A 0% 6% 0% 0% 0% 0% 0% 6%
RBA 22A 13% 6% 20% 6% 10% 20% 5% 0%
Average polymorphism 15% 13% 14% 11% 9% 7% 7% 7%

Table 5: Level of polymorphism between control and treated K. pneumoniae samples. C: Control; TSA: treated sample A; TSA-1: treated sample A-1; TSB: treated sample B; TSB-1: treated sample B-1.

The level of polymorphism was found in an average range of 11 to 15% in the treated samples as compared to control after the biofield treatment. The highest change in DNA sequence was observed in treated samples with RBA 10A primer as compared to control; whereas no change was found in treated sample with RBA 21A primer as compared to control. Thus, results indicates that treatment samples has genetic variability among organism. RAPD also explains the relevant degree of genetic diversity, however this technique has the potential to detected genetic polymorphism throughout the genome [34].

Biofield energy as the complementary medicine is well documented and considered as alternate medicine approach worldwide. According to the report of National Health Interview Survey (NHIS), conducted by the Centers for Disease Control and Prevention’s (CDC) and National Center for Health Statistics (NCHS) till 2007, energy medicine was practiced almost 4 out of 10 adults in the past 12 months [35]. Current experiment was designed to demonstrate the impact of Mr. Trivedi’s biofield treatment on K. pneumoniae for its antimicrobial susceptibility testing. Further, the molecular methods was performed to study the genetic alterations and similarities using RAPD sequencing methods. Increased infection of K. pneumoniae and other Gram-negative pathogen associated with nosocomial infections have become a global health problem. Results suggest that biofield treatment on microorganism can alter the in vitro sensitivity of the antimicrobials and it might be correlated with acetylation of antimicrobials that may happen via active drug efflux mechanism. Increased incidence of nosocomial infections and broad resistance against broad spectrum antibiotics would be a serious global threat. Mr. Trivedi’s biofield treatment showed a significant decrease in MIC values of ampicillin/sulbactam and chloramphenicol along with improved sensitivity, which suggested an alteration at enzymatic/ genetic level that may modify ligand-receptor interaction. Hence a cascade of intra-cellular signals may be initiated, accelerated or inhibited [36], after biofield treatment on pathogenic microbes. Further, biofield treatment on K. pneumoniae , possible involve alterations at receptor level due to energy transfer via. biofield treatment, which may change the receptor drug interactions, which in turn alter the internal state of the microbe. However, it was reported that electromagnetic fields might alter the transmembrane concentration of cell, and will alter the receptor protein molecule. Biofield treatment might alter the receptor interaction, and results in altered antibiogram of K. pneumoniae with respect to the control [37].

Conclusion

In summary, it can be concluded that Mr. Trivedi’s biofield energy treatment on K. pneumoniae has improved the antimicrobial sensitivity and decreased the MIC value by two folds in case ampicillin/sulbactam and chloramphenicol. Cephalothin showed altered antibiogram after biofield treatment as compared to the control. The biochemical study results showed the alteration of biochemical reactions of cephalothin, colistin, and nitrate, followed by change in the biotype number (7774 4272) after biofield treatment as compared to the control biotype (7774 4274). Using RAPD markers, the biofield treated samples were characterized and showed interspecific polymorphic relationship with K. pneumoniae after biofield treatment. Overall, it seems that Mr. Trivedi’s unique biofield energy treatment on pathogenic microbes might be used as an alternate approach to alter the antimicrobial sensitivity.

Acknowledgement

This work was supported by Trivedi Science™, Trivedi Master Wellness™ and Trivedi Testimonials. Authors acknowledge the generosity and cooperation of all participating members from PD Hinduja National Hospital and MRC, Mumbai, Microbiology Lab for conduction antimicrobial studies. Authors are thankful to Bangalore Genei Private Limited, for conducting RAPD analysis.

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