Abstract:
Klebsiella are opportunistic pathogens that cause a wide spectrum of severe diseases. The aim of the present study was to investigate the impact of biofield treatment on multidrug resistant strain of K. oxytoca with respect to antibiogram pattern along with biochemical study and biotype number. Clinical lab isolate of K. oxytoca was divided into two groups i.e. control and treated. Control group remain untreated and treated group was subjected to Mr. Trivedi’s biofield. The analysis was done on day 10 after biofield treatment and compared with control group. Control and treated groups were analyzed for antimicrobial susceptibility pattern, minimum inhibitory concentration (MIC), biochemical reactions and biotype number using MicroScan Walk-Away® automated system. Experimental results showed the impact of biofield treatment on K. oxytoca and found alteration in both antimicrobial sensitivity and MIC values as compared with untreated group. Antimicrobial sensitivity of about 26.67% tested antimicrobials out of thirty was altered with respect to control. MIC results showed about 12.50% alterations in tested antimicrobials as compared to control. Biochemical study showed 24.24% alteration in tested biochemical reactions after biofield treatment. A significant change in biotype number (7713 5272) was identified after biofield treatment as compared to control (7775 4332). In treated group, a new species was identified as Kluyvera ascorbata, as compared to control, K. oxytoca. Study findings suggest that biofield treatment has a significant effect in altering the antimicrobial sensitivity, MIC values, biochemical reactions and biotype number of multidrug resistant strain of K. oxytoca. Biofield treatment could be applied to alter the antibiogram-resistogram pattern of antimicrobials.
Abstract:
Klebsiella oxytoca (K. oxytoca) is a Gram-negative microbe generally associated with community and hospitalacquired infections. Due to its clinical significance, we evaluated the effect of biofield treatment on phenotype and biotype characteristics of K. oxytoca (ATCC 43165). The study was performed into three groups i.e. C (control), T1 (treatment, revived); and T2 (treatment, lyophilized). Subsequently, groups T1 and T2 were received biofield treatment and control group was remained as untreated. The antimicrobial sensitivity results showed 3.33% and 6.67% alteration in antimicrobials susceptibility in group T1 cells on day 5 and 10, respectively, and 3.33% alteration in antimicrobials susceptibility was observed in group T2 cells on day 10 as compared to control. The sensitivity patterns of cefazolin were changed from resistant (R) to intermediate (I) on day 5, and resistance (R) to susceptible (S) on day 10, in T1 cells of K. oxytoca. The MIC value of cefazolin was decreased by 2-fold in group T1 on day 10 as compared to control. The biofield treated K. oxytoca exhibited the changes in biochemical reactions about 3.03% and 15.15% of total tested biochemicals in group T1 cells on day 5 and 10, respectively as compared to control. The biotype number of K. oxytoca was altered in biofield treated group and organism identified as Raoultella ornithinolytica in T1 on day 10 as compared to control, which is the prominent finding of this study. These changes were found in treated bacteria that might be due to some alteration happened in metabolic/enzymatic pathway and/ or at genetic level of K. oxytoca. Based on these data, it is speculated that biofiled treatment could be an alternative approach that can improve the effectiveness of the existing antimicrobials against the resistant pathogens.
Klebsiella oxytoca is a Gram-negative, rod-shaped bacterium that is closely related to K. pneumoniae, from which it is distinguished by being indole-positive; it also has slightly different growth characteristics in that it is able to grow on melezitose, but not 3-hydroxybutyrate. It was first described in 1886 when it was isolated from sour milk and named Bacillus oxytocus perniciosus (from Greek oxus 'sour' + -tokos 'producing').[1]
Klebsiella oxytoca is characterized by negative methyl red, positive VP, positive citrate, urea and TSI gas production, is AA, and negative for TSI sulfide, DNAse, growth on sulfide-indole motility medium and the phenylalanine deaminase test.
It is a diazotroph, able to colonise plant hosts and fix atmospheric nitrogen into a form which the plant can use. Association of K. oxytoca with the barley rhizosphere during an entire vegetative period has been demonstrated. The bacteria adhere strongly to root hairs, and less strongly to the surface of the zone of elongation and root cap mucilage.[2]
Like other enterobacteria, it is capable of acquiring antibiotic resistance, and isolates have been shown to produce extended-spectrum beta-lactamases as well as carbapenemases.[3]
Klebsiella oxytoca has shown promise in industrial ethanol fuel production,[4] and is referenced as being used to produce hydrogen in patents filed by Nanologix, Inc.
Infections can result in colitis and sepsis.[5]
Outbreaks of antibiotic-resistant Klebsiella oxytoca have occurred in multiple hospitals and ICUs throughout the world, and handwashing stations have been identified as a potentially important environmental reservoir.[6]
Houseflies (Musca domestica) have a mutualistic relationship with the bacterium K. oxytoca. This bacterium can live on the surface of the housefly eggs and has a deterrent effect on the fungi growing in manure, thus benefiting the fly larvae which are competing with the fungi for nutrients.[7]
Klebsiella oxytoca is a Gram-negative, rod-shaped bacterium that is closely related to K. pneumoniae, from which it is distinguished by being indole-positive; it also has slightly different growth characteristics in that it is able to grow on melezitose, but not 3-hydroxybutyrate. It was first described in 1886 when it was isolated from sour milk and named Bacillus oxytocus perniciosus (from Greek oxus 'sour' + -tokos 'producing').
Klebsiella oxytoca is characterized by negative methyl red, positive VP, positive citrate, urea and TSI gas production, is AA, and negative for TSI sulfide, DNAse, growth on sulfide-indole motility medium and the phenylalanine deaminase test.
It is a diazotroph, able to colonise plant hosts and fix atmospheric nitrogen into a form which the plant can use. Association of K. oxytoca with the barley rhizosphere during an entire vegetative period has been demonstrated. The bacteria adhere strongly to root hairs, and less strongly to the surface of the zone of elongation and root cap mucilage.
Like other enterobacteria, it is capable of acquiring antibiotic resistance, and isolates have been shown to produce extended-spectrum beta-lactamases as well as carbapenemases.