Capacitive Coupling Reduces Instrumentation-related Infection in Rabbit Spines: A Pilot Study

Gilotra, Mohit N.; Griffith, Cullen; Schiavone, Jason; Nimmagadda, Naren; Noveau, Jenna; Ludwig, Steven C.

doi:10.1007/s11999-011-2231-1

Cited by 9 publications

(7 citation statements)

References 26 publications

(31 reference statements)

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“…showed the efficacy of non-homogenous electric fields (3–4 V/cm) to effectively control the P. aeruginosa and S. aureus growth rate and showed a synergistic effect when applied alongside chloramphenicol treatment [118]. Some studies have also demonstrated the effectiveness of a pulsed electromagnetic field (2000 μA, 1210–7500 V/cm) with increased number of pulses and pulsed electric field that leads to bacterial cell wall disintegration and internal alteration of the core in an in vitro and rabbit spine infection model, which also showed a synergistic effect with the antibiotic ceftriaxone [115, 119, 120, 121]. Studies have also shown the eradication of S. epidermidis , S. aureus and P. aeruginosa biofilms with the use of DC currents (1800 μA) [122, 123].…”

Section: Main Textmentioning

confidence: 99%

Bacterial biofilm formation on implantable devices and approaches to its treatment and prevention

Khatoon

McTiernan

Suuronen

et al. 2018

Heliyon

869

652

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In living organisms, biofilms are defined as complex communities of bacteria residing within an exopolysaccharide matrix that adheres to a surface. In the clinic, they are typically the cause of chronic, nosocomial, and medical device-related infections. Due to the antibiotic-resistant nature of biofilms, the use of antibiotics alone is ineffective for treating biofilm-related infections. In this review, we present a brief overview of concepts of bacterial biofilm formation, and current state-of-the-art therapeutic approaches for preventing and treating biofilms. Also, we have reviewed the prevalence of such infections on medical devices and discussed the future challenges that need to be overcome in order to successfully treat biofilms using the novel technologies being developed.

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Section: Main Textmentioning

confidence: 99%

Bacterial biofilm formation on implantable devices and approaches to its treatment and prevention

Khatoon

McTiernan

Suuronen

et al. 2018

Heliyon

869

652

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“…While the use of ES in wound care management is well established, we did not identify any previous studies assessing the impact of ES on wound biofilms in a human ex vivo model. Investigations of ES against biofilms in vivo are also sparse, with only six studies to date having assessed the effect of ES on biofilms, with the majority showing positive outcomes; however, none of these studies investigated the direct effect of ES on cutaneous wound bacterial biofilms.…”

Section: Discussionmentioning

confidence: 99%

Electrical stimulation disrupts biofilms in a human wound model and reveals the potential for monitoring treatment response with volatile biomarkers

Ashrafi

Frazer

Morris

et al. 2018

Wound Repair Regeneration

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Management of biofilm infections relies on time‐consuming laboratory techniques and monitoring treatment by subjective clinical evaluations. Due to these limitations, there is a need to explore alternative strategies. The aims of this study were to assess the feasibility of using volatile organic compound (VOC) biomarkers to monitor treatment response and measure anti‐biofilm efficacy of electrical stimulation (ES) in vitro and in human cutaneous wound biofilm models. Staphylococcus aureus (MSSA) and Pseudomonas aeruginosa (PA) biofilms were exposed to ES, ciprofloxacin, or both, with efficacy assessed and quantified by fluorescence staining, enumeration, metabolic assays, and biomass quantification; VOCs were measured by gas chromatography–mass spectrometry. In vitro MSSA and PA and ex vivo PA biofilms exposed to ES showed significantly reduced bacterial viability, metabolic activity, and biomass compared to controls (p < 0.05). There was significant variation in the relative abundance of VOCs in in vitro MSSA and PA and in ex vivo PA biofilms exposed to ES and antibiotic (p < 0.05). 2‐methyl‐1‐propanol was associated with MSSA viability (R = 0.93, p < 0.05), biomass (R = 0.97, p < 0.05), and metabolic activity (R = 0.93, p < 0.05) and 3‐methyl‐1‐butanol was associated with PA biomass (R = 0.93, p < 0.05). We showed that ES and VOC biomarkers are possible options for alternative nonpharmacological antimicrobial management of biofilms and noninvasive monitoring of wound infection treatment responses, respectively.

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“…This could be the result of disruption of the biofilm to release bacteria in the more vulnerable planktonic form or through a molecular or microenvironmental mechanism that is currently unknown. Although there have been numerous in vitro reports on the antimicrobial effects of direct electrical simulation with or without combination with antibiotics [3,6,8,9,17,18,24], there are only a few in vivo reports [7,13,23]. In contrast to the other in vivo models using electrical stimulation to treat implant-associated infections [7,13,23], CVCES uses a three-electrode configuration that allows us to precisely control the cathodic potential of the titanium implant [10,11].…”

Section: Discussionmentioning

confidence: 99%

“…Although there have been numerous in vitro reports on the antimicrobial effects of direct electrical simulation with or without combination with antibiotics [3,6,8,9,17,18,24], there are only a few in vivo reports [7,13,23]. In contrast to the other in vivo models using electrical stimulation to treat implant-associated infections [7,13,23], CVCES uses a three-electrode configuration that allows us to precisely control the cathodic potential of the titanium implant [10,11]. Although the exact antimicrobial mechanism of CVCES is not well understood, it is believed that cathodic modulation of Ti's voltage-dependent properties is one of the main driving factors for the robust antibacterial effects we have observed in our experiments [10,11,19].…”

Section: Discussionmentioning

confidence: 99%

Cathodic Voltage-controlled Electrical Stimulation Plus Prolonged Vancomycin Reduce Bacterial Burden of a Titanium Implant-associated Infection in a Rodent Model

Nodzo

Tobias

Ahn

et al. 2016

Clinical Orthopaedics &Amp; Related Research

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Background Cathodic voltage-controlled electrical stimulation (CVCES) of titanium implants, either alone or combined with a short course of vancomycin, has previously been shown to reduce the bone and implant bacterial burden in a rodent model of methicillin-resistant Staphylococcus aureus (MRSA) implant-associated infection (IAI). Clinically, the goal is to achieve complete eradication of the IAI; therefore, the rationale for the present study was to evaluate the antimicrobial effects of combining CVCES with prolonged antibiotic therapy with the goal of decreasing the colony-forming units (CFUs) to undetectable levels.Questions/purposes (1) In an animal MRSA IAI model, does combining CVCES with prolonged vancomycin therapy decrease bacteria burden on the implant and surrounding bone to undetectable levels? (2) When used with prolonged vancomycin therapy, are two CVCES treatments more effective than one? (3) What are the longer term histologic effects (inflammation and granulation tissue) of CVCES on the surrounding tissue? Methods Twenty adult male Long-Evans rats with surgically placed shoulder titanium implants were infected with a clinical strain of MRSA (NRS70). One week after infection, the rats were randomly divided into four groups of five: (1) VANCO: only vancomycin treatment (150 mg/ kg, subcutaneous, twice daily for 5 weeks); (2) VANCO + 1STIM: vancomycin treatment (same as the VANCO group) coupled with one CVCES treatment (À1.8 V for 1 hour on postoperative day [POD] 7); (3) VANCO + 2STIM: vancomycin treatment (same as the VANCO group) coupled with two CVCES treatments (À1.8 V for 1 hour on POD 7 and POD 21); or (4) CONT: no treatment. On POD 42, the implant, bone, and peripheral blood were collected for CFU enumeration and histological analysis, where we compared CFU/mL on the implants and bone among the groups. A pathologist, blinded to the experimental conditions, performed a semiquantitative analysis Clinical Orthopaedics and Related Research ®A Publication of The Association of Bone and Joint Surgeons® of inflammation and granulation tissue present in serial sections of the humeral head for animals in each experimental group. Results The VANCO + 1STIM decreased the implant bacterial burden (median = 0, range = 0-10 CFU/mL) when compared with CONT (median = 5.7 9 10 4 , range = 4.0 9 10 3 À8.0 9 10 5 CFU/mL; difference of medians = À5.6 9 10 4 ; p \ 0.001) and VANCO (median = 4.9 9 10 3 , range = 9.0 9 10 2 À2.1 9 10 4 CFU/mL; difference of medians = À4.9 9 10 3 ; p \ 0.001). The VANCO + 1STIM decreased the bone bacterial burden (median = 0, range = 0-0 CFU/mL) when compared with CONT (median = 1.3 9 10 2 , range = 0-9.4 9 10 2 CFU/ mL; difference of medians = À1.3 9 10 2 ; p \ 0.001) but was not different from VANCO (median = 0, range = 0-1.3 9 10 2 CFU/mL; difference of medians = 0; p = 0.210). The VANCO + 2STIM group had implant CFU (median = 0, range = 0-8.0 9 10 1 CFU/mL) and bone CFU (median = 0, range = 0-2.0 9 10 1 CFU/mL) that were not different from the VANCO + 1STIM treatment ...

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Capacitive Coupling Reduces Instrumentation-related Infection in Rabbit Spines: A Pilot Study

Cited by 9 publications

References 26 publications

Bacterial biofilm formation on implantable devices and approaches to its treatment and prevention

Bacterial biofilm formation on implantable devices and approaches to its treatment and prevention

Electrical stimulation disrupts biofilms in a human wound model and reveals the potential for monitoring treatment response with volatile biomarkers

Cathodic Voltage-controlled Electrical Stimulation Plus Prolonged Vancomycin Reduce Bacterial Burden of a Titanium Implant-associated Infection in a Rodent Model

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