Rapid and highly sensitive detection of pyocyanin biomarker in different Pseudomonas aeruginosa infections using gold nanoparticles modified sensor

Elkhawaga, Amal A.; Khalifa, Marwa M.; El‐Badawy, Omnia; Hassan, Mona A.; El‐Said, Waleed A.

doi:10.1371/journal.pone.0216438

Cited by 41 publications

(21 citation statements)

References 48 publications

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“…However, those methods are time-consuming as they require the target molecules/proteins to be purified from bacterial cultures. Recently, nanoparticles have been developed to allow rapid identification of pyocyanin [ 131 ] and LasA protease [ 132 ] with high sensitivity even in the presence of other species within cell cultures. Gold nanoparticles (Au NPs) deposited onto indium tin oxide electrodes was able to enhance the detection of pyocyanin at a concentration as low as 40 µM as compared to the minimum 80 µM of pyocyanin detected using unmodified electrodes [ 131 ].…”

Section: Diagnosticsmentioning

confidence: 99%

“…Recently, nanoparticles have been developed to allow rapid identification of pyocyanin [ 131 ] and LasA protease [ 132 ] with high sensitivity even in the presence of other species within cell cultures. Gold nanoparticles (Au NPs) deposited onto indium tin oxide electrodes was able to enhance the detection of pyocyanin at a concentration as low as 40 µM as compared to the minimum 80 µM of pyocyanin detected using unmodified electrodes [ 131 ]. Encapsulating the Au NPs with a thin layer of polyaniline hydrochloride (PANI) forming PANI/Au core-shell NPs increased the sensitivity of the PANI/Au NPs-modified electrodes towards pyocyanin down to 36 µM, which could accelerate the diagnostic process, achieving effective treatments and prevention of chronic infections [ 131 ].…”

Section: Diagnosticsmentioning

confidence: 99%

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Pseudomonas aeruginosa Biofilms

Thi

Wibowo

Rehm

2020

IJMS

375

317

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Pseudomonas aeruginosa is an opportunistic human pathogen causing devastating acute and chronic infections in individuals with compromised immune systems. Its highly notorious persistence in clinical settings is attributed to its ability to form antibiotic-resistant biofilms. Biofilm is an architecture built mostly by autogenic extracellular polymeric substances which function as a scaffold to encase the bacteria together on surfaces, and to protect them from environmental stresses, impedes phagocytosis and thereby conferring the capacity for colonization and long-term persistence. Here we review the current knowledge on P. aeruginosa biofilms, its development stages, and molecular mechanisms of invasion and persistence conferred by biofilms. Explosive cell lysis within bacterial biofilm to produce essential communal materials, and interspecies biofilms of P. aeruginosa and commensal Streptococcus which impedes P. aeruginosa virulence and possibly improves disease conditions will also be discussed. Recent research on diagnostics of P. aeruginosa infections will be investigated. Finally, therapeutic strategies for the treatment of P. aeruginosa biofilms along with their advantages and limitations will be compiled.

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Section: Diagnosticsmentioning

confidence: 99%

Section: Diagnosticsmentioning

confidence: 99%

Pseudomonas aeruginosa Biofilms

Thi

Wibowo

Rehm

2020

IJMS

375

317

View full text Add to dashboard Cite

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“…Elkhawaga et al have prepared PANI/Au NPs/ITO electrode as PYO sensor in a culture of P. aeruginosa. The results indicated that PANI/Au NPs/ ITO electrode is more sensitive toward PYO biomarker than either bare ITO electrode or Au NPs/ITO electrode with LOD of 500 nM [42]. The enhancement of the electrochemical activity of PANI/Au NPs/ITO modified electrode towards the PYO related to the presence of positive charges on its surface that could enhance the mass transfer rate of the negatively charged PYO based on the electrostatic attraction force.…”

Section: Nscps For Different Biosensor Applicationsmentioning

confidence: 96%

Application of Conducting Polymer Nanostructures to Electrochemical Biosensors

et al. 2020

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Over the past few decades, nanostructured conducting polymers have received great attention in several application fields, including biosensors, microelectronics, polymer batteries, actuators, energy conversion, and biological applications due to their excellent conductivity, stability, and ease of preparation. In the bioengineering application field, the conducting polymers were reported as excellent matrixes for the functionalization of various biological molecules and thus enhanced their performances as biosensors. In addition, combinations of metals or metal oxides nanostructures with conducting polymers result in enhancing the stability and sensitivity as the biosensing platform. Therefore, several methods have been reported for developing homogeneous metal/metal oxide nanostructures thin layer on the conducting polymer surfaces. This review will introduce the fabrications of different conducting polymers nanostructures and their composites with different shapes. We will exhibit the different techniques that can be used to develop conducting polymers nanostructures and to investigate their chemical, physical and topographical effects. Among the various biosensors, we will focus on conducting polymer-integrated electrochemical biosensors for monitoring important biological targets such as DNA, proteins, peptides, and other biological biomarkers, in addition to their applications as cell-based chips. Furthermore, the fabrication and applications of the molecularly imprinted polymer-based biosensors will be addressed in this review.

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“…The commercially‐available Zensor TE100 SPE showed an excellent correlation between electrical signal loss and the viability of PA cells after antibiotic (colistin sulfate) exposure [ 73b,75 ] and to monitor the electrochemical response of PYO generated by bacteria in the presence of various amino acids ( Figure 8 A,B). [ 73b ] Maximal current peaks were reduced by ≈68% and 82% when exposed to colistin sulfate, a last‐resort treatment for cases of MDR PA infection.…”

Section: Electrochemical Detection Of Pamentioning

confidence: 99%

“…[ 73b ] Maximal current peaks were reduced by ≈68% and 82% when exposed to colistin sulfate, a last‐resort treatment for cases of MDR PA infection. [ 73b,75,76 ] Other EC studies for PYO‐tracing using SPEs as the primary tech include the commercially available SPE, Dropsens C223AT with a 1.6 mm Au WE, as well as Au CE and Ag RE. [ 64,74 ] Similarly to the Zenzor TE100, Dropsens C223AT SPEs are highly adaptable, having a low‐cost, high conductivity, and allow various electrochemical methods such as SWV, CV, DPV, thus being optimal for the electrochemical sensing of PYO.…”

Section: Electrochemical Detection Of Pamentioning

confidence: 99%

Emerging Technologies for the Electrochemical Detection of Bacteria

McEachern

Harvey

Merle

2020

Biotechnology Journal

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Infections are a huge economic liability to the health care system, although real‐time detection can allow early treatment protocols to avoid some of this cost and patient morbidity and mortality. Pseudomonas aeruginosa (PA) is a drug‐resistant gram‐negative bacterium found ubiquitously in clinical settings, accounting for up to 27% of hospital acquired infections. PA secretes a vast array of molecules, ranging from secondary metabolites to quorum sensing molecules, of which many can be exploited to monitor bacterial presence. In addition to electrochemical immunoassays to sense bacteria via antigen–antibody interactions, PA pertains a distinct redox‐active virulence factor called pyocyanin (PYO), allowing a direct electrochemical detection of the bacteria. There has been a surge of publications relating to the electrochemical tracing of PA via a myriad of novel biosensing techniques, materials, and methodologies. In addition to indirect methods, research approaches where PYO has been sensitively detected using surface modified electrodes are reviewed and compared with conventional PA‐sensing methodologies. This review aims at presenting indirect and direct electrochemical methods currently developed using various surface modified electrodes, materials, and electrochemical configurations on their electrocatalytic effects on sensing of PA and in particular PYO.

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Rapid and highly sensitive detection of pyocyanin biomarker in different Pseudomonas aeruginosa infections using gold nanoparticles modified sensor

Cited by 41 publications

References 48 publications

Pseudomonas aeruginosa Biofilms

Pseudomonas aeruginosa Biofilms

Application of Conducting Polymer Nanostructures to Electrochemical Biosensors

Emerging Technologies for the Electrochemical Detection of Bacteria

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