2014
DOI: 10.1039/c4lc00471j
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Rapid isolation and diagnosis of live bacteria from human joint fluids by using an integrated microfluidic system

Abstract: Arthroplasty is a general approach for improving the life quality for patients with degenerative or injured joints. However, post-surgery complications including periprosthetic joint infection (PJI) poses a serious drawback to the procedure. Several methods are available for diagnosing PJI, but they are time-consuming or have poor sensitivity and specificity. Alternatively, reverse-transcription PCR can detect live bacteria and reduce false-positive results but cannot avoid the cumbersome RNA handling and huma… Show more

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Cited by 26 publications
(25 citation statements)
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“…Then, the sample was first treated with 1 ll of 1 mg/ml EMA (Molecular Probes V R , USA) in the reaction chamber and exposed under visible light (18 W, 1200 lm) for 5 min (Figure 1(a)). According to our previous study (Chang et al (2014)), EMA can distinguish live bacteria from dead ones after 5-min of light exposure. EMA can be employed to distinguish between live and dead bacteria as it can penetrate into the broken cell walls of dead bacteria and intercalate into DNA irreversibly (Chang et al (2014);; and Liu et al (2012)).…”
Section: A Experimental Proceduresmentioning
confidence: 88%
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“…Then, the sample was first treated with 1 ll of 1 mg/ml EMA (Molecular Probes V R , USA) in the reaction chamber and exposed under visible light (18 W, 1200 lm) for 5 min (Figure 1(a)). According to our previous study (Chang et al (2014)), EMA can distinguish live bacteria from dead ones after 5-min of light exposure. EMA can be employed to distinguish between live and dead bacteria as it can penetrate into the broken cell walls of dead bacteria and intercalate into DNA irreversibly (Chang et al (2014);; and Liu et al (2012)).…”
Section: A Experimental Proceduresmentioning
confidence: 88%
“…According to our previous study (Chang et al (2014)), EMA can distinguish live bacteria from dead ones after 5-min of light exposure. EMA can be employed to distinguish between live and dead bacteria as it can penetrate into the broken cell walls of dead bacteria and intercalate into DNA irreversibly (Chang et al (2014);; and Liu et al (2012)). Then, reagents for low temperature chemical lysis (detail information for low temperature chemical lysis was described in Section II D) and 5 ll of 16S ribosomal ribonucleic acid (16S rRNA) nucleotide probecoated magnetic beads (7 Â 10 5 beads/ll) (Bergin et al (2010)) were added into the reaction chamber ( Figure 1(b)).…”
Section: A Experimental Proceduresmentioning
confidence: 88%
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“…Making use of mannose binding lectin (MBL) coated magnetic beads and subsequent magnetic flux concentrator, Cooper et al were able to spread captured Candida (C.) albicans fungi (99%) thinly to optimize optical imaging (Cooper et al, 2014). Wang et al argued that it is also important to differentiate live from dead bacteria to prevent unnecessary administration of antibiotics (Chang et al, 2014). The group thus designed a microfluidic system based on ethidium monoazide-based assay and PCR to probe for live bacteria from fluid isolated from periprosthetic joint infection.…”
Section: Sepsis Diagnosismentioning
confidence: 99%