Your search keyword '"Howlin, Robert P."' showing total 3 results

1. Fluid-driven interfacial instabilities and turbulence in bacterial biofilms.

Author

Fabbri, Stefania, Li, Jian, Howlin, Robert P., Rmaile, Amir, Gottenbos, Bart, De Jager, Marko, Starke, E. Michelle, Aspiras, Marcelo, Ward, Marilyn T., Cogan, Nicholas G., and Stoodley, Paul

Subjects

BIOFILMS, HYDRODYNAMICS, METABOLITES, TURBULENCE, FOULING

Abstract

Biofilms are thin layers of bacteria embedded within a slime matrix that live on surfaces. They are ubiquitous in nature and responsible for many medical and dental infections, industrial fouling and are also evident in ancient fossils. A biofilm structure is shaped by growth, detachment and response to mechanical forces acting on them. The main contribution to biofilm versatility in response to physical forces is the matrix that provides a platform for the bacteria to grow. The interaction between biofilm structure and hydrodynamics remains a fundamental question concerning biofilm dynamics. Here, we document the appearance of ripples and wrinkles in biofilms grown from three species of bacteria when subjected to high-velocity fluid flows. Linear stability analysis suggested that the ripples were Kelvin-Helmholtz Instabilities. The analysis also predicted a strong dependence of the instability formation on biofilm viscosity explaining the different surface corrugations observed. Turbulence through Kelvin-Helmholtz instabilities occurring at the interface demonstrated that the biofilm flows like a viscous liquid under high flow velocities applied within milliseconds. Biofilm fluid-like behavior may have important implications for our understanding of how fluid flow influences biofilm biology since turbulence will likely disrupt metabolite and signal gradients as well as community stratification. [ABSTRACT FROM AUTHOR]

Published

2017

2. Comparing PMMA and calcium sulfate as carriers for the local delivery of antibiotics to infected surgical sites.

Author

McConoughey, Stephen J., Howlin, Robert P., Wiseman, Jessica, Stoodley, Paul, and Calhoun, Jason H.

Abstract

Antibiotic-loaded bone cement is a primary option for treatment of orthopedic infections. Poly(methyl methacrylate) (PMMA) is a widely used cement that, when loaded with antibiotics in spacer or bead form, has been shown to reduce infection rates. However, PMMA is not resorbable and requires a second surgery for removal, while also acting as a potential foreign body for bacterial colonization. Alternatively, resorbable bone cements, such as calcium sulfate, have been proposed and present the advantage of being completely reabsorbed. It is unknown whether the antibiotic elution characteristics of absorbable bone cements are similar to PMMA. This study (1) characterized antibiotic elution from synthetic, highly purified calcium sulfate cement beads of varying sizes against pathogenic bacteria both in liquid culture and seeded on agar plates, (2) tested calcium sulfate beads against PMMA beads loaded with the same antibiotics, and (3) analyzed the structural differences between how PMMA and calcium sulfate bind to antibiotics. In every assay, the calcium sulfate beads performed as well as, or better than, the PMMA beads in inhibition of bacterial growth and elution of vancomycin in vitro with complete elution observed from calcium sulfate within three days. These data suggest that calcium sulfate, functions, as well as PMMA in the patient setting for infection control. © 2014 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 103B: 870-877, 2015. [ABSTRACT FROM AUTHOR]

Published

2015

3. Cephalosporin-3′-diazeniumdiolates: Targeted NO-Donor Prodrugs for Dispersing Bacterial Biofilms.

Author

Barraud, Nicolas, Kardak, Bharat G., Yepuri, Nageshwar R., Howlin, Robert P., Webb, Jeremy S., Faust, Saul N., Kjelleberg, Staffan, Rice, Scott A., and Kelso, Michael J.

Published

2012