Iyad S. Saidi scite author profile

Adherent bacterial biofilms have been implicated in the irreversible contamination of implanted medical devices. We evaluated the resistance of various tympanostomy (pressure equalization [PE]) tube materials to biofilm formation using an in vivo model. PE tubes of silicone, silver oxide-impregnated silicone, fluoroplastic, silver oxide-impregnated fluoroplastic, and ion-bombarded silicone were inserted into the tympanic membranes of 18 Hartley guinea pigs. Staphylococcus aureus was then inoculated into the middle ears. An additional 8 guinea pigs were used as controls; the PE tubes were inserted without middle ear inoculation. All PE tubes were removed on day 10 and analyzed for bacterial contamination using culture, immunofluorescence, and scanning electron microscopy (SEM). All infected ears developed otitis media with otorrhea, but none of the animal control ears drained. Fluorescence imaging of the animal control tubes showed large cellular components consistent with inflammation. The infected tubes showed heavy DNA fluorescence consistent with bacteria and inflammatory cells. All animal control tubes except the ion-bombarded silicone tubes showed adherent inflammatory film on SEM. Also, all tubes placed in infected ears except the ion-bombarded silicone tubes showed adherent bacterial and inflammatory films on SEM. Nonadherent surface properties such as the ion-bombarded silicone may be helpful in preventing chronic PE tube contamination.

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<title>Developing an optical fiber reflectance spectrometer to monitor bilirubinemia in neonates</title>

Jacques

Saidi

Ladner

et al. 1997

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XeCl laser ablation of atherosclerotic aorta: Optical properties and energy pathways

et al. 1992

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The energetics of 308-nm excimer laser irradiation of human aorta were studied. The heat generation that occurred during laser irradiation of atherosclerotic aorta equaled the absorbed laser energy minus the fraction of energy for escaping fluorescence (0.8-1.6%) and photochemical decomposition (2%). The absorbed laser energy is equal to the total delivered light energy minus the energy lost as specular reflectance (2.4%, air/tissue) and diffuse reflectance (11.5-15.5%). Overall, about 79-83.5% of the delivered light energy was converted to heat. We conclude that the mechanism of XeCl laser ablation of soft tissue involves thermal overheating of the irradiated volume with subsequent explosive vaporization. The optical properties of normal wall of human aorta and fibrous plaque, both native and denatured were determined. The light scattering was significant and sufficient to cause a subsurface fluence (J/cm2) in native aorta that equaled 1.8 times the broad-beam radiant exposure, phi o (2.7 phi o for denatured aorta). An optical fiber must have a diameter of at least 800 microns to achieve a maximum light penetration (approximately 200 microns for phi o/e) in the aorta along the central axis of the beam.

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Iyad S. Saidi

Mie and Rayleigh modeling of visible-light scattering in neonatal skin

In Vivo Resistance to Bacterial Biofilm Formation on Tympanostomy Tubes as a Function of Tube Material

<title>Developing an optical fiber reflectance spectrometer to monitor bilirubinemia in neonates</title>

XeCl laser ablation of atherosclerotic aorta: Optical properties and energy pathways

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