Steven L. Goodman scite author profile

Multidrug-resistant bacterial infections are an ever-growing threat because of the shrinking arsenal of efficacious antibiotics. Metal nanoparticles can induce cell death, yet the toxicity effect is typically nonspecific. Here, we show that photoexcited quantum dots (QDs) can kill a wide range of multidrug-resistant bacterial clinical isolates, including methicillin-resistant Staphylococcus aureus, carbapenem-resistant Escherichia coli, and extended-spectrum β-lactamase-producing Klebsiella pneumoniae and Salmonella typhimurium. The killing effect is independent of material and controlled by the redox potentials of the photogenerated charge carriers, which selectively alter the cellular redox state. We also show that the QDs can be tailored to kill 92% of bacterial cells in a monoculture, and in a co-culture of E. coli and HEK 293T cells, while leaving the mammalian cells intact, or to increase bacterial proliferation. Photoexcited QDs could be used in the study of the effect of redox states on living systems, and lead to clinical phototherapy for the treatment of infections.

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Nanoscale topography of the basement membrane underlying the corneal epithelium of the rhesus macaque

Abrams¹,

Goodman²,

Nealey³

et al. 2000

Cell and Tissue Research

321

182

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This paper quantitatively defines the nanoscale topography of the basement membrane underlying the anterior corneal epithelium of the macaque. Excised corneal buttons from macaques were placed in 2.5 mM ethylenediaminetetraacetate (EDTA) for 2.5 h, after which the epithelium was carefully removed to expose the underlying basement membrane. The integrity of the remaining basement membrane was verified using fluorescent microscopy in conjunction with antibody staining directed against laminin and collagen type IV as well as transmission electron microscopy. Characterization of the surface of the basement membrane was performed using transmission electron microscopy, high-resolution, low-voltage scanning electron microscopy, and atomic force microscopy. Quantitative data were obtained with all three imaging techniques and compared. The basement membrane has a complex topography consisting of tightly cross-linked fibers intermingled with pores. The mean elevation of features measured by transmission electron microscopy, scanning electron microscopy, and atomic force microscopy was 149 +/- 60 nm, 191 +/- 72 nm, and 147 +/- 73 nm, respectively. Mean fiber diameter as measured by SEM was 77 +/- 44 nm and pore diameter was 72 +/- 40 nm, with pores occupying approximately 15% of the total surface area. Similar feature types and dimensions were also found for Matrigel, a commercially available basement membrane-like complex, supporting that a minimum of artifact was introduced by corneal preparative procedures to remove the overlying epithelium. Topographic features amplified the surface area over which cell-substratum interactions occur by an estimated 400%. The three-dimensional structure of the basement membrane exhibits a rich complex topography of individual features, consisting of pores and fibers with dimensions ranging from 30 to 400 nm. These nanoscale substratum features may modulate fundamental cell behaviors such as adhesion, migration, proliferation, and differentiation.

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Submicron Multiphoton Free-Form Fabrication of Proteins and Polymers: Studies of Reaction Efficiencies and Applications in Sustained Release

et al. 2000

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Nonlinear multiphoton photo-cross-linking and photopolymerization of proteins and polymers in solution have been used to direct the three-dimensional assembly of micron scale objects. Two aspects of fabricated proteinatious matrixes are examined in this paper: the efficiency of protein photopolymerization and the application of fabricated matrixes as sustained release devices. The efficiency of photoactivated cross-linking of the proteins bovine serum albumin and fibrinogen, using rose bengal, have been determined and found to vary with photosensitizer concentration. This concentration dependence suggests that the mechanism for protein cross-linking is a direct hydrogen transfer between an amino acid residue of the protein and the dye molecule itself. A comparison of the surface structure of single and multiple protein oligomers is undertaken and shown to vary significantly depending on fabrication materials. Alkaline phosphatase bioactivity, upon entrapment in a protein structure, is maintained. The properties of fabricated protein matrixes as sustained release devices is also examined. The rates of diffusion of fluorescently labeled dextrans (10 and 40 kDa) from an optically fabricated BSA matrix vary with molecular weight and are linear with cross-link density. The half-life of release of 10 kDa dextran-TMR from a BSA micron scale structure is less than or equal to 6 min while 40 kDa dextran-TMR halflife of release is 25 min. Finally, rhodamine 610, a typical drug size molecule, was entrapped in an acrylamide structure, and its release is found to be diffusion-limited with half-lives of 10-31 min, depending on cross-link density.

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Nanoscale Topography of the Corneal Epithelial Basement Membrane and Descemet's Membrane of the Human

Abrams

Schaus

Goodman

et al. 2000

Cornea

178

148

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With the use of the TEM, SEM, and AFM, a detailed description of the surface topography of corneal epithelial basement membrane and Descemet's membrane of the human cornea are provided. The significance of differences in corneal basement membrane topography may reflect differences in function of the overlying cells or may be related to differences in cell migration and turnover patterns between the epithelium and endothelium.

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Steven L. Goodman

Effects of synthetic micro- and nano-structured surfaces on cell behavior

Photoexcited quantum dots for killing multidrug-resistant bacteria

Nanoscale topography of the basement membrane underlying the corneal epithelium of the rhesus macaque

Submicron Multiphoton Free-Form Fabrication of Proteins and Polymers: Studies of Reaction Efficiencies and Applications in Sustained Release

Nanoscale Topography of the Corneal Epithelial Basement Membrane and Descemet's Membrane of the Human

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