Pogogyne Floribunda (Lamiaceae), A New Species from the Great Basin in Northeastern California

Pogogyne jloribunda is described as a new endemic species from Lassen and Modoc counties in northeastern California. Its occurrence on the eastern Modoc Plateau of the Great Basin Floristic Province is the first record for the genus outside the California Floristic Province. Pogogyne zizyphoroides also is reported from the Great Basin in Lassen County

Next generation transduction pathways for nano-bio-chip array platforms

textIn the following work, nanoparticle quantum dot (QD) fluorophores have been exploited to measure biologically relevant analytes via a miniaturized sensor ensemble to provide key diagnostic and prognostic information in a rapid, yet sensitive manner—data essential for effective treatment of many diseases including HIV/AIDS and cancer. At the heart of this “nano-bio-chip” (NBC) sensor is a modular chemical/cellular processing unit consisting of either a polycarbonate membrane filter for cell-based assays, or an agarose bead array for detection of biomarkers in serum or saliva. Two applications of the NBC sensor system are described herein, both exhibiting excellent correlation to reference methods ((R² above 0.94), with analysis times under 30 minutes and sample volumes below 50 [mu]L. First, the NBC sensor was employed for the sequestration and enumeration of T lymphocytes, cells specifically targeted by HIV, from whole blood samples. Several different conjugation methods linking QDs to recognition biomolecules were extensively characterized by biological and optical methods, with a thiol-linked secondary antibody labeling scheme yielding intense, specific signal. Using this technique, the photostability of QDs was exploited, as was the ability to simultaneously visualize different color QDs via a single light pathway, effectively reducing optical requirements by half. Further, T-cell counts were observed well below the 200/[mu]L discriminator between HIV and AIDS and across the common testing region, demonstrating the first reported example of cell counting via QDs in an enclosed, disposable device. Next, multiplexed bead-based detection of cancer protein biomarkers CEA, Her-2/Neu, and CA125 in serum and saliva was examined using a sandwich immunoassay with detecting antibodies covalently bound to QDs. This nano-based signal was amplified 30 times versus molecular fluorophores and cross talk in multiplexed experiments was less than 5%. In addition, molecular-level tuning of recognition elements (size, concentration) and agarose porosity resulted in NBC limits of detection two orders of magnitude lower than ELISA, values competitive with the most sensitive methods yet reported (0.021 ng/mL CEA). Taken together, these efforts serve to establish the valuable role of QDs in miniaturized diagnostic devices with potential for delivering biomedical information rapidly, reliably, and robustly.Chemistry and Biochemistr

Cellulose Nanoparticles are a Biodegradable Photoacoustic Contrast Agent for Use in Living Mice.

Molecular imaging with photoacoustic ultrasound is an emerging field that combines the spatial and temporal resolution of ultrasound with the contrast of optical imaging. However, there are few imaging agents that offer both high signal intensity and biodegradation into small molecules. Here we describe a cellulose-based nanoparticle with peak photoacoustic signal at 700 nm and an in vitro limit of detection of 6 pM (0.02 mg/mL). Doses down to 0.35 nM (1.2 mg/mL) were used to image mouse models of ovarian cancer. Most importantly, the nanoparticles were shown to biodegrade in the presence of cellulase both through a glucose assay and electron microscopy

Molecular imaging of oxidative stress using an LED-based photoacoustic imaging system.

LED-based photoacoustic imaging has practical value in that it is affordable and rugged; however, this technology has largely been confined to anatomic imaging with limited applications into functional or molecular imaging. Here, we report molecular imaging reactive oxygen and nitrogen species (RONS) with a near-infrared (NIR) absorbing small molecule (CyBA) and LED-based photoacoustic imaging equipment. CyBA produces increasing photoacoustic signal in response to peroxynitrite (ONOO-) and hydrogen peroxide (H2O2) with photoacoustic signal increases of 3.54 and 4.23-fold at 50 µM of RONS at 700 nm, respectively. CyBA is insensitive to OCl-, ˙NO, NO2-, NO3-, tBuOOH, O2-, C4H9O˙, HNO, and ˙OH, but can detect ONOO- in whole blood and plasma. CyBA was then used to detect endogenous RONS in macrophage RAW 246.7 cells as well as a rodent model; these results were confirmed with fluorescence microscopy. Importantly, CyB suffers photobleaching under a Nd:YAG laser but the signal decrease is <2% with the low-power LED-based photoacoustic system and the same radiant exposure time. To the best of our knowledge, this is the first report to describe molecular imaging with an LED-based photoacoustic scanner. This study not only reveals the sensitive photoacoustic detection of RONS but also highlights the utility of LED-based photoacoustic imaging

Photoacoustic Imaging for Noninvasive Periodontal Probing Depth Measurements.

The periodontal probe is the gold standard tool for periodontal examinations, including probing depth measurements, but is limited by systematic and random errors. Here, we used photoacoustic ultrasound for high-spatial resolution imaging of probing depths. Specific contrast from dental pockets was achieved with food-grade cuttlefish ink as a contrast medium. Here, 39 porcine teeth (12 teeth with artificially deeper pockets) were treated with the contrast agent, and the probing depths were measured with novel photoacoustic imaging and a Williams periodontal probe. There were statistically significant differences between the 2 measurement approaches for distal, lingual, and buccal sites but not mesial. Bland-Altman analysis revealed that all bias values were < ±0.25 mm, and the coefficients of variation for 5 replicates were <11%. The photoacoustic imaging approach also offered 0.01-mm precision and could cover the entire pocket, as opposed to the probe-based approach, which is limited to only a few sites. This report is the first to use photoacoustic imaging for probing depth measurements with potential implications to the dental field, including tools for automated dental examinations or noninvasive examinations

Knife- Versus Abrasive-Planed Wood: Quality of Adhesive Bonds

Glueline strength and durability were determined for abrasive- versus knife-planed wood surfaces. Laminated beam sections were made, 16 each of southern pine and Douglas-fir, using 4 surfacing treatments prior to laminating. The four treatments were knife planing, and abrasive planing with 36, 60, and 80 grit. Comparisons were made of resistance to glueline separation after accelerated aging, of bond shear strength, and of percentage wood failure within a species group.Under microscopic examination, abrasive planing showed crushing and tearing of the wood surface, whereas knife planing showed a clean-cut surface. Gluelines with abrasive-planed surfaces were similar to the knife-planed in shear strength, were higher in percentage of wood failure, and lower in resistance to glueline separation upon accelerated aging

Graduate Assistants in Areas of National Nedd (GAANN) fellowship program at Georgia Tech, 1992-1995

Issued as Final report, Project no. E-21-569Final report has author: Mary Ann Ingra