Determining the efficacy of camera traps, live capture traps, and detection dogs for locating cryptic small mammal species.

Metal box (e.g., Elliott, Sherman) traps and remote cameras are two of the most commonly employed methods presently used to survey terrestrial mammals. However, their relative efficacy at accurately detecting cryptic small mammals has not been adequately assessed. The present study therefore compared the effectiveness of metal box (Elliott) traps and vertically oriented, close range, white flash camera traps in detecting small mammals occurring in the Scenic Rim of eastern Australia. We also conducted a preliminary survey to determine effectiveness of a conservation detection dog (CDD) for identifying presence of a threatened carnivorous marsupial, Antechinus arktos, in present-day and historical locations, using camera traps to corroborate detections. 200 Elliott traps and 20 white flash camera traps were set for four deployments per method, across a site where the target small mammals, including A. arktos, are known to occur. Camera traps produced higher detection probabilities than Elliott traps for all four species. Thus, vertically mounted white flash cameras were preferable for detecting the presence of cryptic small mammals in our survey. The CDD, which had been trained to detect A. arktos scat, indicated in total 31 times when deployed in the field survey area, with subsequent camera trap deployments specifically corroborating A. arktos presence at 100% (3) indication locations. Importantly, the dog indicated twice within Border Ranges National Park, where historical (1980s-1990s) specimen-based records indicate the species was present, but extensive Elliott and camera trapping over the last 5-10 years have resulted in zero A. arktos captures. Camera traps subsequently corroborated A. arktos presence at these sites. This demonstrates that detection dogs can be a highly effective means of locating threatened, cryptic species, especially when traditional methods are unable to detect low-density mammal populations.

Raman Spectroscopic Analysis of Fingernail Clippings Can Help Differentiate Between Postmenopausal Women Who Have and Have Not Suffered a Fracture.

Raman spectroscopy was applied to nail clippings from 633 postmenopausal British and Irish women, from six clinical sites, of whom 42% had experienced a fragility fracture. The objective was to build a prediction algorithm for fracture using data from four sites (known as the calibration set) and test its performance using data from the other two sites (known as the validation set). Results from the validation set showed that a novel algorithm, combining spectroscopy data with clinical data, provided area under the curve (AUC) of 74% compared to an AUC of 60% from a reduced QFracture score (a clinically accepted risk calculator) and 61% from the dual-energy X-ray absorptiometry T-score, which is in current use for the diagnosis of osteoporosis. Raman spectroscopy should be investigated further as a noninvasive tool for the early detection of enhanced risk of fragility fracture.

Profiling retinal biochemistry in the MPDZ mutant retinal dysplasia and degeneration chick: a model of human RP and LCA.

PURPOSE: Raman microscopy, a rapid nondestructive technique that profiles the composition of biological samples, was used to characterize retinal biochemistry in the retinal dysplasia and degeneration (rdd) and wild-type (wt) chick retina during retinogenesis and at hatching. METHODS: Embryonic day (E)13 and posthatch day (P)1 rdd and wt retinal cross-sections (n = 3 of each line at each age) were profiled using 633 helium-neon laser excitation. The biochemical composition was determined using computational analysis of the Raman spectra. In parallel histology, TUNEL and glial fibrillary acidic protein (GFAP) immunostaining were used to visualize retinal dysfunction. RESULTS: Principal component (PC) analysis of the Raman spectra identified 50 major biochemical profiles, but only PCs that made significant contributions to variation within rdd and wt retina were mapped. These significant PCs were shown to arise from DNA, various fatty acids, melanin, and a number of proteins. Distinct patterns of GFAP immunostaining and a larger population of TUNEL-positive nuclei were observed in the rdd versus wt retina. CONCLUSIONS: This study has demonstrated that Raman microscopy can discriminate between major retinal biomolecules, thus providing an unbiased account of how their composition varies due to the impact of the MPDZ null mutation in the rdd chick relative to expression in the normal wt retina.

Advanced glycation as a basis for understanding retinal aging and noninvasive risk prediction.

The retina is exquisitely sensitive to age-related processes, and, in many cases, these can precipitate progressive and profound loss of vision. Many asymptomatic abnormalities that accrue in the outer retina as we get older can serve as a sinister preamble to age-related macular degeneration (AMD). This condition remains the leading cause of irreversible blindness in industrialized countries, but its precise pathogenesis has yet to be completely elucidated. Over recent years, increasing evidence has suggested that the accumulation of advanced glycation end products (AGEs) and activation of the receptor for AGEs in the outer retina could play a significant role in the initiation and progression of AMD. The current review outlines this evidence and indicates how products of Maillard chemistry could be used as robust markers for outer retinal aging and susceptibility to AMD. The utility of Raman spectroscopy to measure AGE adducts in human tissues is presented. The methodology reinforces the association between AGE formation and retinal aging and provides exciting possibilities for assessing these pathogenic agents in the living eye and, perhaps, for providing a valuable index for AMD susceptibility.