Keratoprostheses for corneal blindness: a review of contemporary devices

According to the World Health Organization, globally 4.9 million are blind due to corneal pathology. Corneal transplantation is successful and curative of the blindness for a majority of these cases. However, it is less successful in a number of diseases that produce corneal neovascularization, dry ocular surface and recurrent inflammation, or infections. A keratoprosthesis or KPro is the only alternative to restore vision when corneal graft is a doomed failure. Although a number of KPros have been proposed, only two devices, Boston type-1 KPro and osteo-odonto-KPro, have came to the fore. The former is totally synthetic and the latter is semi-biological in constitution. These two KPros have different surgical techniques and indications. Keratoprosthetic surgery is complex and should only be undertaken in specialized centers, where expertise, multidisciplinary teams, and resources are available. In this article, we briefly discuss some of the prominent historical KPros and contemporary devices

Proceedings of the Second Airborne Imaging Spectrometer Data Analysis Workshop

Topics addressed include: calibration, the atmosphere, data problems and techniques, geological research, and botanical and geobotanical research

A dark field illumination probe linked to Raman spectroscopy for non-invasivety determination of ocular biomarkers

For early and effective diagnosis of eye diseases, acquiring biochemical information in the eye is preferred. However, it is obtained by performing a biopsy of the eye tissue. This poses a risk to the integrity of the eye and cannot be performed on a regular basis. Raman spectrometry is a potential and powerful tool for the non-invasive investigation of biochemical information. The challenge to use it in an ophthalmic application is the essential of a high-power laser direct shining through the eye, which raises safety concerns for potential retinal damage .In this thesis, biomedical applications of Raman spectroscopy are explored for eye disease biomarkers and ocular drug measurements in ex vitro, in vitro and in vivo. To ensure a safety measurement by projecting a laser in the eye, two types of dark-field illumination probes are designed, manufactured and validated in conjunction with confocal Raman spectroscopy (CRS) to avoid light damage of the retina. Furthermore, a non-contact dark-field illumination method for the same purpose is proposed and theoretically validated

Quantitative Chemically-Specific Coherent Diffractive Imaging of Buried Interfaces using a Tabletop EUV Nanoscope

Characterizing buried layers and interfaces is critical for a host of applications in nanoscience and nano-manufacturing. Here we demonstrate non-invasive, non-destructive imaging of buried interfaces using a tabletop, extreme ultraviolet (EUV), coherent diffractive imaging (CDI) nanoscope. Copper nanostructures inlaid in SiO2 are coated with 100 nm of aluminum, which is opaque to visible light and thick enough that neither optical microscopy nor atomic force microscopy can image the buried interfaces. Short wavelength (29 nm) high harmonic light can penetrate the aluminum layer, yielding high-contrast images of the buried structures. Moreover, differences in the absolute reflectivity of the interfaces before and after coating reveal the formation of interstitial diffusion and oxidation layers at the Al-Cu and Al-SiO2 boundaries. Finally, we show that EUV CDI provides a unique capability for quantitative, chemically-specific imaging of buried structures, and the material evolution that occurs at these buried interfaces, compared with all other approaches.Comment: 12 pages, 8 figure

Development of a fundus camera for analysis of photoreceptor directionality in the healthy retina

The Stiles-Crawford effect (SCE) is the well-known phenomenon in which the brightness of light perceived by the human eye depends upon its entrance point in the pupil. This physiological characteristic is due to the directional sensitivity of the cone photoreceptors in the retina and it displays an approximately Gaussian dependency which is altered in a number of pathologies. Retinal imaging, a widely spread clinical practice, may be used to evaluate the SCE and thus serve as diagnostic tool. Nonetheless, its use for such a purpose is still underdeveloped and far from the clinical reality. In this project a fundus camera was built and used to assess the cone photoreceptor directionality by reflective imaging of the retina in healthy individuals. The physical and physiological implications of its development are addressed in detail in the text: the optical properties of the human eye, illumination issues, acquiring a retinal image formed by the eye, among others. A full description of the developmental process that led to the final measuring method and results is also given. The developed setup was successfully used to obtain high quality images of the eye fundus and in particular the parafoveal cone photoreceptors. The SCE was successfully observed and characterized. Even though considerable improvements could be done to the measurement method, the project showed the feasibility of using retinal imaging to evaluate the SCE thus motivating its usage in a clinical environment

Single Molecule Detection of Near-Infrared Phthalocyanine Dyes

The major advantage associated with near-infrared monitoring is the fact that few compounds show intrinsic fluorescence in this region of the spectrum and hence background from other molecules is reduced. Phthalocyanine dyes provide emission at deep red and near infrared wavelengths but have excellent photostability and hence are an attractive candidate for near-infrared fluorescence bioassay applications. However, because of their small Stokes shifts, non-standard methods are needed for optimum separation of fluorescence from scattered laser light. This thesis reports the development of a custom confocal microscope that uses a lowcost laser diode operating at 667 nm for sample excitation and an angle-tuned Raman notch filter to block scattered laser radiation and provide high-throughput of fluorescence with small Stokes shift. Also, a diffraction grating is used to isolate the laser excitation wavelength from the broadband luminescence of the laser. The experimental system is used to observe photon bursts from single molecules of zinc phthalocyanine fluorophores in an ethanol solution. The autocorrelation function of the photon trace, which is measured in fluorescence correlation spectroscopy, provides a measure of the presence of photon bursts from single molecules. Experiments to characterize the limits of detection of near-infrared fluorophores in aqueous solution using the microscope are also discussed

Population Study of the Variation in Monochromatic Aberrations of the Normal Human Eye Over the Central Visual Field

Abstract We present data analysis for ocular aberrations of 60 normal eyes measured with a Hartmann-Shack (HS) wavefront sensor (WFS). Aberration measurements were made on-axis and at 5 degree field angles in the nasal, inferior, temporal and superior semi-meridians. Particular attention is given to aberration distributions and possible strategies for aberration correction are discussed. A versatile HS WFS was designed and constructed with features of simultaneous pupil centre determination, off-axis capability, real-time data displays, and efficient lenslet sampling orientation. The subject alignment is achieved by the use of a parallel channel that is recombined with the sensing channel to simultaneously image the eye and the HS spots onto a single CCD. The pupil centre is determined using this image of the eye (iris edge), rather than the HS spots. The optical design includes a square lenslet array positioned with its diagonals aligned with the most typical principal astigmatic meridians of the eye. This favourable orientation helps to enlarge the dynamic range of the WFS. The telecentric re-imaging of the HS spots increases the robustness of the system to defocus in the event of CCD misalignment