A protein dye-binding assay on cellulose membranes for tear protein quantification: Use of conventional Schirmer strips

PURPOSE: To develop a method to quantify tear protein concentration with the sensitivity to measure this variable in the restricted volumes of single human tear samples. METHODS: Aliquots of tear fluid from healthy subjects and a solution of standard bovine serum albumin (BSA) were spotted on cellulose membranes. Membranes were fixed, stained for protein with Coomassie blue, and washed until they displayed clear backgrounds. Stained spots were excised and eluted in a defined volume of methanol-ammonia, and the absorbance was determined spectrophotometrically at 610 nm. Membranes were calibrated by calculating their apparent thickness from the areas of stained spots and the corresponding aliquot volumes of either tear fluid or BSA solution. RESULTS: In our dye-binding assay, absorbance (0-1.00 OD) was found to have a linear relation with tear fluid volume (1-7 μL). In a study involving samples from 33 healthy subjects, aliquots (3 μL) of tear fluid were found to yield absorbances in th

Use of polyurethane minisponges to collect human tear fluid

Purpose: To characterize a method of tear collection based on the use of amphiphilic polyurethane absorbing minisponges. Methods: Tear fluid was collected from 17 healthy volunteers. A preweighed polyurethane dry minisponge was laid on the margin of the lower eyelid. Once wet (5-10 minutes), the fluid was transferred to a preweighed Eppendorf tube after squeezing the sponge by centrifugation. The amount of fluid absorbed and fluid recovered were determined by reweighing the sponge and the tube after absorption and centrifugation steps, respectively. The fluid was qualitatively characterized by electrophoretic polypeptide profiling in Coomassie blue-stained SDS-polyacrylamide gels. Results: Per eye, 14.6 ± 5.3 μL tear fluid was collected. That volume was about 90% of the fluid absorbed by polyurethane minisponges, almost doubling the fraction recovered from other more hydrophilic absorbing polymers. Major bands characterizing the electrophoretic profile of this fluid were those of 79,

Microdesiccates produced from normal human tears display four distinctive morphological components

Desiccation of human tears on glass surfaces results in fern-like crystalloids. This phenomenon has been associated with tear normality (Tear Ferning Test, TFT) and is used as a diagnostic aid to evaluate patients with Dry-Eye disease. However, TFT is focused on the assessment of only a minor fraction of desiccated tear samples and considers only the relative abundance and density of fern-like crystalloids. The aim of this study was to characterize morphologically entire desiccated micro volumes of tears from healthy donors. Tear samples were collected from 23 healthy young adult volunteers. Tear aliquots (1-3 μL) were allowed to dry on glass surfaces under ambient conditions of temperature (15-25°C) and relative humidity (40-45%). Dry samples were analyzed by dark-field microscopy. Morphometric data were acquired with Image J software. Tear volume was positively correlated with both area and time of desiccation. Morphological features of multiple microdesiccates produced from a single subject displayed striking similarities whereas tear microdesiccates from different healthy subjects displayed consistent differences but shared a common general design. This design may be mostly represented by the occurrence of four distinctive zones, named as zones I, II, III and Transition band. The main features of these zones are described

Progress in tear microdesiccate analysis by combining various transmitted-light microscope techniques

BACKGROUND: Tear desiccation on a glass surface followed by transmitted-light microscopy has served as diagnostic test for dry eye. Four distinctive morphological domains (zones I, II, III and transition band) have been recently recognized in tear microdesiccates. Physicochemical dissimilarities among those domains hamper comprehensive microscopic examination of tear microdesiccates. Optimal observation conditions of entire tear microdesiccates are now investigated. One-μ! aliquots of tear collected from individual healthy eyes were dried at ambient conditions on microscope slides. Tear microdesiccates were examined by combining low-magnification objective lenses with transmitted-light microscopy (brightfield, phase contrasts Ph1,2,3 and darkfield. RESULTS: Fern-like structures (zones II and III) were visible with all illumination methods excepting brightfield. Zone I was the microdesiccate domain displaying the most noticeable illumination-dependent variations, namely transparent band delimited by an outer rim (Ph1, Ph2), homogeneous compactly built structure (brightfield) or invisible domain (darkfield, Ph3). Intermediate positions of the condenser (BF/Ph1, Ph1/Ph2) showed a structured roughly cylindrical zone I. The transition band also varied from invisibility (brightfield) to a well-defined domain comprising interwoven filamentous elements (phase contrasts, darkfield. CONCLUSIONS: Imaging of entire tear microdesiccates by transmitted-light microscopy depends upon illumination. A more comprehensive description of tear microdesiccates can be achieved by combining illumination methods

Conjunctival impression cytology in patients with normal and impaired OSDI scores Citología de impresión conjuntival en pacientes con valores OSDI normales y alterados

© 2013 Sociedad Española de Oftalmología. Published by Elsevier España, S.L.U. All rights reserved. Purpose: To describe goblet cell density and Nelson grading in different areas of the ocu-lar surface using conjunctival impression cytology (CIC) among patients with normal andimpaired Ocular Surface Disease Index (OSDI) scores. Material and methods: Patients (n = 166) under assessment for dry eye were recruited between 2011 and 2012 and classified according to the OSDI score in 4 categories (normal and impaired). Cytological study (CIC plus Papanicolaou staining) using the Nelson grading system, with modifications in staging, and goblet cell counting were performed on the nasal, temporal, inferior, and superior bulbar conjunctival surfaces. Results: Nelson grading was significantly higher in patients with a severely impaired OSDI score (1.41 ± 0.14) compared to normal patients (0.86 ± 0.09) (P<.01). Goblet cell density was significantly reduced in patients with a severely impaired OSD

Dynamics of tear fluid desiccation on a glass surface: a contribution to tear quality assessment

Artículo de publicación ISIBackground: Fern-like crystalloids form when a microvolume of tear is allowed to dry out at ambient conditions on a glass surface. Presence of crystalloids in tear “microdesiccates” is used to evaluate patients with Dry-Eye disease. This study aims to examine morphologically the desiccation process of normal tear fluid and to identify changes associated with accelerated tear evaporation. Tear microdesiccates from healthy (Non-Dry Eye) and Dry Eye subjects were produced at ambient conditions. Microdesiccate formation was monitored continuously by dark-field video microscopy. Additionally, accelerated desiccation of tear samples from healthy subjects was conducted under controlled experimental conditions. Particular morphological domains of tear microdesiccates and their progressive appearance during desiccation were compared. Results: In normal tear microdesiccates, four distinctive morphological domains (zones I, II, III and transition band) were recognized. Stepwise formation of those domains is now described. Experimentally accelerated desiccation resulted in marked changes in some of those zones, particularly involving either disappearance or size reduction of fern-like crystalloids of zones II and III. Tear microdesiccates from Dry Eye subjects may also display those differences and be the expression of a more synchronous formation of microdesiccate domains. Conclusion: Morphological characteristics of tear microdesiccates can provide insights into the relative rate of tear evaporation.This study was partially supported by Grant 1110325 from Fondo Nacional de Ciencia y Tecnología (Fondecyt), Chile