Experience of focused workshop intervention in presentation skills - Importance of foundational skills for ophthalmologists in training.

Background: The study was conducted to assess the impact of a workshop intervention designed to enhance presentation skills of ophthalmology fellows in training. Methods: A 10-hour workshop on presentation skills was conducted for ophthalmology fellows in the 2022 cohort at a single institution. An email was sent to the 2022 cohort to recruit participants. A total of 29 fellows (19 females, 10 males) volunteered to participate in the study. Participants completed a self-rating questionnaire to assess improvement in their presentation skills at four different time points of the workshop. The self-rating questionnaire utilized a ten-point rating scale (1-10) and evaluated properties and content (PC) and soft skills (SS). Data were analysed using SPSS software. Friedman and post-hoc tests compared self-ratings at four time points. Statistical significance was set at p-value < 0.05. Results: Both properties & content (PC) and soft skills (SS) showed significant difference (p < 0.001) post workshop compared to earlier stages. The higher self-rating (PC4 and SS4) highlights increased awareness towards the scope of improving the presentation after the workshop intervention. Conclusions: Presentation skills empower medical professionals to better communicate with diverse audiences, demonstrating their currency in medical knowledge, lobbying for correct understanding, and bringing praxis to pedagogy. The findings support the integration of similar workshops into medical curricula to foster well-rounded medical professionals.

Analysing the effectiveness of Just-A-Minute Optometry Clinical Pearls: a micro-learning tool in continuing optometry education.

CLINICAL RELEVANCE: Just-A-Minute Clinical Pearls as a microlearning concept may be beneficial in enhancing optometry and ophthalmology practice globally. BACKGROUND: Medical education often witnesses a gap in effectively translating the learnings into clinical practice, pointing to the complex and traditional teaching methods as hindrances. The present work studied the usefulness and acceptability of Just-A-Minute Optometry Clinical Pearls, a micro-learning tool, among optometrists and ophthalmologists. METHODS: Just-A-Minute Optometry clinical pearls were developed by the optometry team of LV Prasad Eye Institute and shared (via email) among optometrists and ophthalmologists on a daily basis between June 2021 to May 2022. In the middle of the project, the recipients were invited to participate in an online survey. The variables studied included frequency of checking clinical pearls, simplicity of their content, grasping speed, most used subspeciality pearls, knowledge gain and retention, practice applicability, overall learning experience, and the likelihood of recommending it to a friend. RESULTS: Among 150 respondents, 103 (68.7%) were ophthalmologists, and 46 (30.7%) were optometrists. The majority were from private (n = 64, 42.7%) and institutional (n = 48, 32%) practices, with 102 (68.4%) having more than five years and 21 (14%) having 2-5 years of experience. About 115 (77%) respondents checked clinical pearls every day, 147 (99%) found the format easy, and 131 (88%) could grasp the content within one minute. They felt that JAM-OCP 'always' enhanced clinical knowledge (n = 108, 72%) and clinical applicability (n = 82, 55%) and helped in knowledge retention (n = 123, 84%). The responses to the clinical application significantly varied (Chi-square tests) among subgroups of education qualification (p < 0.001) and practice types (p < 0.03). CONCLUSIONS: The Just-A-Minute Optometry Clinical Pearls were beneficial to optometrists and ophthalmologists in their practices. This, as a tele-education tool, supports continuing optometry education across the globe.

Thickness of Intraretinal Layers in Patients with Type 2 Diabetes Mellitus Depending on a Concomitant Diabetic Neuropathy: Results of a Cross-Sectional Study Using Deviation Maps for OCT Data Analysis.

Optical coherence tomography (OCT) supports the detection of thickness changes in intraretinal layers at an early stage of diabetes mellitus. However, the analysis of OCT data in cross-sectional studies is complex and time-consuming. We introduce an enhanced deviation map-based analysis (MA) and demonstrate its effectiveness in detecting early changes in intraretinal layer thickness in adults with type 2 diabetes mellitus (T2DM) compared to common early treatment diabetic retinopathy study (ETDRS) grid-based analysis (GA). To this end, we obtained OCT scans of unilateral eyes from 33 T2DM patients without diabetic retinopathy and 40 healthy controls. The patients were categorized according to concomitant diabetic peripheral neuropathy (DN). The results of MA and GA demonstrated statistically significant differences in retinal thickness between patients and controls. Thinning was most pronounced in total retinal thickness and the thickness of the inner retinal layers in areas of the inner macular ring, selectively extending into areas of the outer macular ring and foveal center. Patients with clinically proven DN showed the strongest thinning of the inner retinal layers. MA showed additional areas of thinning whereas GA tended to underestimate thickness changes, especially in areas with localized thinning. We conclude that MA enables a precise analysis of retinal thickness data and contributes to the understanding of localized changes in intraretinal layers in adults with T2DM.

Deviation Maps for Understanding Thickness Changes of Inner Retinal Layers in Children with Type 1 Diabetes Mellitus.

Purpose: To analyze the use of deviation maps (DevMs) to understand thickness changes of inner retinal layers in optical coherence tomography (OCT) data. To test a new visual analytics (VA) method with reduced complexity of OCT data analysis by comparing the layer thickness of children with type 1 diabetes mellitus (T1DM) to matched controls. Methods: OCT was performed on unilateral eyes of 26 children with T1DM without diabetic retinopathy and 29 healthy children to obtain macular volume scans. Subsequently, segmented inner retinal layers were analyzed using VA. Deviation maps were generated to readily visualize thickness differences between both groups and to investigate thickness changes of individual patients in relation to the control group. Results: In DevMs of the patient group, the total retina (TR) demonstrated localized, irregular areas of thinning (mean ± standard deviation) involving foveal center, inner macula, and inferior-nasal outer macula (-9.31 ± 1.73 µm; p < 0.05). Similarly, retinal nerve fiber layer showed continuous and localized areas of thinning in both inner and outer macula, extending nasally (-5.45 ± 4.31 µm; p < 0.05). In DevMs of individual patients, the TR and inner retinal layers revealed remarkable changes in thickness that were present between patients at both late and early stages of diabetes. Conclusion: The VA method simplifies the in-depth analysis of OCT volume data from different groups and is effective in detecting retinal thickness changes in children with diabetes. It can be easily adopted in a clinical set-up and intuitively used in complex multidisciplinary studies.

Spectral-Domain Optical Coherence Tomography for Determination of Retinal Thickness in Pediatric Patients with Mild-To-Moderate Chronic Kidney Disease: A Cross-Sectional Study.

OBJECTIVE: Children with chronic kidney diseases (CKD) are at risk for neurological diseases at early adulthood. Spectral-domain optical coherence tomography (SD-OCT) of the retina is especially suitable for determination of intraretinal layer thickness. We wonder whether retinal thinning is already present in pediatric patients with mild-to-moderate CKD. PATIENTS AND METHODS: Children (n = 15; 14.9 ± 2.4 years) with mild-to-moderate CKD (median eGFR of 95ml/min/1.73m2; range: 28-187ml/min/1.73m2) due to glomerulopathy, congenital anomalies of kidney and urinary tract (CAKUT), or haemolytic uremic syndrome (HUS) underwent a detailed ophthalmologic examination including high-resolution SD-OCT. Three OCT scans were obtained from the right eyes of all patients. Within each scan, retinal layers were separated and the mean thickness was determined at the foveal, parafoveal, and perifoveal area. The results were compared to those we obtained previously from healthy children. RESULTS: At the parafoveal area, thickness (median, range) of the total retina (ALL), ganglion cell layer (GCL), and inner plexiform layer (IPL) were reduced compared to healthy volunteers (339µm, (288-361µm) vs. 348µm, (320-385µm); 49.8µm (30.5-56.6µm) vs. 53.5µm (49.5-60.5µm) and 41.0µm (29.4-43.7µm) vs. 43.46µm (39.5-46.3µm); each p < 0.05). The intraretinal thickness measurements at the foveal and perifoveal areas revealed no statistically significant differences between patients and controls. CONCLUSION: Distinct changes within the parafoveal area of the total retina, GCL, and IPL are present in children with mild-to-moderate CKD. Prospective studies are required to assess the clinical significance of our findings.

Corneal Subbasal Nerve Plexus Changes in Severe Diabetic Charcot Foot Deformity: A Pilot Study in Search for a DNOAP Biomarker.

INTRODUCTION: Diabetic neuroosteoarthropathy (DNOAP) early symptoms are unspecific, mimicking general infectious symptoms and rendering a diagnosis challenging. Consequently, unfavourable outcomes occur frequently, with recurrent foot ulceration, infectious complications, and eventually amputation. Corneal confocal microscopy (CCM) of the subbasal nerve plexus (SNP) is used to detect early peripheral neuropathy in diabetic patients without diabetic retinopathy. This pilot study was designed to determine if specific SNP changes manifest in severe DNOAP in comparison to a healthy control group. METHODS: This pilot study utilized a matched-pair analysis to investigate SNP changes by in vivo CCM for 26 patients (mean patient age 63.7 years, range 27 to 78) with severe DNOAP defined by condition after the need for reconstructive foot surgery (n = 13) and a healthy control group (n = 13). Corneal nerve fibre length (CNFL), nerve fibre density (CNFD), nerve branch density (CNBD), average weighted corneal nerve fibre thickness (CNFTh), nerve connecting points (CNCP), and average weighted corneal nerve fibre tortuosity (CNFTo) were assessed as well as the general clinical status, diabetic status, and ophthalmologic basic criteria. RESULTS: In vivo CCM revealed significantly reduced SNP parameters in the DNOAP group for CNFL (p = 0.010), CNFD (p = 0.037), CNBD (p = 0.049), and CNCP (p = 0.012) when compared to the healthy control group. Six patients (46%) of the DNOAP group suffered from diabetic retinopathy and none of the control group. CONCLUSIONS: This pilot study revealed a rarefication of SNP in all measured parameters in patients with severe DNOAP. We see a potential value of CCM providing a SNP-based biomarker for early stages of DNOAP prior to the development of any foot deformities that needs to be evaluated in further studies. This trial is registered with German Clinical Trials Register (DKRS) DRKS00007537.

Cellular in vivo 3D imaging of the cornea by confocal laser scanning microscopy.

We present an in vivo confocal laser scanning microscopy based method for large 3D reconstruction of the cornea on a cellular level with cropped volume sizes up to 266 x 286 x 396 µm3. The microscope objective used is equipped with a piezo actuator for automated, fast and precise closed-loop focal plane control. Furthermore, we present a novel concave surface contact cap, which significantly reduces eye movements by up to 87%, hence increasing the overlapping image area of the whole stack. This increases the cuboid volume of the generated 3D reconstruction significantly. The possibility to generate oblique sections using isotropic volume stacks opens the window to slit lamp microscopy on a cellular level.

Role of Bone Morphogenetic Protein 7 (BMP7) in the Modulation of Corneal Stromal and Epithelial Cell Functions.

In the cornea, healing of the wounded avascular surface is an intricate process comprising the involvement of epithelial, stromal and neuronal cell interactions. These interactions result to the release of various growth factors that play prominent roles during corneal wound healing response. Bone morphogenetic proteins (BMPs) are unique multi-functional potent growth factors of the transforming growth factor-beta (TGF-β) superfamily. Treatment of corneal epithelial cells with substance P and nerve growth factor resulted to an increase in the expression of BMP7 mRNA. Since BMP7 is known to modulate the process of corneal wound healing, in this present study, we investigated the influence of exogenous rhBMP7 on human corneal epithelial cell and stromal cell (SFs) function. To obtain a high-fidelity expression profiling of activated biomarkers and pathways, transcriptome-wide gene-level expression profiling of epithelial cells in the presence of BMP7 was performed. Gene ontology analysis shows BMP7 stimulation activated TGF-β signaling and cell cycle pathways, whereas biological processes related to cell cycle, microtubule and intermediate filament cytoskeleton organization were significantly impacted in corneal epithelial cells. Scratch wound healing assay showed increased motility and migration of BMP7 treated epithelial cells. BMP7 stimulation studies show activation of MAPK cascade proteins in epithelial cells and SFs. Similarly, a difference in the expression of claudin, Zink finger E-box-binding homeobox 1 was observed along with phosphorylation levels of cofilin in epithelial cells. Stimulation of SFs with BMP7 activated them with increased expression of α-smooth muscle actin. In addition, an elevated phosphorylation of epidermal growth factor receptor following BMP7 stimulation was also observed both in corneal epithelial cells and SFs. Based on our transcriptome analysis data on epithelial cells and the results obtained in SFs, we conclude that BMP7 contributes to epithelial-to-mesenchymal transition-like responses and plays a role equivalent to TGF-β in the course of corneal wound healing.

[Visual Analysis of Retinal OCT Data]. / Visuelle Analyse von retinalen OCT-Daten.

Optical coherence tomography (OCT) enables noninvasive high-resolution 3D imaging of the human retina, and thus plays a fundamental role in ophthalmology. Via OCT examination, even subtle retinal changes can be captured, which occur in very early stages of different diseases (e.g., glaucoma, diabetes mellitus, or age-related macular degeneration). Yet, analyzing the resulting data is challenging. Conventionally, OCT data are strongly aggregated via automated methods. While this reduces the amount of information to be analyzed, it also makes it difficult, if not impossible, to identify small and localized retinal changes. This might lead to wrong diagnoses, since these methods do not account for patient-specific characteristics. We address this problem by providing new and efficient visual-interactive methods. Particularly, we introduce dedicated visualizations that show different aspects of the data. In addition, we support patient-specific selections of relevant data regions. Selected regions are emphasized, or separately visualized to inspect retinal substructures in detail. By visually comparing the regions to reference data, even very small retinal changes can be detected. We demonstrate the utility of our approach by applying it to data of a study with pediatric patients suffering from diabetes mellitus type 1. Our results show that visual-interactive methods indeed help to analyze subtle retinal changes and, thus, support the diagnosis of diseases in an early stage.

Characteristic quantities of corneal epithelial structures in confocal laser scanning microscopic volume data sets.

PURPOSE: Fully automated quantification of the morphologic features of different epithelial cell layers in healthy human corneas. METHODS: In vivo confocal laser scanning microscopy was performed on the unilateral eyes of 6 healthy volunteers. Stacks of 160 images (400 × 400 µm) with an interslice distance of 0.4 µm were used to generate full thickness volume data sets of the epithelium. Size and shape factors of basal (BC) and intermediate cell (IC) layers were quantified using appropriate image analysis algorithms. Evaluated parameters include mean area, compactness, solidity, major and minor diameter, and maximum boundary distance. RESULTS: Mean area of BC and IC demonstrated a linear increase from 80 to 160 µm². A similar trend was noted with major and minor diameter and maximum boundary distance. Major diameters of BC and IC measured between 13.2 and 17.0 µm, whereas minor diameter of these cells measured between 8.6 and 12.4 µm. The maximum boundary distance of BC and IC ranged from 7.0 to 9.1 µm. Compactness of epithelial cells clustered around 1.45 and 1.5, whereas cell solidity measured between 1.0 and 1.03. CONCLUSION: Several characteristic morphologic quantities can be calculated using this methodology without manual intervention. Our study demonstrated promising results and suggests that this fully automated morphologic quantification can be successfully applied to assess microstructural changes of the epithelium in normal and various corneal disorders.

Corneal responses to eye rubbing with spectral domain optical coherence tomography.

PURPOSE: Surprisingly, a significant reduction (18.4%) in epithelial thickness was found after 15 seconds of eye rubbing measured using Holden-Payor optical pachometer reported in the literature. Hence, we aimed at studying the effects of compressive and shearing pressure associated with eye rubbing on total corneal, epithelial and Bowman's membrane thickness using spectral domain OCT (SD-OCT). METHODS: SD-OCT (Spectralis; Heidelberg Engineering) was used to acquire cross-sectional images of the cornea. Central total-corneal thickness (TCT), epithelial thickness (ET) and Bowman's membrane thickness (BMT) was measured on 20 eyes of 10 subjects with normal corneas without any ocular pathology using in-house developed MATLAB (Mathworks, Inc.) program. Two different measurement methods (distance between inflection points and peak to peak distance) were performed on luminance graph to obtain thickness profile of the corneas. Baseline measurements were compared with the measurements obtained immediately after 30 seconds of circular eye rubbing over the closed eye lid with contra lateral eye at a primary gaze position. RESULTS: We have found that the mean difference in TCT, ET and BMT to be 0.44 ± 6.00 µm, 0.28 ± 1.72 µm, and 0.01 ± 0.77 µm with first method of measurement, respectively, and the mean difference in TCT and ET were -0.26 ± 5.75 µm, and 0.37 ± 1.38 µm with second method of measurement respectively before and after eye rubbing. These differences were statistically insignificant (all p > 0.05) using both measuring methods. CONCLUSION: Thirty seconds of circular pattern rubbing over closed eye lids using index finger produce no significant changes on total corneal, epithelial and Bowman's membrane thickness.

A perfluoropolyether corneal inlay for the correction of refractive error.

This study assessed the long-term biological response of a perfluoropolyether-based polymer developed as a corneal inlay to correct refractive error. The polymer formulation met chemical and physical specifications and was non-cytotoxic when tested using standard in vitro techniques. It was cast into small microporous membranes that were implanted as inlays into corneas of rabbits (n = 5) and unsighted humans (n = 5 + 1 surgical control) which were monitored for up to 23 and 48 months respectively. Overall, the inlays were well tolerated during study period with the corneas remaining clear and holding a normal tear film and with no increased vascularisation or redness recorded. Inlays in three human corneas continued past 48 months without sequelae. Inlays in two human corneas were removed early due to small, focal erosions developing 5 and 24 months post-implantation. Polymer inlays maintained their integrity and corneal position for the study duration although the optical clarity of the inlays reduced slowly with time. Inlays induced corneal curvature changes in human subjects that showed stability with time and the refractive effect was reversed when the inlay was removed. Outcomes showed the potential of a perfluoropolyether inlay as a biologically acceptable corneal implant with which to provide stable correction of refractive error.

Synthetic corneal inlays.

This review is based on the activities of the Vision Cooperative Research Centre (previously Cooperative Research Centre for Eye Research and Technology) Corneal Implant team from 1991 to 2007. The development of a synthetic polymer of perfluoropolyether (PFPE), meeting essential physical and biological requirements, for use as a corneal inlay is presented. Each inlay was placed in a corneal flap created with a microkeratome and monitored over a two-year period in a rabbit model. The results indicate that the PFPE implant shows excellent biocompatibility and biostability. As a result, a Phase 1 clinical trial is being conducted. Three years post-implantation, the PFPE inlays are exhibiting continued excellent biocompatibility. Corneal inlays made from PFPE are biocompatible with corneal tissue in the long term and offer a safe and biologically-acceptable alternative to other forms of refractive surgery.