Introduction: Alzheimer disease (AD) is the most common form of dementia worldwide. The modalities to diagnose AD are generally expensive and limited. Both the central nervous system (CNS) and the retina are derived from the cranial neural crest,therefore, changes in retinal layers may reflect changes in the CNS tissue. Optical coherence tomography (OCT) machine can show delicate retinal layers and is widely used for retinal disorders. This study aims to find a new biomarker to help clinicians diagnose AD via retinal OCT examination. Methods: After considering the inclusion and exclusion criteria, 25 patients with mild and moderate AD and 25 healthy subjects were enrolled in the study. OCT was done for all eyes. The central macular thickness (CMT) and the ganglion cell complex (GCC) thickness were calculated. The groups were compared using the SPSS software, v. 22. Results: Both GCC thickness and CMT were significantly decreased in patients with AD when compared to healthy age-and sex-matched individuals. Conclusion: Retinal changes, specifically CMT and GCC thickness, may reflect the AD process in the brain. OCT can be considered a non-invasive and inexpensive method to help diagnose AD.

Purpose: To evaluate diagnostic performance of ganglion cell inner plexiform layer (GCIPL) and retinal nerve fiber layer (RNFL) parameters measured with Cirrus high-definition optical coherence tomography (OCT) in patients with preperimetric glaucoma. Methods: In this multicenter cross-sectional study, 150 eyes of 83 patients with preperimetric glaucoma were compared with 200 eyes of age and sex matched healthy subjects. All patients had visual field testing and OCT scanning of GCIPL and RNFL in all quadrants. The independent Samples t-test was used to determine if a difference exists between the means of two independent groups on a continuous dependent variable. The area under the receiver operating characteristic (ROC) curve (AUC) of each parameter was calculated for discriminatory ability between normal controls and preperimetric glaucoma. The sensitivity and specificity were estimated by point coordinates on ROC curve. Results: The best parameters for distinguishing preperimetric glaucoma from healthy eyes were the combined average GCIPL + average RNFL, followed by average RNFL + GCIPL (inferotemporal), and average RNFL + GCIPL (minimum). The GCIPL parameters with the highest to lowest AUC (in decreasing order) were inferotemporal, followed by average, minimum, superior, inferior, superonasal, inferonasal, superotemporal, and quadrants. The RNFL parameters with the highest to lowest AUC (in decreasing order) were average, followed by nasal, temporal, superior, and inferior quadrants. The sensitivity of combined GCIPL + RNFL parameters ranged 85%–88% and the specificity ranged 76%–88%. The sensitivity for RNFL parameters ranged 80%–90% and the specificity ranged 64%–88%. Conclusion: GCIPL and RNFL have good discriminatory ability,the sensitivity and specificity increase when both parameters are combined for early detection of glaucoma.

Background and Objective: Hirschsprung’s disease is a congenital disorder, characterized by the absence of ganglion cells in the intramural and submucosal plexus in distal parts of large bowel. Diagnosis is based on the histopathologic examination of hematoxilin and eosin stained sections. Due to diagnosis limitation by Hematoxylin and Eosin staining (H&E), this study was done to identify the ganglion cells by BCL-2 immunoreactivity and compared it with H & E staining.Materials and Methods: In this laboratory study, paraffin blocks of 36 specimens demonstrating ganglion cells on original H&E stained sections and 35 specimens lacking ganglion cells on H&E staining, were selected. Recuts were stained by H&E and BCL-2 methods.Results: Ganglion cells were observed in 36 cases by H&E staining but in BCL-2 staining ganglion cells were detected in 29 cases. In 35 cases reported negative for ganglion cells on H&E staining, ganglion cells were detected in 5 cases by BCL-2 method. Sensitivity, spesificity, positive and negative predictive values for BCL-2 method for diagnosis of hirshsprung’s disease were 81%, 86%, 85% and 86% respectively. discordancy (positive BCL-2, negative H&E) was 14%.Conclusion: Immunohistochemistry method using BCL-2 improve the accuracy of diagnosis in hirschsprung’s disease, when accompanied with H&E staining, particulary for negative slides.

Background: Some pregnant women are exposed to occupational noise, a risk factor for the development of the auditory system. The auditory system is one of the areas in embryonic development in which noise might induce aberrant development. Noise can change the gene expression pattern of an embryo and thereby modify the physiology of the auditory system. Therefore, noise can change the molecular structure of the developing ear. One of the critical molecules involved in development of auditory system is glycoconjugate. The aim of this study was to investigate the molecular changes of the developing spiral ganglion after exposure to industrial levels of noise.Methods: A total of 42 pregnant mice were divided into control and experimental groups. Each group was further divided into three subgroups. The three experimental subgroups were exposed to daily noise with an intensity of 100 db for 2.5 hours until sacrifice (for the first group to be sacrificed) or day seven of postnatal life (for the other two groups). The mice offspring were sacrificed at the first, seventh and 14th days of postnatal life. The inner ears were prepared histologically. The specimens were stained with the lectins wheat germ antigen (WGA), peanut agglutinin (PNA), Dolichos biflorus agglutinin (DBA) and BSAI-B4.Results: The results indicated that, although there were no histological changes at the light-microscopic level in the ear development, statistical analysis showed that there was a significant decrease in the uptake of the BSA1-B4 lectin by neurons of spiral ganglion in 14th day of postnatal life in the experimental group compared to that of the control group (p<0.05).Conclusions: After noise exposure, in spite of normal neuronal structure, these cells were modified at the molecular level, especially in glycoconjugate expression, influencing the normal physiology of neurons and causing auditory disorders.

The mammalian cochlea is a highly complex structure which contains several cells, including sensory receptor or hair cells. The main function of the cochlear hair cells is to convert the mechanical vibrations of the sound into electrical signals, then these signals travel to the brain along the auditory nerve. Auditory hair cells in some amphibians, reptiles, fish, and birds can regenerate or replace by new cells, but irreversible damage to the mammalian hair cells are not being replaced through differentiation of the internal epithelial cells in the inner ear. Indeed, mammalian auditory hair cells do not spontaneously repair or regenerate after development. Sometimes, functions of damaged hair cells may be restored, but in most cases, there is no such possibility and permanent hearing loss occurs. Several factors such as chronic ear infections, genetic disorders, drug abuse, acoustic trauma and aging can damage the cochlea, resulting in permanent hearing loss. More than 250 million people in the world have disabling hearing impairment...