Suicidal Ideation and Depression Among Adolescent and Young Adult Cancer Patients.

Purpose: Adolescent and young adult (AYA) cancer patients (aged 18-39 years) represent a unique population within oncology. The developmental and mental health challenges that can co-occur with a diagnosis of cancer during this age range make AYAs a high-risk group for mental health problems, including depression and suicidal ideation. Therefore, the objective of this study was to assess the differences in rates of suicidal ideation and depression between AYAs and older adults (OAs; aged 40+ years) within an outpatient cancer support clinic. Methods: Depression screening data from routine clinical care were gathered and analyzed for adult patients receiving support services at an outpatient academic cancer clinic. The general mental health screening protocol included the Patient Health Questionnaire (PHQ)-9, which was used as a measure of depression symptoms, including suicidal ideation. Results: Five hundred cancer survivors were included in the initial data analysis, with 21 (40.38%) of the AYAs and 143 (31.92%) of the OAs scoring ≥5 on the PHQ-9. Statistical analysis of groups at this cutoff score reflected no significant difference in depression between AYA and OA groups. However, a chi-square analysis revealed significantly higher suicidal ideation endorsement by AYAs versus OAs in this sample (χ2 [1, N = 500] = 3.98, p = 0.046). Conclusion: Results from routinely collected clinical data reveal a higher rate of suicidal ideation in AYAs compared with OA cancer patients, which supports the need for additional research on AYA cancer patient suicidal ideation in different settings and the implementation of mental health programs specifically for AYA patients.

Nonlinear optical macroscopic assessment of 3-D corneal collagen organization and axial biomechanics.

PURPOSE: To characterize and quantify the collagen fiber (lamellar) organization of human corneas in three dimensions by using nonlinear optical high-resolution macroscopy (NLO-HRMac) and to correlate these findings with mechanical data obtained by indentation testing of corneal flaps. METHODS: Twelve corneas from 10 donors were studied. Vibratome sections, 200 µm thick, from five donor eyes were cut along the vertical meridian from limbus to limbus (arc length, 12 mm). Backscattered second harmonic-generated (SHG) NLO signals from these sections were collected as a series of overlapping 3-D images, which were concatenated to form a single 3-D mosaic (pixel resolution: 0.44 µm lateral, 2 µm axial). Collagen fiber intertwining was quantified by determining branching point density as a function of stromal depth. Mechanical testing was performed on corneal flaps from seven additional eyes. Corneas were cut into three layers (anterior, middle, and posterior) using a femtosecond surgical laser system and underwent indentation testing to determine the elastic modulus for each layer. RESULTS: The 3-D reconstructions revealed complex collagen fiber branching patterns in the anterior cornea, with fibers extending from the anterior limiting lamina (ALL, Bowman's layer), intertwining with deeper fibers and reinserting back to the ALL, forming bow spring-like structures. Measured branching-point density was four times higher in the anterior third of the cornea than in the posterior third and decreased logarithmically with increasing distance from the ALL. Indentation testing showed an eightfold increase in elastic modulus in the anterior stroma. CONCLUSIONS: The axial gradient in lamellar intertwining appears to be associated with an axial gradient in the effective elastic modulus of the cornea, suggesting that collagen fiber intertwining and formation of bow spring-like structures provide structural support similar to cross-beams in bridges and large-scale structures. Future studies are necessary to determine the role of radial and axial structural-mechanical heterogeneity in controlling corneal shape and in the development of keratoconus, astigmatism, and other refractive errors.

Volumetric reconstruction of the mouse meibomian gland using high-resolution nonlinear optical imaging.

Recent studies suggest that mouse meibomian glands (MG) undergo age-related atrophy that mimics changes seen in age-related human MG dysfunction (MGD). To better understand the structural/functional changes that occur during aging, this study developed an imaging approach to generate quantifiable volumetric reconstructions of the mouse MG and measure total gland, cell, and lipid volume. Mouse eyelids were fixed in 4% paraformaldehyde, embedded in LR White resin and serially sectioned. Sections were then scanned using a 20× objective and a series of tiled images (1.35 × 1.35 × 0.5 mm) with a pixel size of 0.44 microm lateral and 2 microm axial were collected using a Zeiss 510 Meta LSM and a femtosecond laser to simultaneously detect second harmonic generated (SHG) and two-photon excited fluorescence (TPEF) signals from the tissue sections. The SHG signal from collagen was used to outline and generate an MG mask to create surface renderings of the total gland and extract relevant MG TPEF signals that were later separated into the cellular and lipid compartments. Using this technique, three-dimensional reconstructions of the mouse MG were obtained and the total, cell, and lipid volume of the MG measured. Volumetric reconstructions of mouse MG showed loss of acini in old mice that were not detected by routine histology. Furthermore, older mouse MG had reduced total gland volume that is primarily associated with loss of the lipid volume. These findings suggest that mice MG undergo "dropout" of acini, similar to that which occurs in human age-related MGD.

Evaluating corneal collagen organization using high-resolution nonlinear optical macroscopy.

PURPOSE: Recent developments in nonlinear optical (NLO) imaging using femtosecond lasers provides a noninvasive method for detecting collagen fibers by imaging second harmonic-generated (SHG) signals. However, this technique is limited by the small field of view necessary to generate SHG signals. The purpose of this report is to review our efforts to greatly extend the field of view to assess the entire collagen structure using high-resolution macroscopic (HRMac) imaging. METHODS: Intact human eyes were fixed under pressure, and the whole cornea (13-mm diameter) was excised and embedded in low-melting point agar for vibratome sectioning (200-300 microm). Sections were then optically scanned using a Zeiss LSM 510 Meta and Chameleon femtosecond laser (Carl Zeiss Microimaging Inc., Thornwood, NY) to generate SHG images. For each vibratome section, an overlapping series of three-dimensional data sets (466 x 466 x 150 microm) were taken, covering the entire tissue (15 mm x 6 mm area) using a motorized, mechanical stage. The three-dimensional data sets were then concatenated to generate an NLO-based tomograph. RESULTS: The HRMac of the cornea yielded large macroscopic (80 megapixels per plane), three-dimensional tomographs with high resolution (0.81 microm lateral, 2.0 microm axial) in which individual collagen fibers (stromal lamellae) could be traced, segmented, and extracted. Three-dimensional reconstructions suggested that the anterior cornea comprises highly intertwined lamellae that insert into the anterior limiting lamina (Bowman's layer). CONCLUSIONS: We conclude that HRMac using NLO-based tomography provides a powerful new tool to assess collagen structural organization within the cornea.

In vivo non-linear optical (NLO) imaging in live rabbit eyes using the Heidelberg Two-Photon Laser Ophthalmoscope.

Imaging of non-linear optical (NLO) signals generated from the eye using ultrafast pulsed lasers has been limited to the study of ex vivo tissues because of the use of conventional microscopes with slow scan speeds. The purpose of this study was to evaluate the ability of a novel, high scan rate ophthalmoscope to generate NLO signals using an attached femtosecond laser. NLO signals were generated and imaged in live, anesthetized albino rabbits using a newly designed Heidelberg Two-Photon Laser Ophthalmoscope with attached 25 mW fs laser having a central wavelength of 780 nm, pulsewidth of 75 fs, and a repetition rate of 50 MHz. To assess two-photon excited fluorescent (TPEF) signal generation, cultured rabbit corneal fibroblasts (RCF) were first labeled by Blue-green fluorescent FluoSpheres (1 mum diameter) and then cells were micro-injected into the central cornea. Clumps of RCF cells could be detected by both reflectance and TPEF imaging at 6 h after injection. By 6 days, RCF containing fluorescent microspheres confirmed by TPEF showed a more spread morphology and had migrated from the original injection site. Overall, this study demonstrates the potential of using NLO microscopy to sequentially detect TPEF signals from live, intact corneas. We conclude that further refinement of the Two-photon laser Ophthalmoscope should lead to the development of an important, new clinical instrument capable of detecting NLO signals from patient corneas.

High resolution three-dimensional reconstruction of the collagenous matrix of the human optic nerve head.

Glaucoma is the second most common cause of blindness worldwide, leading to irreversible loss of vision. Prior studies indicate that ocular pressure-induced displacement of the lamina cribrosa (LC) may be responsible for retinal ganglion cell axon damage inside the neural canal. We present a novel approach to imaging the entire lamina cribrosa and the scleral canal at high lateral and axial resolution by using a combination of array tomography and nonlinear optical imaging of serial ultrathin orthogonal sections to detect second harmonic generated (SHG) signals from collagen. The resulting images can be analyzed individually or combined to form a three-dimensional reconstruction of the lamina. Due to the specificity of SHG generated from collagen the density and distribution of collagen inside the scleral canal can be objectively quantified with a high degree of accuracy. The reconstruction shows a non-uniform distribution of collagen along both the longitudinal and orthogonal axes. Mapping the collagen density by geographic region reveals significant differences in collagen content that result in "thin spots" with low collagen density as well as areas of very high collagen content. This suggests a non-uniform mechanical stiffness across the lamina that may account for increased axon damage observed in glaucoma patients. The inferior temporal region of the ONH in particular is marked by low collagen density, which corresponds with clinical observations identifying this region as being more susceptible to damage during the onset of glaucoma. Further application of this technique will help characterize the relationship of age, race and gender on the morphology of the LC.