Characterizing the thermally induced structural changes to intact porcine eye, part 1: second harmonic generation imaging of cornea stroma

We characterize the structural changes of porcine corneal structures from 25 to 90 degrees C using second harmonic generation (SHG) microscopy. Our results show that porcine stroma undergoes several distinct stages of structural changes between 25 and 90 degrees C. A decrease in SHG intensity from 30 to 45 degrees C and the existence of SHG intensity peaks at 53, 65, and 77 degrees C correlate to distinct structural alterations of the corneal stroma. At higher temperatures, the SHG intensity decreases and a baseline in SHG signal is reached at 90 degrees C. Our results demonstrate that SHG microscopy is a useful technique for obtaining qualitative and quantitative information of thermally treated corneal fibers without histological or labeling procedures. With additional developments, SHG imaging may be developed into an effective imaging technique for in vivo characterization of cornea structural changes.     

Nodal and paranodal structural changes in frog optic nerve during early Wallerian degeneration

Summary Ultrastructural changes in the nodal and paranodal regions of myelinated nerve fibres of frog optic nerves were studied during early stages of Wallerian degeneration. The earliest changes seen include retraction of paranodal loops of myelin from the axolemma and disconnection of paranodal myelin loops from myelin lamellae. These paranodal changes are asymmetric around the node and may be more advanced on either the proximal or distal side. Axoplasmic changes, including segregation of microtubules from neurofilaments, disorientation of microtubules and accumulation of abnormal organelles at nodes, appear shortly. In some axons the undercoating along the widened nodal surfaces becomes patchy, and blebs appear in the nodal axolemma. In freeze-fracture replicas a mixture of particle clusters and particle-free areas appears in both E- and P-faces of the nodal axolemma. Blebs remain particle free. Initially, E-face particles remain segregated to the node and are present only at much lower concentrations in the demyelinated paranodal axolemma, suggesting that they are not freely mobile at this stage. Nodal E-face particles begin to decrease on day 5 associated with an increase in particles at the adjacent demyelinated paranode, and by day 11 the particle distribution is uniformly low over the entire extent of the nodal and demyelinated paranodal axolemma. If nodal E-face particles represent sodium channels, as has been proposed, the sequence of changes in Wallerian degeneration would be compatible with a gradual redistribution of nodal sodium channels into the demyelinated paranode.     

In-vivo high resolution imaging of optic nerve head drusen using spectral-domain Optical Coherence Tomography

Background  

Optic nerve head drusen (ONHD) are white calcareous deposits, seen either superficially on the optic nerve head or buried within it. Diagnosis of ONHD is made by one or more ways: clinical exam, autofluorescence, ultrasound of the optic nerve, CT scan and/or visual field examination. The present study describes features of ONHD based on another diagnostic modality, the spectral-domain OCT (Spectralis).     

Quantitative analysis of structural disorder in intervertebral disks using second harmonic generation imaging: comparison with morphometric analysis

A novel signal processing algorithm for quantifying structural disorder in biological tissue using second harmonic generation (SHG) imaging is described. Both the magnitude and the pattern of disorder in collagenous tissues can be determined with this method. Mathematical models are used to determine the range of disordered states over which the algorithm can be used, because highly disordered biological samples do not generate second harmonic signals. The method is validated by measuring disorder in heated fascicles using SHG and showing that results are significantly correlated with morphometric determination. Applicability of the method to tissue pathology is demonstrated by analysis of a mouse model of intervertebral disk injury. Disks were subjected to tensile or compressive forces in vivo for one week. Structural disorder in the annulus fibrosus was measured by SHG scanning and by standard morphometric analysis. Values for disorder obtained by SHG scanning were significantly correlated with values obtained by morphometry (p<0.001). Quantitation of disorder using SHG offers significant advantages over morphometric determination. Data obtained in this study suggest that this method can be used to discriminate between reversible and irreversible tissue damage.     

Use of an ex vivo local lymph node assay to assess contact hypersensitivity potential

The local lymph node assay (LLNA) is used to assess the contact hypersensitivity potential of compounds. In the standard assay, mice are treated topically with test compound to the dorsum of both ears on Days 1-3. The induction of a hypersensitivity response is assessed on Day 6 by injecting [(3)H]-thymidine into a tail vein and measuring thymidine incorporation into DNA of lymph node cells draining the ears. The ex vivo LLNA is conducted similarly except lymphocyte proliferation is assessed after in vitro incubation of lymph node cells with [(3)H]-thymidine, which significantly reduces the amount of radioactive waste. The current study tested the use of this approach for hazard assessment of contact hypersensitivity and to estimate allergenic potency. Female BALB/c mice were treated on Days 1-3 with two nonsensitizers (4' -methoxyacetophenone, diethyl phthalate), three weak sensitizers (hydroxycitronellal, eugenol, citral), one weak-to-moderate sensitizer (hexylcinnamic aldehyde), two moderate sensitizers (isoeugenol, phenyl benzoate), and one strong sensitizer (dinitrochlorobenzene). On Day 6, isolated lymph node cells were incubated overnight with [(3)H]-thymidine and thymidine incorporation was measured by liquid scintillation spectrophotometry. The ex vivo LLNA accurately distinguished the contact sensitizers from the nonsensitizing chemicals, and correctly ranked the relative potency of the compounds tested. The EC3 values, i.e., the effective concentration of test substance needed to induce a stimulation index of 3, were as follows: 4' -methoxyacetophenone (> 50%), diethyl phthalate (> 50%), hydroxycitronellal (20.4%), eugenol (13.6%), citral (8.9%), isoeugenol (3.8%), hexylcinnamic aldehyde (2.7%), phenyl benzoate (2%), and dinitrochlorobenzene (0.02%). In addition, low inter-animal and inter-experiment variability was seen with 25% hexyl-cinnamic aldehyde (assay positive control). The results of the ex vivo LLNA in the current study were consistent with published reports using the standard LLNA and provided further evidence that supports the use of this alternative approach to assess the skin sensitization potential of test compounds.     

视乳头的结构和力学特性对筛板变形的影响

目的:建立包含筛板的全眼球轴对称模型,分析视乳头的结构和力学特性对青光眼患者筛板变形的影响。方法:基于青光眼患者和正常对照组的视乳头结构参数数据,并参考文献结果,建立包含筛板的全眼球轴对称有限元模型;分析视乳头的力学特性和结构参数对筛板变形的影响。结果:眼压升高会导致筛板后移,且随着眼压的升高,筛板变形程度增大。巩膜、筛板和硬脑膜的弹性模量对筛板变形的影响程度较大;且筛板厚度、视杯深度、视杯宽度均对筛板变形有影响。青光眼患者的眼底结构参数、力学特性会使其筛板对眼压和颅压的作用更敏感。结论:有限元方法可用于筛板变形影响因素的研究,为青光眼早期诊断提供参考。     

New insights into blindness; mechanical fatigue of optic nerve head in glaucomatous optic neuropathy

A common cause of blindness worldwide is glaucoma. It is characterized by visual field loss which is caused by optic nerve damage leading to glaucomatous optic neuropathy (GON). Modelling of GON development may be helpful for designing strategies to decelerate the rate of GON progression and prevent GON development at early stages. Attempts to complete the modelling of GON development continue. In this paper, it was speculated that the modelling could be more completed through a biomechanical point of view. GON may result from the mechanical fatigue effects of radial tensile stress (TS), caused by intra-ocular pressure (IOP), on the optic nerve head (ONH). The mechanical fatigue rate is influenced by patient’s age, the maximum and minimum magnitude of IOP, the amplitude of IOP and TS fluctuations, the ONH geometry, scleral thickness and biomechanical properties of the sclera, particularly the peripapillary part, and the axial length of the globe. Based on this model, more efficient strategies can be developed to augment the ONH and decelerate the progression of glaucomatous optic nerve damage, and even screen high-risk individuals at early stages.     

Application of finite-element analysis with optimisation to assess thein vivo non-linear myocardial material properties using echocardiographic imaging

An application of finite-element analysis with an optimisation technique to assess the myocardial material properties in diastasisin vivo is described. Using the data collected from an animal model, the three-dimensional geometry of the left ventricular chamber, at several times in diastole, was reconstructed. From the measurement of the ventricular chamber pressure during image acquisition, finite-element analysis was performed to predict the expansion during diastasis. Initially, by restricting the motion of the epicardial nodes and computing the reaction forces, an ‘equivalent pericardial pressure’ was determined and applied in subsequent analysis. The duration of diastasis was divided into three or four intervals and the analysis was performed at each interval to assess the material properties of the myocardium. Using such a step-wise linear approach, the non-linear material properties of the myocardium during passive expansion was determined. Our results demonstrated that the computed ‘equivalent pericardial pressure’ increased with and was smaller than the corresponding left ventricularchamber pressure. The passive myocardium exhibited a linear tangent modulus against chamber pressure relationship which is equivalent to an exponential stress/strain relationship, similar to those suggested byin vitro studies.     

Functional and fine structural changes in isolated rat lungs challenged with endotoxin ex vivo and in vitro.

The aim of this study was to relate changes in rat lung functions caused by the endotoxin lipopolysaccharide (LPS) to alterations in structure. The following four experimental groups were used: 1), control in vitro, perfusion for 150 minutes; 2), LPS in vitro, perfusion for 150 minutes and infusion of 5 mg of LPS after 40 minutes; 3), control ex vivo, perfusion for 10 minutes; and 4), LPS ex vivo, lungs perfused for 10 minutes from rats treated for 110 minutes with 20 mg/kg LPS intraperitoneally. Histologically, blood-derived leukocytes were detectable only in lungs from group 4, where neutrophils were found in capillaries, interstitium, and endothelial pouches. LPS treatment increased pulmonary resistance and decreased pulmonary compliance in group 4 (ex vivo), and, to a greater extent, in group 2 (in vitro). In these two groups, formation of giant lamellar bodies in the type II pneumocytes was observed. By histological examination, the bronchoconstriction induced by LPS in vitro was localized to the terminal bronchioles. At 2 hours after LPS treatment, no edema and no change in precapillary and postcapillary resistance, capillary pressure, vascular compliance, capillary permeability, and the wet/dry ratio was observed. Thus, our major findings are that LPS induced constriction of the terminal bronchioles in vitro, formation of giant lamellar bodies in type II pneumocytes ex vivo and in vitro, and trapping of neutrophils in endothelial pouches in vivo.     

Application of electron microscopy to the study of structural changes in the liver in non-A,non-B hepatitis

Ultrastructural studies employing techniques such as alternative electron metal stain, high-angle tilting and high-voltage electron microscopy were carried out on liver biopsies obtained from chimpanzees infected with non-A, non-B hepatitis. Typical derangement of the endoplasmic reticulum leading to the formation of tubular structures in hepatocytes was observed. The use of potassium permanganate as an alternative stain revealed two features which have not been previously described. The first of these shows the wall of the tubular structures to be composed of a well-defined fibrillarlike meshwork with a periodicity of approximately 15 nm. The second feature is the demonstration of clusters of fibrin-like inclusions consisting of striated fibrils in the neighbourhood of the tubular structures. The presence of intracytoplasmic fibrin may indicate non-specific morphological evidence of cell injury. Crystalline structures containing arrays of particles with an average size of 24 nm were also observed in the endoplasmic reticulum of endothelial cells of the hepatic sinusoids. Morphological differences between the crystalline lattice and the reticular arrangement, demonstrated with the use of high-angle tilting of the specimen in the electron microscope suggest that the arrays may not be viral particles but a reflection of pathological response of the host cell.     

Prostaglandin E2 changes in the retina and optic nerve of an eye with injured optic nerve.

Changes in arachidonic acid metabolism were studied in the optic nerve, the chorioretina, and in the vitreous following crush injury to the optic nerve of rats. Crush injury led to: (i) a 3.9-fold increase in optic nerve prostaglandin type E2 in vitro production which peaked on day 5 and was followed by a gradual decline, but was still significantly higher than baseline levels by day 12; (ii) a two-fold increase in the chorioretina prostaglandin type E2 in vitro production which peaked on day 1, and resumed baseline levels by day 3; (iii) a 3.5-fold increase in vitreous prostaglandin type E2 levels on day 1 which remained at 1.5-2 times higher than baseline levels for the rest of the study period (12 days). The findings indicate that the pattern of changes in prostaglandin type E2 production by the optic nerve (consisting mostly of white matter) is different from that described for injured brain tissues. The prolonged accumulation of vitreal prostaglandin type E2 in eyes with damaged optic nerve may lead to undesirable effects on the retina beyond those directly manifested in the retina by altered axonal flow in the injured optic nerve.     

Fluorescence imaging to assess the matrix metalloproteinase activity and its inhibitor in vivo

Matrix metalloproteinases (MMPs) are a kind of secretory proteinases. Degradation of the extracellular matrix (ECM) by MMPs enhances tumor invasion and metastasis. To monitor MMPs activity and assess the MMP inhibitor effects in vivo, we constructed a plasmid that encoded a secretory fluorescent sensor named DMC (DsRed2-MSS-CFP expressed from pDisplay vector) that DsRed2 and cyan fluorescent protein (CFP) linked by MMP substrate site (MSS). MDA-MB 435s cells highly expressing endogenetic secretory MMP were transfected with the DMC plasmid so that the DMC could be cleaved by endogenetic MMP and the fluorescence ratio of DsRed2 to CFP was decreased. Treating the cells with GM6001, an MMP inhibitor, blocked the cleavage of DMC and caused an increase of the DsRed2/CFP ratio. The same result was achieved by using an in vivo tumor model that stable DMC-expressing MDA-MB 435s cells inoculated onto the chorioallantoic membrane of developing chick embryos to form primary tumors on the membrane. Thus, the fluorescent sensor DMC is able to sensitively monitor MMP activity and assess MMP inhibitors for anticancer research in vivo. This proves a novel method to efficiently screen and assess the anticancer drug MMP inhibitor in living cells and in vivo tumor models.     

Longitudinal in vivo imaging to assess blood flow and oxygenation in implantable engineered tissues

The functionality of vascular networks within implanted prevascularized tissues is difficult to assess using traditional analysis techniques, such as histology. This is largely due to the inability to visualize hemodynamics in vivo longitudinally. Therefore, we have developed dynamic imaging methods to measure blood flow and hemoglobin oxygen saturation in implanted prevascularized tissues noninvasively and longitudinally. Using laser speckle imaging, multispectral imaging, and intravital microscopy, we demonstrate that fibrin-based tissue implants anastomose with the host (severe combined immunodeficient mice) in as short as 20?h. Anastomosis results in initial perfusion with highly oxygenated blood, and an increase in average hemoglobin oxygenation of 53%. However, shear rates in the preformed vessels were low (20.8±12.8?s(-1)), and flow did not persist in the vast majority of preformed vessels due to thrombus formation. These findings suggest that designing an appropriate vascular network structure in prevascularized tissues to maintain shear rates above the threshold for thrombosis may be necessary to maintain flow following implantation. We conclude that wide-field and microscopic functional imaging can dynamically assess blood flow and oxygenation in vivo in prevascularized tissues, and can be used to rapidly evaluate and improve prevascularization strategies.     

The peripapillary glia of the optic nerve head in the chicken retina

Abstract The eye of reptiles and birds is characterized by an avascular retina and a vascular convolute called conus papillaris in reptiles and pecten oculi in birds which arises from the papilla nervi optici (PNO) or optic nerve head into the vitreous. At least in birds, this central part of the retina is the site of a heterogeneous population of glial cells. Müller cells reside in the retina, astrocytes in the optic nerve, and pecteneal glial cells in the pecten. The latter are developmentally related to the pigment epithelial cells. In addition to these established types of cells, there is a population of glial cells lining the base of the pecten oculi. In the present study, we investigated both the morphology and the development of these glial cells of the PNO in a series of chicken embryos. These cells were called peripapillary glial cells. They were characterized by their morphology and by their spatiotemporal expression of antigens typical of glial cells (intermediate filaments and glutamine synthetase). They reside at the border between the retina and the optic nerve and at the innermost border of the ventricular cleft representing transitional forms among Müller cells, astrocytes, and pigment epithelial cells. The developmental data suggest a migration of the perikarya of the peripapillary glia in vitread direction, which may coincide with that of the pecteneal glia. Whereas the pecteneal glial cells differentiate morphologically from E16 on, the peripapillary glia retain characteristics of radial glia by spanning the distance from the vitreous to the ventricular cleft. Blood vessels only occurred in the optic nerve head and the pecten oculi. No capillaries were found in the retinal tissue, beyond the peripapillary glia, leading us to suggest that these cells may play a role in demarcating the outer limit of vascularization. The functional properties of these cells are unknown but were discussed to include prevention of vessel growth into the avascular retina and/or axonal guidance during development.     

Replication of simian immunodeficiency virus (SIV) in ex vivo lymph nodes as a means to assess susceptibility of macaques in vivo

Six macaques, apparently uninfected, following low-dose exposure to the pathogenic SIV(mac251) and SIV(SME660) by the mucosal route, were used in a pilot study to investigate whether infectability of ex vivo lymph nodes could predict resistance and/or susceptibility to SIV infection in vivo. Of six macaques exposed to the less-pathogenic virus SIV(MNE), four resisted viral infection. Analysis of the susceptibility of the PBMC of these four animals before SIV(MNE) challenge indicated that all of them were resistant to infection by the SIV(BK28) isolate and, in three of them, this resistance was dependent on CD8+ T cells. Blocks of lymph nodes of these four macaques were resistant to SIV(MNE) infection ex vivo following SIV(MNE) viral challenge exposure. However, the same blocks from the same animals were permissive to the more virulent SIV(251(32H)). Accordingly, three of these macaques were readily infected following challenge exposure with SIV(251(32H)). Lymphoproliferative responses in blood or lymph nodes, local C-C chemokine production in the lymph-node explants, and cytotoxic T-cell activity measured throughout the study did not correlate with ex vivo resistance or susceptibility to in vivo infection. In conclusion, PBMC and lymph-node resistance or susceptibility to infection ex vivo appeared to correlate with in vivo infectivity and, thus, these approaches should be further tested for their predictive value for in vivo infection.     

Enzyme histochemical changes in some optic projection areas of the goldfish after optic nerve lesions

Enzyme histological changes have been studied in several optic projection areas after right optic nerve lesion in goldfish. An increase in acid phosphatase activity was found in the optic tectum, nucleus rotundus, nucleus geniculatus lateralis and area pretectalis between 2 and 15 days postoperatively. The enzymes glutamate dehydrogenase, lactate dehydrogenase, NADH tetrazolium reductase, cytochrome oxidase, succinate dehydrogenase and beta-hydroxybutyrate dehydrogenase showed a decrease in activity in all or some of these projection areas. No changes were found in acetylcholinesterase activity after optic nerve lesions. Three weeks postoperatively, all enzyme activities returned to the same level as on the normal side. The results are discussed in relation to possible neurotransmitters in goldfish optic terminals.     

In vivo monitoring of structural and mechanical changes of tissue scaffolds by multi-modality imaging

Degradable tissue scaffolds are implanted to serve a mechanical role while healing processes occur and putatively assume the physiological load as the scaffold degrades. Mechanical failure during this period can be unpredictable as monitoring of structural degradation and mechanical strength changes at the implant site is not readily achieved in vivo, and non-invasively. To address this need, a multi-modality approach using ultrasound shear wave imaging (USWI) and photoacoustic imaging (PAI) for both mechanical and structural assessment in vivo was demonstrated with degradable poly(ester urethane)urea (PEUU) and polydioxanone (PDO) scaffolds. The fibrous scaffolds were fabricated with wet electrospinning, dyed with indocyanine green (ICG) for optical contrast in PAI, and implanted in the abdominal wall of 36 rats. The scaffolds were monitored monthly using USWI and PAI and were extracted at 0, 4, 8 and 12 wk for mechanical and histological assessment. The change in shear modulus of the constructs in vivo obtained by USWI correlated with the change in average Young's modulus of the constructs ex vivo obtained by compression measurements. The PEUU and PDO scaffolds exhibited distinctly different degradation rates and average PAI signal intensity. The distribution of PAI signal intensity also corresponded well to the remaining scaffolds as seen in explant histology. This evidence using a small animal abdominal wall repair model demonstrates that multi-modality imaging of USWI and PAI may allow tissue engineers to noninvasively evaluate concurrent mechanical stiffness and structural changes of tissue constructs in vivo for a variety of applications.     

Effect of pulse duration on two-photon excited fluorescence and second harmonic generation in nonlinear optical microscopy

We have developed a multiphoton microscopy (MPM) system using a 12-fs Ti:sapphire laser with adjustable dispersion precompensation in order to examine the impact of pulse duration on nonlinear optical signals. The efficiencies of two-photon-excited fluorescence (TPEF) and second harmonic generation (SHG) were studied for various pulse durations, measured at the sample, ranging from approximately 400 fs to sub-20 fs. Both TPEF and SHG increased proportionally to the inverse of the pulse duration for the entire tested range. Because of improved signal-to-noise ratio, sub-20-fs pulses were used to enhance MPM imaging depth by approximately 160%, compared to 120-fs pulses, in human skin.