Morphological and biochemical analysis of intact and opaque cornea in dogs

The arrangement of collagen fibrils and glycosaminoglycans (GAGs) in substantia propria are important for maintaining transparency of the cornea. Interferences in collagen fibrils and GAG production could be adversative to corneal integrity. In this study, six dogs consisting of four Beagles with normal cornea (normal), one Beagles with opaque cornea (sample No. 1) and one Shih Tzu with neovascularization opaque cornea (sample No.2) were used. All samples were observed morphologically by light and electron microscopes to obtain diameter and distribution of collagen fibrils in substantia propria and were performed biochemically to investigate into GAGs and collagen types. The average diameter of collagen fibrils in the intact cornea of normal, sample No.1 and No.2 was 33.2, 35.0 and 25.0 nm, respectively. The percentage of matrix per unit area was 67% in normal, 87% in sample No.1 and 28.3% in sample No.2. The type III collagen ratio was 25.3% in normal, 21.3% in sample No.1 and 35.8% in sample No.2. The relative amount of heparan sulfate, chondroitin sulfate, dermatan sulfate and keratin sulfate was 1.5, 9.7, 51.1 and 37.7% in normal, 3.3, 26.0, 45.7 and 23.7% in sample No.1 and 1.2, 18.0, 16.6 and 54.1% in sample No.2. Hyaluronic acid was found only in sample No.1 with a relative amount of 1.3%. Since there was some relationship between collagen formation and GAGs composition, it might be speculated that disturbance in arrangement of collagen fibrils and GAG metabolism especially in substantia propria would bring up opacity of the cornea.     

An ultrastructural investigation of dermatopontin-knockout mouse corneas

Introduction The corneal stroma is composed of a network of heterotypic collagen fibrils, proteoglycans and matrix proteins. Transparency of the tissue principally requires the uniformity of fibril diameters and interfibrillar distances and the presence of a quasi‐hexagonal lattice arrangement of parallel fibrils. Keratan sulfate proteoglycans (KSPGs) have a crucial role and the KS chains are clearly required for the maintenance of transparency. Undersulfation of corneal KS results in tissue opacity and the lumican (a KSPG) knockout mouse shows corneal opacity and the disruption of collagen fibril diameters and interfibrillar distances ( Chakravarti et al. 1998 ). Biochemical analysis has shown that dermatopontin is an abundant component of the extracellular matrix and that it interacts with KSPGs via the KS chains. This study aims to determine whether dermatopontin has a direct role in corneal matrix organization by investigating the corneal ultrastructure of dermatopontin‐null (dpt^–/–) mouse corneas. Materials and methods Conventional light microscopy was used to compare the corneal thickness of dpt^–/– mice ( Takeda et al. 2002 ) with that of the wild‐type. Collagen fibril distribution was studied using transmission electron microscopy and the datasets analysed using SIS‐pro image analysis software to determine fibrillar volume, shape factor, fibril diameter and spacing. Results Light microscopy demonstrated that dpt^–/– corneas show a 24% reduction in average stromal thickness compared to wild‐type (P < 0.001). The epithelium and Descemet's membrane appear normal. Examination of dpt^–/– stroma by transmission electron microscopy indicates a significant disruption to lamellar organization in the posterior region while the central and anterior regions appear largely unaffected compared to wild‐type. The collagen fibrils in dpt^–/– stroma show a pronounced increase in interfibrillar spacing as well as exhibiting a lower fibril volume fraction. There is no apparent difference in fibril diameter between dpt^–/– and wild‐type mice. Discussion Collectively, these data suggest that dermatopontin plays a key role in collagen fibril organization and deposition. Like the cornea from lumican‐knockout mice ( Chakravarti et al. 1998 ), the defects in collagen organization in dpt^–/– cornea appear to be most severe in the posterior stroma. It is likely that dermatopontin interacts with the KS chains on lumican and this interaction is involved in the maintenance of stromal architecture.     

The arrangement of collagen fibrils in the iridescent cornea of the scorpion fish, Taurulus (Cottus) bubalis, and the transparency of vertebrate corneal stroma.

The iridescent layer in the corneal stroma of the scorpion fish, Taurulus (Cottus) bubalis (Scorpaeniformes), is composed of alternating thin lamellae of normal stroma containing collagen fibrils and lamellae of an amorphous dense-staining material. 2. Iridescence is lost after conventional resin embedding procedures, but is retained after embedding in urea-glutaraldehyde polymer. 3. The retention of iridescence and the absence of gross thickness changes during embedding in urea-glutaraldehyde polymer are an indication that the fine structure of the cornea is less altered than by conventional resin embedding. 4. It is believed that in life the collagen fibrils in the cornea of the scorpion fish and the cornea of the frog and rabbit are slightly larger and much more closely packed than is revealed by conventional resin-embedded sections.     

Rabbit corneal damage produced by Pseudomonas aeruginosa infection.

Gross, light microscopic, and electron microscopic examination of the rabbit corneal destruction produced by experimental Pseudomonas aeruginosa infections revealed a combination of acute inflammation and liquefaction necrosis of the cornea. Degeneration of the epithelial cells and the start of polymorphonuclear leukocyte infiltration of the cornea occurred initially. These changes were followed by loss of the epithelium, degeneration and loss of the keratocytes and endothelium, loss of the characteristic weblike pattern of the proteoglycan ground substance, dispersal of ultrastructurally normal collagen fibrils, extensive accumulation followed by degeneration of polymorphonuclear leukocytes, and accumulation of plasma proteins and fibrin in the necrotic cornea. Histochemical examination of the cornea suggested a loss of the proteoglycan ground substance but not of collagen. Rabbit corneas injected with Clostridium histolyticum collagenase showed gross and cellular changes similar to those observed during the pseudomonal infections; however, histochemical examination suggested a loss of collagen, and electron microscopy revealed ultrastructurally abnormal collagen fibrils. The results support the idea (i) that a bacterial or host-derived collagenase is not required for extensive corneal damage during a P. aeruginosa corneal infection, and (ii) that a P. aeruginosa corneal infection may severly damage the cornea by producing extensive corneal edema and by causing the loss of the corneal proteoglycan ground substance, thus resulting in dispersal of undamaged collagen fibrils, weakening of the cornea, and subsequent descemetocele formation and corneal perforation by the anterior chamber pressure.     

The engineering of organized human corneal tissue through the spatial guidance of corneal stromal stem cells

Corneal stroma is an avascular connective tissue characterized by layers of highly organized parallel collagen fibrils, mono-disperse in diameter with uniform local interfibrillar spacing. Reproducing this level of structure on a nano- and micro-scale may be essential to engineer corneal tissue with strength and transparency similar to that of native cornea. A substrate of aligned poly(ester urethane) urea (PEUU) fibers, 165 ± 55 nm in diameter, induced alignment of cultured human corneal stromal stem cells (hCSSCs) which elaborated a dense collagenous matrix, 8-10 μm in thickness, deposited on the PEUU substratum. This matrix contained collagen fibrils with uniform diameter and regular interfibrillar spacing, exhibiting global parallel alignment similar to that of native stroma. The cells expressed high levels of gene products unique to keratocytes. hCSSCs cultured on PEUU fibers of random orientation or on a cast film of PEUU also differentiated to keratocytes and produced abundant matrix, but lacked matrix organization. These results demonstrate the importance of topographic cues in instructing organization of the transparent connective tissue of the corneal stroma by differentiated keratocytes. This important information will help with design of biomaterials for a bottom-up strategy to bioengineer spatially complex, collagen-based nano-structured constructs for corneal repair and regeneration.     

The subfibrillar arrangement of corneal and scleral collagen fibrils as revealed by scanning electron and atomic force microscopy

The present study was designed to analyze the subfibrillar structure of corneal and scleral collagen fibrils by scanning electron microscopy (SEM) and atomic force microscopy (AFM). Isolated collagen fibrils of the bovine cornea and sclera were fixed with 1% OsO4, stained with phosphotungstic acid and uranyl acetate, dehydrated in ethanol, critical point-dried, metal-coated, and observed in an in-lens type field emission SEM. Some isolated collagen fibrils were fixed with 1% OsO4, dehydrated, critical point-dried and observed without metal-coating in an AFM. Isolated collagen fibrils treated with acetic acid were also examined by SEM and AFM. SEM and AFM images revealed that corneal and scleral collagen fibrils had periodic transverse grooves and ridges on their surface; the periodicity (i.e., D-periodicity) was about 63 nm in the cornea and about 67 nm in the sclera. Both corneal and scleral collagen fibrils contained subfibrils running helicoidally in a rightward direction to the longitudinal axis of the fibril; the inclination angle was about 15 degrees in the corneal fibrils and 5 degrees in the scleral fibrils. These findings indicate that the different D-periodicity between corneal and scleral fibrils depends on the different inclinations of the subfibrils in each fibril. The present study thus showed that corneal collagen fibrils differ from scleral collagen fibrils not only in diameter but also in substructure.     

Collagen fibril assembly during postnatal development and dysfunctional regulation in the lumican-deficient murine cornea.

The transparent cornea is the outer barrier of the eye and is its major refractive surface. Development of a functional cornea requires a postnatal maturation phase involving development, growth and organization of the stromal extracellular matrix. Lumican, a leucine-rich proteoglycan, is implicated in regulating assembly of collagen fibrils and the highly organized extracellular matrix essential for corneal transparency. We investigated the regulatory role(s) of lumican in fibril assembly during postnatal corneal development using wild type (Lum+/+) and lumican-null (Lum-/-) mice. In Lum+/+ mice, a regular architecture of small-diameter fibrils is achieved in the anterior stroma by postnatal day 10 (P10), while the posterior stroma takes longer to reach this developmental maturity. Thus, the anterior and the posterior stroma follow distinct developmental timelines and may be under different regulatory mechanisms. In Lum-/- mice, it is the posterior stroma where abnormal lateral associations of fibrils and thicker fibrils with irregular contours are evident as early as P10. In contrast, the anterior stroma is minimally perturbed by the absence of lumican. In Lum+/+ mice, lumican is expressed throughout the developing stroma at P10, with strong expression limited to the posterior stroma in the adult. Therefore, the posterior stroma, which is most vulnerable to lumican-deficiency, demonstrates an early developmental defect in fibril structure and architecture in the Lum-/- mouse. These defects underlie the reported increased light scattering and opacity detectable in the adult. Our findings emphasize the early regulation of collagen structure by lumican during postnatal development of the cornea.     

Wave-length dependencies of light scattering in normal and cold swollen rabbit corneas and their structural implications

1. The studies described herein involve the use of light scattering measurements to characterize the ultrastructural arrangement of the constituent collagen fibrils in rabbit corneal stromas.2. Theoretical light scattering techniques for calculating the scattering to be expected from the structures revealed by electron micrographs are discussed, and comparison with the experimental light scattering tests the validity of these structures.3. The wave-length dependence of light transmission and of angular light scattering from normal corneas is in agreement with the short range ordering of collagen fibrils depicted in electron micrographs.4. The transmission measurements on oedematous rabbit corneas indicate that transmission decreases linearly with the ratio of thickness to normal thickness.5. The wave-length dependence of transmission through cold swollen corneas indicates that the increased scattering is caused by large inhomogeneities in the ultrastructure. Electron micrographs do, indeed, reveal the presence of such inhomogeneities in the form of large regions completely devoid of fibrils.     

Orthogonal scaffold of magnetically aligned collagen lamellae for corneal stroma reconstruction

The creation of 3D scaffolds that mimic the structure of physiological tissue required for normal cell function is a major bioengineering challenge. For corneal stroma reconstruction this necessitates the creation of a stroma-like scaffold consisting of a stack of orthogonally disposed sheets of aligned collagen fibrils. This study demonstrates that such a scaffold can be built up using magnetic alignment. By allowing neutralized acid-soluble type I collagen to gel in a horizontal magnetic field (7 T) and by combining a series of gelation-rotation-gelation cycles, a scaffold of orthogonal lamellae composed of aligned collagen fibrils has been formed. Although initially dilute, the gels can be concentrated without noticeable loss in orientation. The gels are translucent but their transparency can be greatly improved by the addition of proteoglycans to the gel-forming solution. Keratocytes align by contact guidance along the direction of collagen fibrils and respect the orthogonal design of the collagen template as they penetrate into the bulk of the 3D matrix. The scaffold is a significant step towards the creation of a corneal substitute with properties resembling those of native corneal stroma.     

Irreversible optical clearing of rabbit dermis for autogenic corneal stroma transplantation

Tissue engineering and transplantation of autogenic grafts have been widely investigated for solving problems on current allograft treatments (i.g., donor shortage and rejection). However, it is difficult to obtain an autogenic corneal stromal replacement that is composed of transparent, tough, and thick collagen constructs by current cell culture-based tissue engineering. Aim of this study is to develop transparent dermis for an autogenic corneal stroma transplantation. This study examined dehydration at 4-8°C and carbodiimide cross-linking on cloudy rabbit dermis (approx. 1.8%-3.8% light transmittance at 550 nm) for dermis optical clearing. Transparency of dehydrated rabbit dermis was founded to be approx. 37.9%-41.4% at 550 nm. Additional cross-linking treatment on dehydrated dermis prevented from swelling and clouding in saline, and improved its transparency to be 56.9% at 550 nm. Rabbit corneal epithelium was found to regenerate on optically cleared dermis in vitro. Furthermore, no abnormal biological response (i.e., inflammation, vascularization, and the barrier defect of epithelia) or no optical functional change on optically cleared dermis was observed during its 4-week autogenic transplantation into rabbit corneal stromal pocket.     

The scale of substratum topographic features modulates proliferation of corneal epithelial cells and corneal fibroblasts

The cornea is a complex tissue composed of different cell types, including corneal epithelial cells and keratocytes. Each of these cell types are directly exposed to rich nanoscale topography from the basement membrane or surrounding extracellular matrix. Nanoscale topography has been shown to influence cell behaviors, including orientation, alignment, differentiation, migration, and proliferation. We investigated whether proliferation of SV40-transformed human corneal epithelial cells (SV40-HCECs), primary human corneal epithelial cells (HCECs), and primary corneal fibroblasts is influenced by the scale of topographic features of the substratum. Using basement membrane feature sizes as our guide and the known dimensions of collagen fibrils of the corneal stroma (20-60 nm), we fabricated polyurethane molded substrates, which contain anisotropic feature sizes ranging from 200-2000 nm on pitches ranging from 400 to 4000 nm (pitch = ridge width + groove width). The planar regions separating each of the six patterned regions served as control surfaces. Primary corneal and SV40-HCEC proliferation decreased in direct response to decreasing nanoscale topographies down to 200 nm. In contrast to corneal epithelial cells, corneal fibroblasts did not exhibit significantly different response to any of the topographies when compared with planar controls at 5 days. However, decreased proliferation was observed on the smallest feature sizes after 14 days in culture. Results from these experiments are relevant in understanding the potential mechanisms involved in the control of proliferation and differentiation of cells within the cornea.     

Characterization of rabbit corneal damage produced by Serratia keratitis and by a serratia protease.

The structural alterations elicited in the rabbit corneal stroma by experimental Serratia marcescens keratitis and by a highly purified serratia protease preparation were compared by gross observation, biochemical analyses, and electron microscopic examination of the affected tissue. Acute inflammation, liquefactive necrosis of the cornea, and descemetocele formation occurred during the development of the infection and after the intracorneal injection of submicrogram amounts of the protease. In vitro incubation of insoluble corneal stromal tissue with the bacterium or with the protease resulted in solubilization of the stromal proteoglycan ground substance; however, specific collagenase activity was not detected. Electron microscopic examination of corneas damaged by the bacterial infection and by the protease revealed loss of ruthenium red staining of the proteoglycan ground substance and dispersal of ultrastructurally normal collagen fibrils. Thus, our findings indicate that the major corneal damage which occurs during serratia keratitis and after the injection of the serratia protease is caused by solubilization and loss of the ground substance of the tissue. In addition, the observation that the major structural alterations observed during serratia keratitis can be reproduced by the bacterial protease supports the idea that the enzyme is involved, at least in part, with the production of severe corneal damage by the bacterium.     

Tissue engineering of corneal stromal layer with dermal fibroblasts: phenotypic and functional switch of differentiated cells in cornea

Previously, we successfully engineered a corneal stromal layer using corneal stromal cells. However, the limited source and proliferation potential of corneal stromal cells has driven us to search for alternative cell sources for corneal stroma engineering. Based on the idea that the tissue-specific environment may alter cell fate, we proposed that dermal fibroblasts could switch their phenotype to that of corneal stromal cells in the corneal environment. Thus, dermal fibroblasts were harvested from newborn rabbits, seeded on biodegradable polyglycolic acid (PGA) scaffolds, cultured in vitro for 1 week, and then implanted into adult rabbit corneas. After 8 weeks of implantation, nearly transparent corneal stroma was formed, with a histological structure similar to that of its native counterpart. The existence of cells that had been retrovirally labeled with green fluorescence protein (GFP) demonstrated the survival of implanted cells. In addition, all GFP-positive cells that survived expressed keratocan, a specific marker for corneal stromal cells, and formed fine collagen fibrils with a highly organized pattern similar to that of native stroma. However, neither dermal fibroblast-PGA construct pre-incubated in vitro for 3 weeks nor chondrocyte-PGA construct could form transparent stroma. The results demonstrated that neonatal dermal fibroblasts could switch their phenotype in the new tissue environment under restricted conditions. The functional restoration of corneal transparency using dermal fibroblasts suggests that they could be an alternative cell source for corneal stroma engineering.     

Corneal reinforcement using an acellular dermal matrix for an analysis of biocompatibility, mechanical properties, and transparency

The aim of this study was to analyze the viability of using an acellular dermal matrix (ADM) as a reinforcement material for peripheral corneal thinning disease. The complete removal of cell components was confirmed by hematoxylin and eosin (H&E) and 4',6-diamidino-2-phenylindole (DAPI) staining. Transmission electron microscopy determined that the stromal structure was well preserved. Uniaxial tests revealed that the ADM had strong mechanical properties. After being implanted into rabbit cornea the ADM showed no sign of rejection and even achieved good transparency 24weeks post-surgery. H&E staining demonstrated that keratocytes grew in the ADM and the ADM-cornea interface became blurry. Picrosirius red staining revealed great changes of collagen in the ADM. Uniaxial testing of the reinforced cornea showed better mechanical strength than the normal rabbit cornea, but this did not exhibit statistical significance. These results suggest that ADM is a worthy candidate for future exploration as a reinforcement material for peripheral corneal thinning problems.     

脱细胞猪角膜表面基底膜成分的检测

背景：前期实验显示脱细胞猪角膜具有良好的组织相容性,可以支持角膜细胞和皮肤上皮细胞的生长。 目的：检测脱细胞猪角膜是否保存了利于角膜上皮细胞生长的重要组织结构—基底膜。 方法：利用荧光抗体对脱细胞猪角膜表面的基底膜成分(层粘蛋白和Ⅳ型胶原)进行免疫组织化学检测,荧光显微镜下观察脱细胞猪角膜表面是否保存了基底膜成分。 结果与结论：免疫荧光染色显示脱细胞猪角膜前基质表面层粘蛋白和Ⅳ型胶原呈阳性表达,与新鲜猪角膜表面基底膜的荧光表达相同,表明脱细胞猪角膜保存了利于角膜上皮细胞生长的基底膜。     

Using acellular porcine limbal stroma for rabbit limbal stem cell microenvironment reconstruction

To investigate the feasibility of using acellular porcine limbal stroma for limbal stem cell microenvironment reconstruction. Limbal reconstruction was performed in rabbit partial limbal defect models. Rabbits were randomly divided into four groups: acellular porcine limbal stroma, de-epithelized rabbit limbal autograft stroma, de-epithelized porcine limbal stroma and acellular porcine corneal stroma transplantation groups. In both the acellular porcine limbal stroma and de-epithelized rabbit limbal autograft stroma groups, cornea transparency and epithelium integrity were sustained and graft rejection was not observed. The basal epithelial cells of the grafts showed the K3+/P63+/Ki67+ phenotype at postoperative month 1, but it returned to K3-/P63+/Ki67+(phenotype characteristic of limbal epithelium) by postoperative months 3 and 6. In the de-epithelized porcine limbal stroma group, acute and serious immune rejection occurred by postoperative days 8-10. The basal epithelial cells of the grafts showed the K3+/P63+/Ki67+ phenotype at postoperative month 1. In the acellular porcine corneal stroma group, there were some new vessel invasion into the peripheral cornea and mild corneal opacity. The basal epithelial cells of the grafts showed the K3+/P63+/Ki67+ phenotype at postoperative months 1, 3, and 6. In conclusion, acellular porcine limbal stroma possessed very low immunogenicity, retained a good original limbal ECM microenvironment, and thus the reconstructed rabbit limbal microenvironment maintained limbal epithelial stem cell stemness and proliferation.     

异种脱细胞角膜基质囊袋移植的生物相容性研究

目的探讨脱细胞猪角膜基质移植入兔角膜囊袋后的生物学反应。方法猪角膜通过不同方式去除细胞及免疫源性成分，保留角膜组织基质的弹力纤维及胶原纤维，将其切取为直径为4mm的植片，植入兔角膜囊袋内，在不同时间点观察生物材料在角膜内生物学反应。结果材料植入兔角膜囊袋3个月，生物相容性良好，材料逐渐降解，材料内有胶原和角膜基质细胞长人。结论新型可降解角膜基质材料植入后未见兔角膜有明显的炎症反应，材料的组织相容性好，可作为组织工程角膜的支架材料。     

Purification of Pseudomonas aeruginosa proteases and microscopic characterization of pseudomonal protease-induced rabbit corneal damage.

Extracellular proteases of three cornea-virulent strains of Pseudomonas aeruginosa were isolated by sequential ammonium sulfate precipitation, Ultrogel AcA 54 gel filtration, and flat-bed isoelectric focusing. The purity of the preparations was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis , thin-layer isoelectric focusing in polyacrylamide gel, immunodiffusion and immunoelectrophoretic procedures, and tests for the presence of other known pseudomonal products. Light and electron microscopic examination of rabbit corneal lesions observed 4 to 6 h after the intracorneal injection of submicrogram amounts of the proteases revealed: (i) degeneration and necrosis of epithelium, endothelium, and keratocytes, (ii) infiltration, degeneration, and necrosis of polymorphonuclear leukocytes, (iii) loss of the characteristic weblike pattern, colloidal iron staining, and ruthenium red staining of the stromal proteoglycan ground substance, (iv) dispersal of strucutrally normal appearing collagen fibrils, ground substance, (iv) dispersal of structurally normal appearing collagen fibrils, and (v) accumulation of plasma proteins and fibrin in the necrotic corneas. These structural alterations are very similar to those observed previously during experimental P. aeruginosa keratitis, and this similarity supports the idea that pseudomonal proteases are responsible, at least in part, for the rapid and extensive liquefaction necrosis characteristic of pseudomonal-induced keratitis. In addition, the results support the idea that pseudomonal proteases elicit severe corneal damage by causing the loss of the corneal proteoglycan ground substance, thus resulting in dispersal of undamaged collagen fibrils, weakening of the corneal stroma, and subsequent descemetocele formation and corneal perforation by the anterior chamber pressure.     

Contact guidance enhances the quality of a tissue engineered corneal stroma

Corneal stroma is a very complex structure, composed of 200 lamellae of oriented collagen fibers. This highly complex nature of cornea is known to be important for its transparency and mechanical integrity. Thus, an artificial cornea design has to take into account this complex structure. In this study, behavior of human corneal keratocytes on collagen films patterned with parallel channels was investigated. Keratocytes proliferated well on films and reached confluency after 7 days in the incubation medium. Nearly all of the cells responded to the patterns and were aligned in contrast to the cells on unpatterned surfaces. Collagen type I and keratan sulfate secreted by keratocytes on patterned films appeared to be aligned in the direction of the patterns. The films showed an intermediate degradation over the course of a month. On the whole, transparency of the films increased with degradation and decreased by the presence of the cells. The decrease was, however, low and transparency level was maintained on the patterned films while on the unpatterned films a sharp decrease in transparency was followed by an improvement. This was due to the more organized distribution of cells and the oriented secretion of extracellular matrix molecules on patterned collagen films. Thus, these results suggest that application of contact guidance in cornea tissue engineering may facilitate the remodeling process, hence decrease the rehabilitation period.     

A quantitative evaluation of Fourier components in transparent and opaque calf cornea

Fourier transform methods were applied to STEM (scanning transmission electron microscopy) images to detect and quantify the subtle differences between the structure of normal transparent calf cornea and opaque calf cornea. In order for a tissue to be transparent, it can scatter or absorb only a small amount of light. Light scattering is minimized when the principal Fourier components of the spatial fluctuations in the index of refraction have wavelengths which are small relative to the wavelength of light (Benedek, 1971). Corneal opacity was produced as a result of high intraocular pressure (100–150 mmHg) when liquid was injected into calf eyes (0–2 weeks old). Pressurization created large structural defects and slight disruptions in the organization of the collagen fibers. Although the fiber organization appeared similar in the micrographs of both opaque and transparent corneas, Fourier analysis of STEM images collected at 50K magnification identified statistically significant differences. Far fewer Fourier components with wavelengths in the light scattering range (200–1100 nm) were observed in the transparent corneas than in the pressurized corneas as predicted by Benedek's theory. It was of interest that corneas treated with 100% glycerol prior to pressurization remained transparent at high intraocular pressures, possibly because glycerol stabilized the structure of the corneas and maintained a uniform index of refraction across the corneal stroma. The results demonstrate the effectiveness of Fourier analysis in detection and quantification of slight changes in structure at the electron microscopic level.