Optimization and evaluation of oxygen-plasma-modified, aligned, poly (Є-caprolactone) and silk fibroin nanofibrous scaffold for corneal stromal regeneration

The shortage of human donor corneas for transplantation necessitates the exploration of tissue engineering approaches to develop corneal substitutes. However, these substitutes must possess the necessary strength, transparency, and ability to regulate cell behaviour before they can be used in patients. In this study, we investigated the effectiveness of an oxygen plasma surface-modified poly-ε-caprolactone (PCL) combined with silk fibroin (SF) nanofibrous scaffold for corneal stromal regeneration. To fabricate the electrospun scaffolds, PCL and SF blends were used on a rotating mandrel. The optimization of the blend aimed to replicate the structural and functional properties of the human cornea, focusing on nanofibre alignment, mechanical characteristics, and in vitro cytocompatibility with human corneal stromal keratocytes. Surface modification of the scaffold resulted in improved transparency and enhanced cell interaction. Based on the evaluation, a composite nanofibrous scaffold with a 1:1 blend of PCL and SF was selected for a more comprehensive analysis. The biological response of keratocytes to the scaffold was assessed through cellular adhesion, proliferation, cytoskeletal organization, gene expression, and immunocytochemical staining. The scaffold facilitated the adhesion of corneal stromal cells, supporting cell proliferation, maintaining normal cytoskeletal organization, and promoting increased expression of genes associated with healthy corneal stromal keratocytes. These findings highlight the potential of a surface-modified PCL/SF blend (1:1) as a promising scaffolding material for corneal stromal regeneration. The developed scaffold not only demonstrated favourable biological interactions with corneal stromal cells but also exhibited characteristics aligned with the requirements for successful corneal tissue engineering. Further research and refinement of these constructs could lead to significant advancements in addressing the shortage of corneas for transplantation, ultimately improving the treatment outcomes for patients in need.

The effect of prior long-term recellularization with keratocytes of decellularized porcine corneas implanted in a rabbit anterior lamellar keratoplasty model

Decellularized porcine corneal scaffolds are a potential alternative to human cornea for keratoplasty. Although clinical trials have reported promising results, there can be corneal haze or scar tissue. Here, we examined if recellularizing the scaffolds with human keratocytes would result in a better outcome. Scaffolds were prepared that retained little DNA (14.89 ± 5.56 ng/mg) and demonstrated a lack of cytotoxicity by in vitro. The scaffolds were recellularized using human corneal stromal cells and cultured for between 14 in serum-supplemented media followed by a further 14 days in either serum free or serum-supplemented media. All groups showed full-depth cell penetration after 14 days. When serum was present, staining for ALDH3A1 remained weak but after serum-free culture, staining was brighter and the keratocytes adopted a native dendritic morphology with an increase (p < 0.05) of keratocan, decorin, lumican and CD34 gene expression. A rabbit anterior lamellar keratoplasty model was used to compare implanting a 250 μm thick decellularized lenticule against one that had been recellularized with human stromal cells after serum-free culture. In both groups, host rabbit epithelium covered the implants, but transparency was not restored after 3 months. Post-mortem histology showed under the epithelium, a less-compact collagen layer, which appeared to be a regenerating zone with some α-SMA staining, indicating fibrotic cells. In the posterior scaffold, ALDH1A1 staining was present in all the acellular scaffold, but in only one of the recellularized lenticules. Since there was little difference between acellular and cell-seeded scaffolds in our in vivo study, future scaffold development should use acellular controls to determine if cells are necessary.

Multilayered Fabrication Assembly Technique to Engineer a Corneal Stromal Equivalent

Tissue engineering has emerged as a strategy to combat the donor shortage of human corneas for transplantation. Synthetic corneal substitutes are currently unable to support the normal phenotype of human cells and so decellularized animal corneas have been deployed to more closely provide the topographical and biochemical cues to promote cell attachment and function. Although full thickness decellularized corneas can support corneal cells, the cells are slow to populate the scaffold and density declines from the surface. To avoid these problems, this protocol describes the stacking of alternate layers of decellularized porcine corneal sheets and cell-laden collagen hydrogel to produce a corneal construct. The sheets are obtained by cryosectioning porcine corneas, decellularizing them with detergents and nucleases and finally air drying for storage and ease of manufacture. Corneal stromal cells are then encapsulated in a collagen type I solution and cast between these sheets. This protocol presents a rapid method to ensure high cellularity throughout the construct using tissue-derived materials alone. Graphic abstract: Overview of main process to obtain corneal stromal equivalents.

Silk fibroin safety in the eye: a review that highlights a concern

The biomedical use of silk as a suture dates back to antiquity. Fibroin is the structural element that determines the strength of silk and here we consider the safety of fibroin in its role in ophthalmology. The high mechanical strength of silk meant sufficiently thin threads could be made for eye microsurgery, but such usage was all but superseded by synthetic polymer sutures, primarily because silk in its entirety was more inflammatory. Significant immunological response can normally be avoided by careful manufacturing to provide high purity fibroin, and it has been utilised in this form for tissue engineering an array of fibre and film substrata deployed in research with cells of the eye. Films of fibroin can also be made transparent, which is a required property in the visual pathway. Transparent layers of corneal epithelial, stromal and endothelial cells have all been demonstrated with maintenance of phenotype, as have constructs supporting retinal cells. Fibroin has a lack of demonstrable infectious agent transfer, an ability to be sterilised and prepared with minimal contamination, long-term predictable degradation and low direct cytotoxicity. However, there remains a known ability to be involved in amyloid formation and potential amyloidosis which, without further examination, is enough to currently question whether fibroin should be employed in the eye given its innervation into the brain.

Engineering a Corneal Stromal Equivalent Using a Novel Multilayered Fabrication Assembly Technique

To overcome the serious shortage of donor corneas for transplantation, alternatives based on tissue engineering need to be developed. Decellularized corneas are one potential alternative, but their densely packed collagen architecture inhibits recellularization in vitro. Therefore, a new rapid method of recellularizing these constructs to ensure high cellularity throughout the collagen scaffold is needed. In this study, we developed a novel method for fabricating corneal constructs by using decellularized porcine corneal sheets assembled using a bottom-up approach by layering multiple sheets between cell-laden collagen I hydrogel.

Corneal lenticules were cut from porcine corneas by cryosectioning, then decellularized with detergents and air-dried for storage as sheets. Human corneal stromal cells were encapsulated in collagen I hydrogel and cast between the dried sheets. Constructs were cultured in serum-free medium supplemented with ascorbic acid and insulin for 2 weeks. Epithelial cells were then seeded on the surface and cultured for an additional week. Transparency, cell viability, and phenotype were analyzed by qPCR, histology, and immunofluorescence. Constructs without epithelial cells were sutured onto an ex vivo porcine cornea and cultured for 1 week.

Lenticules were successfully decellularized, achieving dsDNA values of 13 ± 1.2 ng/mg dry tissue, and were more resistant to degradation than the collagen I hydrogels. Constructs maintained high cell viability with a keratocyte-like phenotype with upregulation of keratocan, decorin, lumican, collagen I, ALDH3A1, and CD34 and the corneal epithelial cells stratified with a cobblestone morphology. The construct was amenable to surgical handling and no tearing occurred during suturing. After 7 days ex vivo, constructs were covered by a neoepithelium from the host porcine cells and integration into the host stroma was observed.

This study describes a novel approach toward fabricating anterior corneal substitutes in a simple and rapid manner, obtaining mature and suturable constructs using only tissue-derived materials.

Deformation velocity imaging using optical coherence tomography and its applications to the cornea

Optical coherence tomography (OCT) can monitor human donor corneas non-invasively during the de-swelling process following storage for corneal transplantation, but currently only resultant thickness as a function of time is extracted. To visualize and quantify the mechanism of de-swelling, we present a method exploiting the nanometer sensitivity of the Fourier phase in OCT data to image deformation velocities. The technique was demonstrated by non-invasively showing during de-swelling that osmotic flow through an intact epithelium is negligible and removing the endothelium approximately doubled the initial flow at that interface. The increased functional data further enabled the validation of a mathematical model of the cornea. Included is an efficient method of measuring high temporal resolution (1 minute demonstrated) corneal thickness, using automated collection and semi-automated graph search segmentation. These methods expand OCT capabilities to measure volume change processes for tissues and materials.

Evaluation of Eph receptor and ephrin expression within the human cornea and limbus

Eph receptor tyrosine kinases and their ligands, the ephrins, regulate the development and maintenance of multiple organs but little is known about their potential role within the cornea. The purpose of this study was to perform a thorough investigation of Eph/ephrin expression within the human cornea including the limbal stem cell niche. Initially, immunohistochemistry was performed on human donor eyes to determine the spatial distribution of Eph receptors and ephrins in the cornea and limbus. Patterns of Eph/ephrin gene expression in (1) immortalised human corneal endothelial (B4G12) or corneal epithelial (HCE-T) cell lines, and (2) primary cultures of epithelial or stromal cells established from the corneal limbus of cadaveric eye tissue were then assessed by reverse transcription (RT) PCR. Limbal epithelial or stromal cells from primary cultures were also assessed for evidence of Eph/ephrin-reactivity by immunofluorescence. Immunoreactivity for ephrinA1 and EphB4 was detected in the corneal endothelium of donor eyes. EphB4 was also consistently detected in the limbal and corneal epithelium and in cells located in the stroma of the peripheral cornea. Expression of multiple Eph/ephrin genes was detected in immortalised corneal epithelial and endothelial cell lines. Evidence of Eph/ephrin gene expression was also demonstrated in primary cultures of human limbal stromal (EphB4, B6; ephrinA5) and epithelial cells (EphA1, A2; ephrinA5, B2) using both RT-PCR and immunofluorescence. The expression of Eph receptors and ephrins within the human cornea and limbus is much wider than previously appreciated and suggests multiple potential roles for these molecules in the maintenance of normal corneal architecture.

Structural and kinetic characterization of myoglobins from eurythermal and stenothermal fish species

Teleost myoglobin (Mb) proteins from four fish species inhabiting different temperature environments were used to investigate the relationship between protein function and thermal stability. Mb was isolated from yellowfin tuna (homeothermal warm), mackerel (eurythermal warm), and the Antarctic teleost Notothenia coriiceps (stenothermal cold). Zebrafish (stenothermal tropical) myoglobin was expressed from cloned cDNA. These proteins differed in oxygen affinity, as measured by O2 dissociation rates and P50 values, and thermal stability as measured by autooxidation rates. Mackerel Mb had the highest P50 value at 25 degrees C (3.7 mmHg), corresponding to the lowest O2 affinity, followed by zebrafish (1.0 mmHg), yellowfin tuna (1.0 mmHg), and N. coriiceps (0.6 mmHg). Oxygen dissociation rates and Arrhenius plots were similar between all teleost species in this study, with the exception of mackerel myoglobin, which was two-fold faster at all temperatures tested. Myoglobin from the Antarctic teleost had the highest autooxidation rate (0.44 h(-1)), followed by mackerel (0.26 h(-1)), zebrafish (0.22 h(-1)), and yellowfin tuna (0.088 h(-1)). Primary structural analysis revealed residue differences distributed throughout the polypeptide sequences, making it difficult to identify, which, if any, residues contribute to structural flexibility. However, analysis of molecular dynamics trajectories indicates that Mb from the eurythermal mackerel is predicted to be the most flexible protein within the D loop and FG turn. At the same time, it has the lowest O2 affinity and the highest O2 dissociation rates when compared to myoglobins from teleosts that appear to be less flexible in our dynamics simulations.

Amalgam-reinforced stainless steel crown for restoration of permanent molars

This article presents a technique utilizing a stainless steel crown to fabricate a semipermanent provisional restoration of a permanent molar where a diminished risk of occlusal perforation is desired.

The effect of polyvinylpyrrolidone and the cooling rate during corneal cryopreservation

The effect upon endothelial cell survival of (a) PVP and (b) the cooling rate was investigated during the cryopreservation of rabbit corneas with 3 mol/liter dimethyl sulfoxide (Me2SO) dissolved in a hyperkalemic buffer vehicle solution that we designated CPTES; this solution was designed specifically to restrict deleterious ionic imbalances and cell swelling during hypothermic procedures. Polyvinylpyrrolidone (PVP) was used as the colloid and the corneas were cooled at 0.03, 0.1, 1, 25, or 125 degrees C/min, using the minimum amount of extracellular solution. Electron microscopy as well as staining with fluorescein diacetate and ethidium bromide (FDA/EB) was used to assess cellular integrity. To reduce osmotic stress, steps for the serial equilibration of the cryoprotectant additives (CPAs) were based upon calculations that predict endothelial volume during CPA exchange. A toxicity study showed that at 0 degrees C all the CPA equilibration protocols were well tolerated; for example, FDA/EB staining indicated that 97% intact cells were retained following direct transfer to 3 mol/liter Me2SO in CPTES to which 40% w/v PVP had been added as an osmotic buffer. However, less than 20% of cells were intact by FDA/EB staining with all corneas frozen at rates > 1 degree C/min regardless of which equilibration protocol was employed, nor were there any intact cells when 3 mol/liter Me2SO in CPTES was used alone at the lowest cooling rate. At intermediate cooling rates viability was improved: the highest mean survival of 81% was obtained using 3 mol/liter Me2SO in CPTES plus 40% PVP. Electron microscopy showed that detachment of the endothelial layer often occurred, but least damage was evident following exposure to 3 mol/liter Me2SO in CPTES plus 40% PVP and cooling at 1 degree C/min. No thawed cornea could maintain normal control of hydration immediately upon return to isotonic medium. The results show that, with these cryopreservation protocols, loss of cell integrity occurs at cooling rates greater than 1 degree C/min, whereas at lower rates higher survival of individual cells was achieved, but cellular adhesion to the basement membrane was impaired.

Hypothermic preservation of corneas in a hyperkalaemic solution (CPTES): II. Extended storage in the presence of chondroitin sulphate

Periods of preservation for donor corneas, even for short times, are necessary to facilitate optimum conditions in penetrating keratoplasty. However, current techniques for corneal storage at low temperatures may not provide optimal conditions for maintaining tissue integrity. In particular, the ionic composition of the storage medium has received little attention since it has been assumed throughout that the normal complement of ions in tissue culture media will also be suitable for preservation at reduced temperatures. This study extends our previous investigations on the merits of using CPTES (corneal-potassium-TES), a potassium-rich balanced salt solution containing an impermeant anionic pH buffer (TES), as a storage solution specifically designed to prevent the loss of intracellular potassium and minimise endothelial cell swelling during the time that the normal regulatory processes are switched off. The effect of adding the natural polymer chondroitin sulphate (CS) as a colloid osmotic agent to the hyperkalaemic storage medium is now examined. Corneas stored in CPTES containing 2.5% chondroitin sulphate retained a very high level of structural and functional integrity after three, five, and seven days storage at 0 degrees C; furthermore, stromal swelling was restricted to only 21%. All corneas stored in CPTES + 2.5% CS showed active endothelial function by thinning efficiently at rates that were greater than those previously reported for rabbit corneas stored for similar lengths of time in either M-K medium or K-sol. The zwitterionic buffers TES and HEPES were interchangeable in the hyperkalaemic solution and were non-toxic to corneal endothelium at a concentration of 100 mM. These compounds offer excellent pH buffering in bicarbonate-free medium.

The extent of immunological privilege of orthotopic corneal grafts in the inbred rat

Corneal grafts are believed to enjoy a degree of "immunological privilege" primarily due to the avascularity of the recipient bed. In this study orthotopic full-thickness corneal grafts were carried out in the inbred rat, using a technique that is a close model of corneal grafting in humans. The survival times of corneal grafts on nonvascularized beds of 28 fully allogeneic strain combinations were determined without the use of immunosuppression. Some combinations were rejected rapidly, e.g. DA (RT1a) into BN (RT1n) with a mean survival time (MST) +/- SD of 7.8 +/- 1.3 days, and some at a moderate rate, e.g. AO (RT1u) into LEW (RT1l) with an MST of 23.1 +/- 10.0 days, whereas in other cases survival was indefinite, e.g. WAG (RT1u) into PVG (RT1c), an MST of greater than 100 days. Orthotopic corneal grafts on nonvascularized beds between DA and AO parents and the F1, followed the basic rules of transplantation genetics. In addition, the rate of graft rejection was significantly faster (P less than 0.001) with corneal grafts from DA into AO placed onto a vascularized compared with a nonvascularized corneal bed (MST of 6.8 +/- 2.4 or 12.1 +/- 4.0 days respectively). The rate of rejection of corneas on a vascularized bed was at a similar rate to that of orthotopic skin or heterotopic auxiliary heart grafts. The results indicate that the fate of a corneal allograft on a nonvascularized bed is dependent upon the particular combination of donor and recipient strain. No consistent association was observed between any donor or recipient RT1 haplotype and survival; this suggests that non-RT1 background genes may play a role in the survival of corneal grafts.

The assessment of endothelial integrity by scanning electron microscopy and fluorescein diacetate staining following treatment with cryoprotective additives

As part of the development of methods of corneal cryostorage for transplantation, a toxicity study was carried out on the rabbit corneal endothelium using four cryoprotective additives (CPA's) 1) dimethyl sulphoxide (Me2SO), 2) propane-1,2-diol (PG), 3) glycerol (GLY), 4) polyvinylpyrrolidone (PVP). A fifth group, based upon a CPA combination of Me2SO and PVP, was used to characterize both the assays, and the response of the endothelial layer to osmotic stress. The effect upon the cell membrane was assessed using scanning electron microscopy (SEM) and fluorescein diacetate with ethidium bromide staining (FDA/EB). Two sampling points were used, one immediately after treatment and the other following an incubation period. Calculations were performed to predict the maximum relative volume of cells during CPA exchange. Immediately following serial addition and removal of 2 or 3 mol/L (M) PG or GLY, the cells exhibited adverse morphological changes shown with SEM, and the proportion of intact cells judged by FDA/EB staining was significantly reduced when CPA equilibration was performed at 37 degrees C rather than at 20 degrees C. A 3M Me2SO concentration gave less morphological change than 3M PG or GLY, but even after treatment with 4M Me2SO more than 95% cells were judged intact by FDA/EB staining. PVP at 40% w/v showed minimal damage with both assays, and the fifth experimental group suggested that PVP may protect from injury during hypotonic stress. With all groups, the integrity of the cell layer recovered during incubation, so that for each sample the percentage of intact cells was high. However, although confluency was often restored following incubation, total cell density was usually reduced. The results indicate that serial addition and removal of 3M Me2SO is tolerated by the cornea, whereas PG or GLY cannot be used at 2 or 3M without inducing osmotic damage. There was low toxicity to PVP, and it was an effective osmotic buffer.

The evaluation of endothelial damage following corneal storage: a comparison of staining methods and the value of scanning electron microscopy

Staining techniques and scanning electron microscopy (SEM) were used to assess damage to the endothelial cells following corneal storage. The aim was to establish whether these assays are useful in the assessment of endothelial integrity following corneal storage. Four groups ensured a range of normal and damaged endothelial cells: 1) fresh; 2) stored for 7 days in a moist chamber; 3) stored by the cryopreservation method of Capella and Kaufman; 4) damaged by rapid freezing with a cryoprobe. Trypan blue (TB), nitroblue tetrazolium (NBT), acridine orange (AO), fluorescein diacetate (FDA) and ethidium bromide (EB), were used to stain the endothelial layer. SEM was carried out on duplicate samples. Staining with NBT resulted in low cell counts due to loss of cells. There was no significant difference between the extent of damage measured by TB, AO or FDA, but it was shown that staining with FDA and EB can distinguish between damaged and intact cells. Tissue stored for 7 days in a moist chamber had a reduced number of intact cells compared to fresh tissue, and tissue stored by the Capella and Kaufman technique gave a reduced number of intact cells compared to both these control and storage groups. SEM showed surface perforation was characteristic of injured cells, rather than complete disruption. FDA has a theoretical advantage over the other stains, and should provide a more accurate appraisal of defects of cell membrane integrity. For this reason, the use of FDA with EB to stain the endothelium, with SEM carried out on duplicate samples, were preferred as assays to use in the development of corneal storage.

Assessment and interpretation of corneal endothelial cell morphology and function following cryopreservation

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