Lens Regeneration Research Articles

Biologically Relevant Laminin-511 Moderates the Derivation and Proliferation of Human Lens Epithelial Stem/Progenitor-Like Cells.

The role of specific extracellular matrix (ECM) molecules in lens cell development and regeneration is poorly understood, as appropriate cellular models are lacking. Here, a laminin-based lens cell in vitro induction system was developed to study the role of laminin in human lens epithelial stem/progenitor cell (LES/PC) development. The human embryonic stem cell-based lens induction system followed a three-stage protocol. The expression profile of laminins during lens induction was screened, and laminin-511 (LN511) was tested as a candidate substitute. LN511 induction system cellular and molecular features, including induction efficiency, transcription factor expression related to different lens development stages, ECM alterations, and Hippo/YAP signaling, were evaluated. LAMA5, LAMB1, and LAMC1 were highly expressed around the time of LES/PC derivation. We chose LN511 (product of LAMA5, LAMB1, and LAMC1) and found that it considerably enhanced lens cell induction efficiency, compared to that in Matrigel-coated culture, as more and larger lentoid bodies were detected. Notably, LES/PC induction efficiency improved by promoting lens specification-related transcription factor expression and cell proliferation. Transcriptome analysis revealed that compared to those with Matrigel, ECM accumulation and cell adhesion were downregulated in the LN511 system. Hippo/YAP signaling was hypoactive during LES/P-like cell generation, and small molecule inhibitors of YAP/TAZ activity upregulated LES/PC marker expression and promoted the efficiency of LES/P-like cell derivation. The laminin isoform LN511 is a reliable substitute for the LES/P-like cell induction system, and LN511-YAP acted as efficient modulators of LES/PC derivation; this contributes to knowledge of the role of the ECM in human lens development.

Macrophages modulate fibrosis during newt lens regeneration

BackgroundPrevious studies have suggested that macrophages are present during lens regeneration in newts, but their role in the process is yet to be elucidated.MethodsHere we generated a transgenic reporter line using the newt, Pleurodeles waltl, that traces macrophages during lens regeneration. Furthermore, we assessed early changes in gene expression during lens regeneration using two newt species, Notophthalmus viridescens and Pleurodeles waltl. Finally, we used clodronate liposomes to deplete macrophages during lens regeneration in both species and tested the effect of a subsequent secondary injury after macrophage recovery.ResultsMacrophage depletion abrogated lens regeneration, induced the formation of scar-like tissue, led to inflammation, decreased iris pigment epithelial cell (iPEC) proliferation, and increased rates of apoptosis in the eye. Some of these phenotypes persisted throughout the last observation period of 100 days and could be attenuated by exogenous FGF2 administration. A distinct transcript profile encoding acute inflammatory effectors was established for the dorsal iris. Reinjury of the newt eye alleviated the effects of macrophage depletion, including the resolution of scar-like tissue, and re-initiated the regeneration process.ConclusionsTogether, our findings highlight the importance of macrophages for facilitating a pro-regenerative environment in the newt eye by regulating fibrotic responses, modulating the overall inflammatory landscape, and maintaining the proper balance of early proliferation and late apoptosis of the iPECs.

Synchrotron‐based Fourier transform infrared microspectroscopy examined differences between the cultured and post‐operative human lens epithelial cells important for understanding posterior capsular opacification and lens regeneration

Aims/Purpose: To compare the bio‐macromolecular composition and the differences between the human cultured and post‐operative lens epithelial cells (LECs) on lens capsules (LCs) for a better understanding of posterior capsular opacification (PCO)—the most common complication of cataract surgery, and lens regeneration.Methods: The explants of the anterior portion of the LC containing the LECs, obtained from cataract surgery and cultivated under adherent conditions, as well as the post‐operative LC with LECs, were analysed by using synchrotron radiation‐based Fourier transform infrared (SR‐FTIR) microspectroscopy, a vibrational spectroscopic technique that allows monitoring of the entire biochemical status of the biological processes. The SR‐FTIR microspectroscopy setup installed on the beamline MIRAS at the Spanish synchrotron light source ALBA was used, where measurements were set to achieve single‐cell resolution, with high spectral stability and high photon flux.Results: We found that the differences exist between the composites of cultured and post‐operative LECs on LCs on the level of all chemical constituents: proteins, lipids, nucleic acids and carbohydrates as well as oxidative stress. The strongest differences are found in protein secondary structure contribution where the composite of primary LECs cultures on LC have more α‐helix (1652 cm−1) and post‐operative LC have more β‐sheet (1624 cm−1 and 1697 cm−1) secondary structures. The oxidative stress is more expressed in the composite of primary LECs cultures on LC and relatively less in the composite of post‐operative lens epithelium LECs on LC.Conclusions: Our results obtained by SR‐FTIR increase the knowledge about the total proteins, lipids, and nucleic acids in human primary cultures LECs while offering also evidence that SR‐FTIR is sensitive to the pathologic processes of LECs transdifferentiation. We showed that the composite of primary cultures LECs on LC have a distinct bio‐macromolecular composition compared to the composite of post‐operative LECs on LC, which gives additional information for a better understanding of PCO and lens regeneration.

Organ Regeneration Without Relying on Regeneration-Dedicated Stem Cells.

The classic conception of tissue regeneration assumed the existence of tissue-proper regeneration stem cells that are set aside during normal tissue development and reserved as stem cells for regeneration. However, modern studies using cell tracing and other approaches have ruled out the presence of regeneration-proper stem cells in most cases in vertebrate tissue regeneration. The only experimentally validated regeneration-dedicated reserve cells are the satellite cells in skeletal muscle (e.g., Michele 2022) (see Sect. 5.2.3 ). Here, we will first discuss examples of large-scale tissue regeneration, liver regeneration in mammals, and lens and limb regeneration in newts. Then, attempts to widen the tissue regeneration capacity in mammals with exogenous transcription factor genes will be reviewed.

Lens regeneration in situ using hESCs-derived cells —similar to natural lens

Lens itself has limited regeneration functionality, thus we aimed to create regenerated lens with biological function to treat cataracts rather than the intraocular lens used in cataract surgery. We induced exogenous human embryonic stem cells to directionally differentiate into lens fate like cells invitro, mixed these cells with hyaluronate, and then implanted the mixture into lens capsule to regenerate invivo. We successfully achieved near-complete lens regeneration, and the thickness of the regenerated lens reached 85% of the contralateral eye, showing the characteristics of biconvex shape, transparency, and a thickness and diopter close to that of natural lenses. Meanwhile, the participation of Wnt/PCP pathway in lens regeneration was verified. The regenerated lens in this study was the most transparent, thickest, and most similar to the original natural lens that has thus far been reported. Overall, these findings offer a new therapeutic strategy for cataracts and other lens diseases.

Characterizing the lens regeneration process in Pleurodeles waltl

BackgroundAging and regeneration are heavily linked processes. While it is generally accepted that regenerative capacity declines with age, some vertebrates, such as newts, can bypass the deleterious effects of aging and successfully regenerate a lens throughout their lifetime. ResultsHere, we used Spectral-Domain Optical Coherence Tomography (SD-OCT) to monitor the lens regeneration process of larvae, juvenile, and adult newts. While all three life stages were able to regenerate a lens through transdifferentiation of the dorsal iris pigment epithelial cells (iPECs), an age-related change in the kinetics of the regeneration process was observed. Consistent with these findings, iPECs from older animals exhibited a delay in cell cycle re-entry. Furthermore, it was observed that clearance of the extracellular matrix (ECM) was delayed in older organisms. ConclusionsCollectively, our results suggest that although lens regeneration capacity does not decline throughout the lifespan of newts, the intrinsic and extrinsic cellular changes associated with aging alter the kinetics of this process. By understanding how these changes affect lens regeneration in newts, we can gain important insights for restoring the age-related regeneration decline observed in most vertebrates.

Extracellular HSP90 promotes differentiation of lens epithelial cells to fiber cells by activating LRP1-YAP-PROX1 axis.

Capsular residual lens epithelial cells (CRLEC) undergo differentiation to fiber cells for lens regeneration or tansdifferentiation to myofibroblasts leading to posterior capsular opacification (PCO) after cataract surgery. The underlying regulatory mechanism remains unclear. Using human lens epithelial cell lines and the ex vivo cultured rat lens capsular bag model, we found that the lens epithelial cells secrete HSP90α extracellularly (eHSP90) through an autophagy-associated pathway. Administration of recombinant GST-HSP90α protein or its M-domain induces the elongation of rat CRLEC cells with concomitant upregulation of the crucial fiber cell transcriptional factor PROX1and its downstream targets, β- and γ-crystallins and structure proteins. This regulation is abolished by PROX1 siRNA. GST-HSP90α upregulates PROX1 by binding to LRP1 and activating LRP1-AKT mediated YAP degradation. The upregulation of GST-HSP90α on PROX1 expression and CRLEC cell elongation is inhibited by LRP1 and AKT inhibitors, but activated by YAP-1 inhibitor (VP). These data demonstrated that the capsular residue epithelial cells upregulate and secrete eHSP90α, which in turn drive the differentiation of lens epithelial cell to fiber cells. The recombinant HSP90α protein is a potential novel differentiation regulator during lens regeneration.

The lens epithelium as a major determinant in the development, maintenance, and regeneration of the crystalline lens.

The crystalline lens is a transparent and refractive biconvex structure formed by lens epithelial cells (LECs) and lens fibers. Lens opacity, also known as cataracts, is the leading cause of blindness in the world. LECs are the principal cells of lens throughout human life, exhibiting different physiological properties and functions. During the embryonic stage, LECs proliferate and differentiate into lens fibers, which form the crystalline lens. Genetics and environment are vital factors that influence normal lens development. During maturation, LECs help maintain lens homeostasis through material transport, synthesis and metabolism as well as mitosis and proliferation. If disturbed, this will result in loss of lens transparency. After cataract surgery, the repair potential of LECs is activated and the structure and transparency of the regenerative tissue depends on postoperative microenvironment. This review summarizes recent research advances on the role of LECs in lens development, homeostasis, and regeneration, with a particular focus on the role of cholesterol synthesis (eg., lanosterol synthase) in lens development and homeostasis maintenance, and how the regenerative potential of LECs can be harnessed to develop surgical strategies and improve the outcomes of cataract surgery (Fig. 1). These new insights suggest that LECs are a major determinant of the physiological and pathological state of the lens. Further studies on their molecular biology will offer possibility to explore new approaches for cataract prevention and treatment.

In Vivo and Ex Vivo View of Newt Lens Regeneration.

Lens regeneration in the adult newt illustrates a unique example of naturally occurring cell transdifferentiation. During this process, iris pigmented epithelial cells (iPECs) reprogram into a lens, a tissue that is derived from a different embryonic source. Several methodologies both in vivo and in culture have been utilized over the years to observe this phenomenon. Most recently, Optical Coherence Tomography (OCT) has been identified as an effective tool to study the lens regeneration process in continuity through noninvasive, real-time imaging of the same animal. Described in this chapter are three different methodologies that can be used to observe the newt lens regeneration process both in vivo and ex vivo.

Formation of three-dimensional cell aggregates expressing lens-specific proteins in various cultures of human iris-derived tissue cells and iPS cells.

Induced pluripotent stem (iPS) cells are widely used as a research tool in regenerative medicine and embryology. In studies related to lens regeneration in the eye, iPS cells have been reported to differentiate into lens epithelial cells (LECs); however, to the best of our knowledge, no study to date has described their formation of three-dimensional cell aggregates. Notably, in vivo studies in newts have revealed that iris cells in the eye can dedifferentiate into LECs and regenerate a new lens. Thus, as basic research on lens regeneration, the present study investigated the differentiation of human iris tissue-derived cells and human iris tissue-derived iPS cells into LECs and their formation of three-dimensional cell aggregates using a combination of two-dimensional culture, static suspension culture and rotational suspension culture. The results revealed that three-dimensional cell aggregates were formed and differentiated into LECs expressing αA-crystallin, a specific marker protein for LECs, suggesting that the cell-cell interaction facilitated by cell aggregation may have a critical role in enabling highly efficient differentiation of LECs. However, the present study was unable to achieve transparency in the cell aggregates; therefore, we aim to continue to investigate the degradation of organelles and other materials necessary to make the interior of the formed cell aggregates transparent. Furthermore, we aim to expand on our current work to study the regeneration of the lens and ciliary body as a whole in vitro, with the aim of being able to restore focusing function after cataract surgery.

The miRNA-34a/Sirt1/p53 pathway in a rat model of lens regeneration.

BackgroundThere are many molecular factors involved in Wolffian and corneal lens regeneration, but few in lens regeneration by lens epithelial cells (LECs) in mammals. Silent information regulator 1 (Sirt1) has a variety of physiological functions, such as a transport hub, and is involved in pathological conditions. We studied the expression of the microRNA (miRNA)-34a/Sirt1/tumor protein p53 (p53) pathway in a rat model of lens regeneration.MethodsWe performed extracapsular lens extraction in 42 healthy female Sprague-Dawley rats. Slit lamp observation was performed at 3, 7, 14, 21, 30, 60 and 90 days postoperatively, and the rats were killed humanely by cervical dislocation at 30, 60 and 90 days postoperatively to remove the eyeballs. We performed semiquantitative immunofluorescence analysis of Sirt1, p53, alpha-smooth muscle actin (α-SMA) and fibronectin (fn), and real-time fluorescence quantitative polymerase chain reaction (RT-qPCR) to detect the relative expressions of miRNA-34a, Sirt1, p53, aquaporin 0 (AQP 0), γA-crystallin, and beaded filament structural protein 1 (BFSP1) mRNA in the lens and posterior capsule.ResultsThe posterior capsule wrinkled at 3 days and it increased at 7 days. At 14 days, pearl-like opacification appeared under the capsule, with increasing shrinkage. Greater mass-like proliferators in size and number accumulated under the capsule and at the equator after 21 days. A regenerated lens developed in the central depression of the capsule at 30 days, slightly protruding from it. Despite being thickened at 60 days, the central depression persisted, with a smaller change at 90 days than at 60 days. Although the relative mRNA expression of miRNA-34a and p53 in the lens and posterior capsule decreased over time (P=0.000), that of Sirt1 increased (P<0.01). α-SMA was uniformly expressed in the crystals and gradually decreased, while fn expression gradually increased.ConclusionsmiRNA-34a expression decreased and Sirt1 expression increased during lens regeneration. Furthermore, p53 expression decreased, thus reducing apoptosis. Therefore, Sirt1 acted as a key factor in the pathway, and played a protective role in lens regeneration.

Nicotinamide improves in vitro lens regeneration in a mouse capsular bag model

BackgroundMammalian lens regeneration holds great potential as a cataract therapy. However, the mechanism of mammalian lens regeneration is unclear, and the methods for optimization remain in question.MethodsWe developed an in vitro lens regeneration model using mouse capsular bag culture and improved the transparency of the regenerated lens using nicotinamide (NAM). We used D4476 and SSTC3 as a casein kinase 1A inhibitor and agonist, respectively. The expression of lens-specific markers was examined by real-time PCR, immunostaining, and western blotting. The structure of the in vitro regenerated lens was investigated using 3,3′-dihexyloxacarbocyanine iodide (DiOC6) and methylene blue staining, terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL), and transmission electron microscopy.ResultsThe in vitro lens regeneration model was developed to mimic the process of in vivo mammalian lens regeneration in a mouse capsular bag culture. In the early stage, the remanent lens epithelial cells proliferated across the posterior capsule and differentiated into lens fiber cells (LFCs). The regenerated lenses appeared opaque after 28 days; however, NAM treatment effectively maintained the transparency of the regenerated lens. We demonstrated that NAM maintained lens epithelial cell survival, promoted the differentiation and regular cellular arrangement of LFCs, and reduced lens-related cell apoptosis. Mechanistically, NAM enhanced the differentiation and transparency of regenerative lenses partly by inhibiting casein kinase 1A activity.ConclusionThis study provides a new in vitro model for regeneration study and demonstrates the potential of NAM in in vitro mammalian lens regeneration.

Pigment Epithelia of the Eye: Cell-Type Conversion in Regeneration and Disease.

Pigment epithelial cells (PECs) of the retina (RPE), ciliary body, and iris (IPE) are capable of altering their phenotype. The main pathway of phenotypic switching of eye PECs in vertebrates and humans in vivo and/or in vitro is neural/retinal. Besides, cells of amphibian IPE give rise to the lens and its derivatives, while mammalian and human RPE can be converted along the mesenchymal pathway. The PECs’ capability of conversion in vivo underlies the lens and retinal regeneration in lower vertebrates and retinal diseases such as proliferative vitreoretinopathy and fibrosis in mammals and humans. The present review considers these processes studied in vitro and in vivo in animal models and in humans. The molecular basis of conversion strategies in PECs is elucidated. Being predetermined onto- and phylogenetically, it includes a species-specific molecular context, differential expression of transcription factors, signaling pathways, and epigenomic changes. The accumulated knowledge regarding the mechanisms of PECs phenotypic switching allows the development of approaches to specified conversion for many purposes: obtaining cells for transplantation, creating conditions to stimulate natural regeneration of the retina and the lens, blocking undesirable conversions associated with eye pathology, and finding molecular markers of pathology to be targets of therapy.

The importance of the epithelial fibre cell interface to lens regeneration in an in vivo rat model and in a human bag-in-the-lens (BiL) sample

Human lens regeneration and the Bag-in-the-Lens (BIL) surgical treatment for cataract both depend upon lens capsule closure for their success. Our studies suggest that the first three days after surgery are critical to their long-term outcomes. Using a rat model of lens regeneration, we evidenced lens epithelial cell (LEC) proliferation increased some 50 fold in the first day before rapidly declining to rates observed in the germinative zone of the contra-lateral, un-operated lens. Cell multi-layering at the lens equator occurred on days 1 and 2, but then reorganised into two discrete layers by day 3. E- and N-cadherin expression preceded cell polarity being re-established during the first week. Aquaporin 0 (AQP0) was first detected in the elongated cells at the lens equator at day 7. Cells at the capsulotomy site, however, behaved very differently expressing the epithelial mesenchymal transition (EMT) markers fibronectin and alpha-smooth muscle actin (SMA) from day 3 onwards. The physical interaction between the apical surfaces of the anterior and posterior LECs from day 3 after surgery preceded cell elongation. In the human BIL sample fibre cell formation was confirmed by both histological and proteome analyses, but the cellular response is less ordered and variable culminating in Soemmerring's ring (SR) formation and sometimes Elschnig's pearls. This we evidence for lenses from a single patient. No bow region or recognisable epithelial-fibre cell interface (EFI) was evident and consequently the fibre cells were disorganised. We conclude that lens cells require spatial and cellular cues to initiate, sustain and produce an optically functional tissue in addition to capsule integrity and the EFI.

Insights into Bone Morphogenetic Protein-(BMP-) Signaling in Ocular Lens Biology and Pathology.

Bone morphogenetic proteins (BMPs) are a diverse class of growth factors that belong to the transforming growth factor-beta (TGFβ) superfamily. Although originally discovered to possess osteogenic properties, BMPs have since been identified as critical regulators of many biological processes, including cell-fate determination, cell proliferation, differentiation and morphogenesis, throughout the body. In the ocular lens, BMPs are important in orchestrating fundamental developmental processes such as induction of lens morphogenesis, and specialized differentiation of its fiber cells. Moreover, BMPs have been reported to facilitate regeneration of the lens, as well as abrogate pathological processes such as TGFβ-induced epithelial-mesenchymal transition (EMT) and apoptosis. In this review, we summarize recent insights in this topic and discuss the complexities of BMP-signaling including the role of individual BMP ligands, receptors, extracellular antagonists and cross-talk between canonical and non-canonical BMP-signaling cascades in the lens. By understanding the molecular mechanisms underlying BMP activity, we can advance their potential therapeutic role in cataract prevention and lens regeneration.

Current researches and prospects of human induced pluripotent stem cells and gene editing technology of CRISPR/Cas9 in inherited ocular diseases

Human induced pluripotent stem cells have the ability to differentiate into specific cell types or tissues of the eye in humans and have application prospects in retinal cell transplantation, corneal transplantation, and lens regeneration. Gene editing technology of clustered regularly interspaced short palindromic repeats/crispr-associated protein-9 nuclease (CRISPR/Cas9) can introduce causative mutations of inherited ocular diseases into human induced pluripotent stem cells effectively. Then they can be further differentiated into specific somatic cells maintaining a genetic disease background, which can mimic the occurrence of inherited ocular diseases in vitro. The cell model may help scientists study the mechanism of human disease development, establish an in vitro screening platform to find therapeutic drugs, and correct genetic mutations in the human genome for cell therapy. The combination of stem cells and gene editing technology is revolutionizing the regenerative medicine in ophthalmology and gene therapy of inherited ocular diseases. This review summarizes the current application of human induced pluripotent stem cells and its combination with gene editing technology in the study of inherited ocular diseases. (Chin J Ophthalmol, 2021, 57: 712-716).

In Vivo Imaging of Newt Lens Regeneration: Novel Insights Into the Regeneration Process.

PurposeTo establish optical coherence tomography (OCT) as an in vivo imaging modality for investigating the process of newt lens regeneration.MethodsSpectral-domain OCT was employed for in vivo imaging of the newt lens regeneration process. A total of 37 newts were lentectomized and followed by OCT imaging over the course of 60 to 80 days. Histological images were obtained at several time points to compare with the corresponding OCT images. Volume measurements were also acquired.ResultsOCT can identify the key features observed in corresponding histological images based on the scattering differences from various eye tissues, such as the cornea, intact and regenerated lens, and the iris. Lens volume measurements from three-dimensional OCT images showed that the regenerating lens size increased linearly until 60 days post-lentectomy.ConclusionsUsing OCT imaging, we were able to track the entire process of newt lens regeneration in vivo for the first time. Three-dimensional OCT images allowed us to volumetrically quantify and visualize the dynamic spatial relationships between tissues during the regeneration process. Our results establish OCT as an in vivo imaging modality to track/analyze the entire lens regeneration process from the same animal.Translational RelevanceLens regeneration in newts represents a unique example of vertebrate tissue plasticity. Investigating the cellular and morphological events that govern this extraordinary process in vivo will advance our understanding and shed light on developing new therapies to treat blinding disorders in higher vertebrates.

Lens regeneration: scientific discoveries and clinical possibilities.

In the process of exploring new methods for cataract treatment, lens regeneration is an ideal strategy for effectively restoring accommodative vision and avoiding postoperative complications and has great clinical potential. Lens regeneration, which is not a simple repetition of lens development, depends on the complex regulatory network comprising the FGF, BMP/TGF-β, Notch, and Wnt signaling pathways. Current research mainly focuses on in situ and in vitro lens regeneration. On the one hand, the possibility of the autologous stem cell in situ regeneration of functional lenses has been confirmed; on the other hand, both embryonic stem cells and induced pluripotent stem cells have been induced into lentoid bodies in vitro which are similar to the natural lens to a certain extent. This article will briefly summarize the regulatory mechanisms of lens development, describe the recent progress of lens regeneration, explore the key molecular signaling pathways, and, more importantly, discuss the prospects and challenges of their clinical applications to provide reference for clinical transformations.

Lens regeneration in humans: using regenerative potential for tissue repairing.

The crystalline lens is an important optic element in human eyes. It is transparent and biconvex, refracting light and accommodating to form a clear retinal image. The lens originates from the embryonic ectoderm. The epithelial cells at the lens equator proliferate, elongate and differentiate into highly aligned lens fiber cells, which are the structural basis for maintaining the transparency of the lens. Cataract refers to the opacity of the lens. Currently, the treatment of cataract is to remove the opaque lens and implant an intraocular lens (IOL). This strategy is inappropriate for children younger than 2 years, because a developing eyeball is prone to have severe complications such as inflammatory proliferation and secondary glaucoma. On the other hand, the absence of the crystalline lens greatly affects visual function rehabilitation. The researchers found that mammalian lenses possess regenerative potential. We identified lens stem cells through linear tracking experiments and designed a minimally invasive lens-content removal surgery (MILS) to remove the opaque lens material while preserving the lens capsule, stem cells and microenvironment. In infants with congenital cataract, functional lens regeneration in situ can be observed after MILS, and the prognosis of visual function is better than that of traditional surgery. Because of insufficient regenerative ability in humans, the morphology and volume of the regenerated lens cannot reach the level of a normal lens. The activation, proliferation and differentiation of lens stem cells and the alignment of lens fibers are regulated by epigenetic factors, growth factors, transcription factors, immune system and other signals and their interactions. The construction of appropriate microenvironment can accelerate lens regeneration and improve its morphology. The therapeutic concept of MILS combined with microenvironment manipulation to activate endogenous stem cells for functional regeneration of organs in situ can be extended to other tissues and organs with strong self-renewal and repair ability.

Autologous cell regeneration of the crystalline lens

AbstractRegeneration of ocular tissues using stem cells is currently under investigation for the cornea and the retina. Some more recent studies focus also on the regeneration of the crystalline lens. The lens consists of only two cell types, epithelial cells, which can differentiate and act as progenitor cells to the other cell type, fiber cells. Lens epithelial cells are very active, and due to this it is difficult to prevent their proliferation, migration and differentiation when they develop posterior capsule opacification (PCO) after cataract surgery. We have compared the morphology and histopathology of PCO developed in‐vivo with a PCO model of in‐vitro tissue culture. Our in‐vitro tissue culture showed some volumetric growth of cells which expressed the potential to form lens fiber cells. Some, but not all in‐vivo formed PCO showed doughnut shaped lens like structures with anterior epithelial cells, a lens bow and lens fiber like cells, very similar to the natural lens. Special surgical procedures of lens removal have been applied in rabbits and tested to treat human congenital cataract. Both were capable of regenerating the lens to some extent. These studies on PCO and in‐vivo surgery, demonstrate the potential to regenerate the crystalline lens in humans.