Osteoarthritis (OA) is a progressive degenerative joint disease, and to date, no disease-modifying OA drug exists. Amniotic membrane and umbilical cord products have been used clinically in several diseases due to their anti-inflammatory and antiscarring properties. In the present study, we sought to evaluate whether a particulate amniotic membrane and umbilical cord (AM/UC) matrix could aid in attenuating disease progression. Lewis rats underwent medial meniscus transection (MMT) to induce OA. Two weeks after surgery, animals received intra-articular injections (50 μL) of either 50 or 100 μg/μL particulate AM/UC or saline control and were subsequently euthanized 1 or 4 weeks later. Cartilage degeneration was assessed using both histological scoring methods and equilibrium partitioning of an ionic contrast agent-microcomputed tomography (EPIC-μCT). EPIC-μCT analysis demonstrated that overall cartilage destruction was attenuated, with a significant increase in both cartilage thickness and volume as well as a significant decrease in total lesion area in animals injected with either dose of particulate AM/UC at 1 week, but only a high dose at 4 weeks postinjection. Osteoarthritis Research Society International (OARSI) histology scores of tibial sections corroborated EPIC-μCT results. Overall joint destruction was attenuated in animals injected with either dose of AM/UC tissue compared with saline-injected control animals at 1 week postinjection. Only high-dose AM/UC-injected animals continued to show less overall joint destruction by 4 weeks postinjection. Intra-articular injection of particulate AM/UC tissue attenuates cartilage degradation in a rat MMT model of OA, suggesting that it may be able to slow joint destruction in patients with OA.
ObjectiveMicrobial infection has been reported to cause blepharitis, conjunctivitis and keratitis. We evaluated the safety and efficacy of a foam formulation of 2% 4-terpineol (T4O) against common ocular microorganisms.Material and methodsThe antimicrobial effect of a 2% T4O formulation was evaluated by the United States Pharmacopeia 51 (USP <51>) antimicrobial effectiveness test for 14 and 28 days, as well as by a Time Kill Study (ASTM E2315) with a 60 s exposure time. Its potential of causing skin and ocular irritation was evaluated by the Repeated Insult Patch Test and the Hen’s Egg Chorioallantoic Membrane Test, respectively.Results and discussionIt was seen that 2% T4O formulation did not cause ocular irritation, skin irritation, sensitisation or allergic contact dermatitis in human subjects. Most importantly, it killed microorganisms listed in USP <51> at both 14 and 28 days and exerted a rapid killing effect within 60 s against 13 bacteria, 1 fungus and Acanthamoeba castellanii.ConclusionThe above finding suggests that 2% T4O formulation is safe and effective in killing microorganisms related to common ocular and skin infective diseases.Translational relevanceAlthough the clinical efficacy in treating ocular disease was not directly studied; this foam formulation containing 2% T4O, based on the in vitro results of this work, demonstrated that it can potentially be used as a preservative-free cleansing agent for ocular hygiene maintenance due to its ability to exert a broad-spectrum antimicrobial effect without causing ocular or skin irritation.
Limbal niche cells located in the limbal Palisades of Vogt are mesenchymal stem cells that reside next to limbal basal epithelial cells. Limbal niche cells are progenitors that express embryonic stem cell markers such as Nanog, Nestin, Oct4, Rex1, Sox2 and SSEA4, mesenchymal cell markers such as CD73, CD90 and CD105, and angiogenesis markers such as Flk‐1, CD31, CD34, VWF, PDGFRβ and α‐SMA, but negative for CD45. In addition, the stemness of limbal niche cells can be maintained during their cell culture in a three‐dimension environment. Furthermore, expanded limbal niche cells have the capability to undergo adipogenesis, chondrogenesis, osteogenesis and endogenesis in vitro, indicating that they are in fact a valuable resource of adult progenitors. Furthermore studies on how the limbal niche cells regulate the aforementioned stemness and corneal fate decision are warranted, as those investigations will shed new light on how mesenchymal progenitors reverse limbal stem cell deficiency and lead to new methods for limbal niche cell treatment.
Human corneal endothelial cells have two major functions: barrier function mediated by proteins such as ZO-1 and pump function mediated by Na-K-ATPase which help to maintain visual function. However, human corneal endothelial cells are notorious for their limited proliferative capability in vivo and are therefore prone to corneal endothelial dysfunction that eventually may lead to blindness. At present, the only method to cure corneal endothelial dysfunction is by transplantation of a cadaver donor cornea with normal corneal endothelial cells. Due to the global shortage of donor corneas, it is vital to engineer corneal tissue in vitro that could potentially be transplanted clinically. In this review, we summarize the advances in understanding the behavior of human corneal endothelial cells, their current engineering strategy in vitro and their potential applications.
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