Porcine corneal cell culture models for studying epidemic keratoconjunctivitis.

PURPOSE: Epidemic keratoconjunctivitis (EKC) is a severe ocular infection caused by a few types (8, 19a [relabeled as 64 recently], 37, 53, and 54) of human adenoviruses (HAdVs). HAdVs are known for their strong host species specificity that limits studying HAdV virulence and pathophysiology in animal models. METHODS: A HAdV infection model of primary porcine corneal epithelial cells (PPCE) and primary porcine corneal keratocytes (PPCK) was established and compared to primary human corneal epithelial cells (PHCE) and primary human corneal keratocytes (PHCK). Induction of interleukin-8 (IL-8) messenger RNA (mRNA), HAdV DNA replication, and the release of infectious virus progeny by the EKC-associated type HAdV-D37 and the non-EKC-associated type HAdV-D22 were studied. RESULTS: PPCE and PPCK morphology and the expression of α2,3-linked sialic acid, the main receptor of EKC-associated HAdV types, were akin to human corneal cells (PHCE and PHCK). Induction of IL-8 mRNA was observed as early as 8 h after HAdV infection. Induction of IL-8 mRNA by HAdV-D37 infection was significantly higher (p≤0.001) than by HAdV-D22 infection in PPCE, PPCK, PHCE, and PHCK. Detection of HAdV-DNA replication, release of infectious virus progeny, and the development of cytopathic effect indicated that PPCE and PPCK were fully permissive for HAdV-D37 and HAdV-D22 replication as were the human corneal cells (PHCE and PHCK). Infectious virus titers after HAdV-D37 infection (1.0 × 10(5) TCID50/ml) were significantly higher (p=0.001) than after HAdV-D22 infection (1.8 × 10(4) TCID50/ml) in PPCE, PHCE, and PHCK but not significantly different in PPCK. CONCLUSIONS: Primary porcine epithelial cells and keratocytes are nonhuman corneal cell culture models fully permissive for HAdV infection. The models hold promise for studying the virulence and pathophysiology of EKC-associated adenovirus types compared to other adenovirus types.

A new human somatic stem cell from placental cord blood with intrinsic pluripotent differentiation potential.

Here a new, intrinsically pluripotent, CD45-negative population from human cord blood, termed unrestricted somatic stem cells (USSCs) is described. This rare population grows adherently and can be expanded to 10(15) cells without losing pluripotency. In vitro USSCs showed homogeneous differentiation into osteoblasts, chondroblasts, adipocytes, and hematopoietic and neural cells including astrocytes and neurons that express neurofilament, sodium channel protein, and various neurotransmitter phenotypes. Stereotactic implantation of USSCs into intact adult rat brain revealed that human Tau-positive cells persisted for up to 3 mo and showed migratory activity and a typical neuron-like morphology. In vivo differentiation of USSCs along mesodermal and endodermal pathways was demonstrated in animal models. Bony reconstitution was observed after transplantation of USSC-loaded calcium phosphate cylinders in nude rat femurs. Chondrogenesis occurred after transplanting cell-loaded gelfoam sponges into nude mice. Transplantation of USSCs in a noninjury model, the preimmune fetal sheep, resulted in up to 5% human hematopoietic engraftment. More than 20% albumin-producing human parenchymal hepatic cells with absence of cell fusion and substantial numbers of human cardiomyocytes in both atria and ventricles of the sheep heart were detected many months after USSC transplantation. No tumor formation was observed in any of these animals.

Bone healing and migration of cord blood-derived stem cells into a critical size femoral defect after xenotransplantation.

UNLABELLED: Stem cell and tissue engineering-based therapies have become a promising option to heal bony defects in the future. Human cord blood-derived mesenchymal stem cells were seeded onto a collagen/tricalcium phosphate scaffold and xenotransplanted into critical size femoral defects of 46 nude rats. We found a survival of human cells within the scaffold and surrounding bone/bone marrow up to 4 wk after transplantation and an increased bone healing rate compared with controls without stem cells. This study supports the application of cord blood stem cells for bone regeneration. INTRODUCTION: The treatment of critical size bone defects is still a challenging problem in orthopedics. In this study, the survival, migration, and bone healing promoting potency of cord blood-derived stem cells were elucidated after xenotransplantation into a critical size femoral defect in athymic nude rats. MATERIALS AND METHODS: Unrestricted somatic stem cells (USSCs) isolated from human cord blood were tested toward their mesenchymal in vitro potency and cultivated onto a collagen I/III and beta-tricalcium phosphate (beta-TCP) scaffold. The biomaterial-USSC composite was transplanted into a 4-mm femoral defect of 40 nude rats and stabilized by an external fixator. Twelve animals without USSCs served as controls. Cell survival, migration, and bone formation were evaluated by blood samples, X-rays, and histological and immunocytochemical analysis of different organs within a maximal postoperative follow-up of 10 wk. RESULTS: Of the 52 nude rats, 46 animals were evaluated (drop-out rate: 11.5%). Human-derived stem cells showed an engraftment within the scaffold and adjacent femur up to 4 wk after xenotransplantation. With further time, the human cells were destroyed by the host organism. We found a significant increase in bone formation in the study group compared with controls. USSC transplantation did not significantly influence blood count or body weight in athymic nude rats. Whereas the collagen I/III scaffold was almost resorbed 10 wk after transplantation, there were still significant amounts of TCP present in transplantation sites at this time. CONCLUSIONS: Human cord blood-derived stem cells showed significant engraftment in bone marrow, survived within a collagen-TCP scaffold up to 4 wk, and increased local bone formation in a nude rat's femoral defect.