Flank pseudohernia following posterior rib fracture: a case report.

BACKGROUND: A pseudohernia is an abdominal wall bulge that may be mistaken for a hernia but that lacks the disruption of the abdominal wall that characterizes a hernia. Thus, the natural history and treatment of this condition differ from those of a hernia. This is the first report of a pseudohernia due to cough-associated rib fracture. CASE PRESENTATION: A case of pseudohernia due to fractures of the 10th and 11th ribs in a 68-year-old white woman is presented. The patient suffered from a major coughing episode 1 year prior to her presentation, after which she noted a progressively enlarging bulge in her left flank. Computed tomography demonstrated a bulge in the abdominal wall containing bowel and spleen but with all muscle and fascial layers intact; in addition, lateral 10th rib and posterior 11th rib fractures were noted. CONCLUSIONS: As there was no defect in muscle or fascia, we diagnosed a pseudohernia, likely due to a denervation injury from the fractured ribs. Symptomatic treatment was recommended, including wearing a corset and referral to a pain management clinic. Symptomatic treatment is thought to be the mainstay of therapy for pseudohernias, as surgical intervention is unlikely to be of benefit.

Engraftment of quiescent progenitors and conversion to full chimerism after nonmyelosuppressive conditioning and hematopoietic cell transplantation in miniature swine.

Our laboratory has previously reported a nonmyelosuppressive preparative regimen for hematopoietic cell transplantation that leads to mixed chimerism and allograft tolerance in miniature swine across minor and major histocompatibility disparities. Stable chimerism persisted in most of these animals but was restricted to T cells and confined to peripheral blood. Because of the importance of myeloid and erythroid progenitors for the treatment of hematologic disorders, the objective of this study was to assess whether such cells existed in the bone marrow of these lymphoid chimeras as an indication of functional engraftment. Colony-formation assays were performed on donor inocula before infusion and on bone marrow cells harvested from the transplant recipients. Donor-origin myeloid/erythroid progenitor colonies were detected in bone marrow from 6 of 7 lymphoid chimeric recipients. A delayed donor leukocyte infusion successfully converted a stable lymphoid chimera to full multilineage chimerism within 2 weeks. Donor-origin myeloid/erythroid progenitors could be detected in the bone marrow of a host-matched recipient after myeloablation and adoptive transfer of mobilized cells from one of the engrafted lymphoid chimeras. These data suggest that even when only lymphoid chimerism is readily detected by flow cytometry, dormant myeloid/erythroid progenitors can exist and subsequent conversion to full donor chimerism can be achieved. The ability to establish multilineage engraftment and chimerism without significant toxicity may have important clinical implications for the management of nonmalignant hematopoietic disorders and hematologic malignancies.

Variable relationship between chimerism and tolerance after hematopoietic cell transplantation without myelosuppressive conditioning.

BACKGROUND: We have previously described a mixed chimerism protocol that avoids myelosuppressive conditioning and permits hematopoietic cell transplantation across MHC barriers without the need for whole body irradiation in miniature swine. Here, we report our current experience including animals conditioned without thymic irradiation, and we attempt to define the relationship between long-term chimerism and stable tolerance in these animals. METHODS: Recipient swine received in vivo T-cell depletion, with or without thymic irradiation on day -2. Cyclosporine was administered for 30 to 60 days beginning on day -1. A total of 1 to 2 x 10(10) /kg cytokine-mobilized donor hematopoietic cells were infused during 3 days. Chimerism was determined by flow cytometry. In vitro tolerance assays and donor-matched kidney transplantation were performed after cessation of cyclosporine. RESULTS: Most recipients maintained stable chimerism (26 of 35) and were specifically tolerant to donor-matched cells in vitro regardless of whether they received thymic irradiation. Donor-matched kidney transplantations performed in chimeric animals without in vitro antidonor immune responses were accepted without immunosuppression. Some animals developed in vitro evidence of antidonor MHC responsiveness despite the persistence of donor cells in the peripheral blood. Donor-matched kidney transplantations performed in the face of these responses were rejected. CONCLUSIONS: These data indicate that this nonmyelosuppressive protocol can induce stable chimerism and robust tolerance even in animals conditioned without thymic irradiation. However, the data also demonstrate that macrochimerism does not always correlate with tolerance. Lack of in vitro antidonor immune responses in chimeric animals is an important predictor of renal allograft acceptance in this model.

Persistent chimerism despite antidonor MHC in vitro responses in miniature swine following allogeneic hematopoietic cell transplantation.

BACKGROUND: T-cell chimerism predominates in miniature swine receiving hematopoietic-cell transplantation without myelosuppressive conditioning. Several chimeric recipients have become hyporesponsive to donor-major histocompatibility complex (MHC) in vitro and accepted donor-matched renal transplants without immunosuppression. However, some retained antidonor in vitro responses and subsequently rejected donor renal allografts despite the persistence of peripheral blood chimerism. In this study, we characterize the donor cells in both "tolerant" and "nontolerant" chimeric miniature swine. METHODS: Peripheral blood chimerism was determined by flow cytometry. In vitro antidonor responsiveness was determined by mixed lymphocyte reaction (MLR) and cell-mediated lymphocytotoxicity (CML). Donor cells were separated from chimeras by immunomagnetic bead separation and used as stimulators or targets in CML assays. Phenotypic analysis of donor cells in chimeras was performed using flow cytometry. RESULTS: Peripheral blood chimerism stabilized beyond 100 days and was made up almost entirely of T cells. PBMC from nontolerant chimeras could be stimulated in vitro to kill donor cells isolated from the mixed chimera itself. In contrast, PBMC from tolerant chimeras hyporesponsive to donor-type cells could not be stimulated in vitro to kill their own sorted donor cells. CONCLUSIONS: The in vivo persistence of donor T cells in mixed chimeric animals with in vitro antidonor responsiveness is not caused by an inability of these cells to be killed but rather by the poor stimulating capacity of these donor T cells. The nature of donor T cells that persist in the face of in vitro antidonor responses, has important implications for the induction of transplant tolerance by way of the generation of mixed chimerism.