T. Ikonen

Sirolimus (rapamycin) halts and reverses progression of allograft vascular disease in non-human primates.

Background. Current immunosuppressive protocols fail to prevent chronic rejection often manifested as graft vascular disease (GVD) in solid organ transplant recipients.Several new immunosuppressants including sirolimus, a dual function growth factor antagonist, have been discovered, but studies of drug efficacy have been hampered by the lack of a model of GVD in primates, as a prelude to clinical trials. As described earlier, we have developed a novel non-human primate model of GVD where progression of GVD is quantified by intravascular ultrasound (IVUS). Methods. Twelve cynomolgus monkeys underwent aortic transplantation from blood group compatible but mixed lymphocyte reaction-mismatched donors. To allow the development of GVD in the allograft, no treatment was administered for the first 6 weeks. Six monkeys were treated orally with sirolimus from day 45 after transplantation to day 105. Results. Progression of GVD measured as change in intimal area from day 42 to 105 was halted in sirolimus-treated monkeys compared to untreated monkeys (P <0.001, general linear model). On day 105, the intimal area±SEM was 3.7±1.0 and 6.4±0.5 mm2, respectively (P <0.05, t test). The magnitude of allograft intimal area on day 105 correlated inversely with sirolimus trough levels (R2=0.67, P <0.05). Regression of the intimal area was seen in four of six sirolimus-treated monkeys, which was significantly different from the untreated monkeys (P <0.05). Conclusions. Our results in the first non-human primate model of GVD showed that treatment with sirolimus not only halted the progression of preexisting GVD but also was associated with partial regression. Sirolimus trough blood levels were correlated with efficacy. Therefore, sirolimus has the potential to control clinical chronic allograft rejection.

Epithelial re-growth is associated with inhibition of obliterative airway disease in orthotopic tracheal allografts in non-immunosuppressed rats.

Background. Because epithelial cells are targets of alloimmune injury leading ultimately to airway obliteration, we tested whether epithelial re-growth could prevent obliterative airway disease (OAD) in orthotopic tracheal allografts. Methods. Brown Norway tracheal segments were orthotopically transplanted into nonimmunosuppressed Lewis rats. Allografts were removed on days 2–10 (n=13), 30 (n=4), and 60 (n=5) for histology, computerized morphometry (obliteration), and immunohistochemical detection of mononuclear cells, smooth muscle &agr;-actin, and tissue phenotype. Normal tracheas, host tracheas, and heterotopically transplanted allografts served as controls. Results. Orthotopic allografts removed on days 2–10 exhibited epithelial damage and re-growth and mononuclear cell infiltration. On days 30 and 60, partially ciliated cuboidal or attenuated epithelium completely covered the lumen. Although mononuclear cells declined, numerous T cells with a high CD4/CD8 ratio were found in the epithelium till day 60. Orthotopic allograft epithelium expressed donor phenotype on day 7, but recipient phenotype on days 30 and 60. Despite subepithelial &agr;-actin positive myofibroblast proliferation, obliteration did not progress from day 7 to 30 and 60 (35, 30, and 33%, respectively). Although more than in normal or host tracheas, the obliteration in orthotopic allografts on days 30 and 60 was significantly less (P <0.001) than in heterotopic allografts. Conclusions. We describe, for the first time, long-term patency of fully histoincompatible orthotopic tracheal allografts in nonimmunosuppressed rats. Despite acute alloimmune injury and induction of myofibroblast proliferation, epithelial re-growth from the host limited the progression of OAD, thus emphasizing the role of epithelium in the control of airway obliteration.

The therapeutic prescription for the organ transplant recipient: the linkage of immunosuppression and antimicrobial strategies

Infection and rejection, the two major barriers to successful organ transplantation, are closely linked, with immunosuppressive therapy being central to the pathogenesis of both. After almost two decades when azathioprine and prednisone, supplemented by antilymphocyte antibody therapy, were the cornerstones of post‐transplant immunosuppressive programs, there has been a major increase in the therapeutic armamentarium available to treat rejection: cyclosporine, tacrolimus, mycophenolate mofetil, rapamycin, and antibodies directed against the interleukin‐2 receptor. These agents are potent inhibitors of microbial specific T cell function, thus potentiating opportunistic infection with herpes group viruses, fungal and mycobacterial species, Strongyloides stercoralis, and a variety of intracellular pathogens. The mechanisms by which each of these drugs exerts its effects are an important determinant of the antimicrobial strategies that will be necessary to combat infection. Indeed, strategies to limit these infections are being linked to the nature of the immunosuppressive therapy required in a particular patient. Thus, the therapeutic prescription for the transplant patient is said to have two components: an immunosuppressive component to prevent and treat rejection, and an antimicrobial one to make it safe. In addition to using antimicrobial agents therapeutically, in the transplant patient prevention is stressed in which antibiotics are deployed prophylactically or preemptively ( Note ).

Feasibility of In Vivo Intravascular Ultrasound Tissue Characterization in the Detection of Early Vascular Transplant Rejection

BACKGROUND Unprocessed ultrasound radiofrequency (RF) signal analysis has been shown to distinguish different tissue structures more reliably than gray-scale interpretation of conventional ultrasound images. METHODS AND RESULTS The objective of this study was to test the feasibility of in vivo intravascular ultrasound (IVUS) RF signal analysis in an animal model of allograft rejection. Six cynomolgus monkeys underwent transplantation of 3-cm aortic allograft segments distal to the renal arteries from immunologically mismatched donors. IVUS imaging with a 30-MHz system was performed 84 to 105 days after the operation. RF signals were acquired from cross sections of the recipient and the allograft aortas in real time with a digitizer at 500 MHz with 8-bit resolution. Sixty-five cross sections and 68 regions of interest (31 in host aorta and 37 in allograft) were analyzed in the adventitial layer with a total number of 8568 vectors processed. For each region of interest, a weighted-average attenuation was calculated on the basis of the attenuation and length for each individual vector. Histological examination was performed at every cross section imaged by IVUS. When the gray-scale images of conventional IVUS scored by an independent observer were compared, no distinction between adventitia of the native aorta and allograft was possible. Analysis of the average RF backscatter power also showed no significant difference (70.32+/-3.55 versus 70.72+/-3.38 dB). However, the average attenuation of allografts was significantly lower than that of the host aortas (2.64+/-1.38 versus 4.02+/-1.16 dB/mm, P<0.001). Histology demonstrated a marked adventitial inflammatory response in all allografts, with no inflammation observed in the host aortas. CONCLUSIONS In vivo IVUS tissue characterization can be performed during routine imaging. In this model of transplant vasculopathy, RF attenuation measurements were more sensitive than visual or quantitative gray-scale analysis.

Up‐regulation of inducible nitric oxide synthase in fibroblasts parallels the onset and progression of fibrosis in an experimental model of post‐transplant obliterative airway disease

The main cause of mortality following lung transplantation is chronic rejection, manifesting morphologically as obliterative bronchiolitis (OB). It has been suggested that damage to the respiratory epithelium initiates proliferation of mesenchymal cells, leading to dense collagenous scarring in small airways. Inducible nitric oxide synthase (iNOS) is strongly expressed in the damaged epithelium in human OB, along with high levels of peroxynitrite, suggesting that endogenous NO mediates the epithelial destruction. To examine further the role of iNOS in this process, heterotopic airway implants were studied in rats, an acknowledged disease model. Specimens of iso‐ or allografted trachea, collected 3–60 days after implantation, were processed for histology and immunocytochemistry for iNOS and, as a marker of peroxynitrite formation, nitrotyrosine. In both iso‐ and allografts at the earliest stage (day 3), ischaemia was associated with severe epithelial damage or loss. These changes progressed until day 7 and were accompanied by strong expression of iNOS and nitrotyrosine in epithelial cells. In isografts, epithelial recovery was seen, with abundant iNOS immunoreactivity but little nitrotyrosine. In contrast, the epithelium in allografts did not regenerate and progressive inflammation and fibroproliferation occurred until complete obliteration of the tracheal lumen at day 60. The fibroproliferation was associated with changes in morphology of fibroblasts that were accompanied by alterations in their iNOS expression. iNOS immunoreactivity was dense in the plump fibroblasts of early lesions, in some cases as early as post‐operative day 5, but very weak in elongated fibroblasts in totally occluded grafts. The intensity of immunoreactivity for nitrotyrosine corresponded to that of iNOS. These results indicate a dual role for NO in the airway obliteration that follows transplantation, through destruction of epithelium and stimulation of fibroblast activity. Copyright

Airway Goblet Cells and Respiratory Epithelial Injury in an Animal Model of Obliterative Airways Disease (OAD)

Goblet cells are important in the maintenance of the epithelial cell population in the airway, defense against injury and storage and release of mucins, which can protect the surface epithelial layer. In our rat tracheal model of acute rejection, there is injury and loss of respiratory epithelium in allografts. This loss of epithelium is associated with obliteration of the airway lumen. In small bowel allografts, studies have shown that the loss of goblet cells is an important histologic feature of rejection. The aims of this study were: (i) to examine for the first time the close time‐course of goblet cell proliferation in acute rejection; and (ii) to compare the isograft vs. allograft morphometric changes associated with epithelial damage.

Multidimensional assessment of graft vascular disease (GVD) in aortic grafts by serial intravascular ultrasound in rhesus monkeys.

BACKGROUND Graft vascular disease (GVD) is an incompletely understood process and the primary cause of late allograft failure. A nonhuman primate model was established to study the progression of GVD by using serial intravascular ultrasound (IVUS). METHODS Aortic allografts were transplanted below the inferior mesenteric arteries (IMA) into 6 rhesus monkeys. Removed and re-implanted aortic segments between renal arteries, and the inferior mesenteric arteries served as autografts. IVUS was performed at days 0, 24, 52, 80, and 98 after transplantation. Vessel area (VA) and lumen area (LA) were measured from each cross-section at 0.5 mm intervals. Intimal index (II=100x (VA-LA/VA)) and corresponding vessel volumes were calculated for the whole grafts. Histologic features were assessed from autopsy samples using computerized morphometric method and a score from 0 to 3 for GVD (0=none, 3=severe). RESULTS In allografts, vessel volume and luminal volume decreased significantly (P<0.05 for both) and the intimal index increased from 12% to 59% by day 98. These parameters remained unchanged in autografts. Histologic analysis of allografts showed concentric intimal hyperplasia and scattered mononuclear cell accumulations, whereas the autografts had only occasional eccentric intimal changes. The GVD-scores were significantly higher in allografts than in autografts (median 3 vs. 1, P=0.042). CONCLUSIONS We introduce a nonhuman primate model of GVD that enables serial IVUS assessments of multiple parameters of GVD. Concentric intimal proliferation and decrease of vessel dimensions was observed in allografts as a consequence of alloimmunity. This is a potential new model for studying new therapies to prevent GVD or halt its progression.

The histology of subcutaneously implanted donor bronchial rings correlates with rejection scores of lung allografts in a primate lung transplant model.

BACKGROUND The diagnosis of acute rejection in lung transplantation generally relies on transbronchial biopsies. This invasive procedure may be associated with bronchial bleeding or pneumothorax and may not be feasible in patients with severely compromised lung function. The hypothesis of the current study was that histopathological findings of donor bronchial segments implanted into the subcutaneous tissue of lung allograft recipients would predict lung tissue rejection scores, thus providing the clinician with an alternate source of information. METHODS Unilateral left lung transplantation was performed in 34 cynomolgus monkeys as part of a drug efficacy study. After completion of the transplant procedure, 4 bronchial ring segments of the explanted recipient left lung and 4 bronchial ring segments of the non-transplanted right donor lung were implanted subcutaneously in the abdominal region. Lung allograft rejection was evaluated by open lung biopsies of the allograft performed on postoperative (PO) Day 14 and during sacrifice on PO Day 28. At the time of each biopsy, 2 donor and 2 recipient subcutaneous bronchial rings were explanted. Histologic evaluation of the lung tissue samples was performed according to the working formulation of the International Society for Heart and Lung Transplantation. Bronchial rings were independently evaluated by assessing the degree of airway narrowing; percentage of intact epithelial coverage as well as its specific histology (respiratory ciliated, flattened cuboidal, squamous); presence of lymphocytes, macrophages or spindle cells; and presence of peribronchial inflammation, luminal fibrosis, lymphocytic bronchitis or luminal mucous. Statistical analysis was performed by logistic regression. RESULTS In the recipient bronchial rings, there was no evidence of airway narrowing. There was 98% epithelial coverage, 71% that were respiratory ciliated cells, and there was no inflammation. Donor bronchial rings showed no airway narrowing for monkeys with grade A0 to A2 rejection in tissue biopsies and a maximum narrowing (41.2%) with A4 rejection. Epithelial cell coverage was approximately 100% with grade A0-A2 and 44+/-11% with A4 rejection. Lymphocytic bronchitis was most severe in A4 rejection and minimal in A0 to A2 rejection. By logistic regression analysis, independent predictors of a likelihood of rejection were the degree of airway obliteration, the percentage of epithelial cell coverage, the degree of lymphocytic bronchitis and the product of respiratory and flattened cuboidal cell coverage. CONCLUSIONS The current data show that histologic alterations of subcutaneously implanted donor bronchial rings correlate with lung tissue biopsy scores based on the ISHLT working formulation. Because subcutaneous bronchial rings can be explanted under local anesthesia, they may provide useful information for the diagnosis of acute allograft rejection in patients with impaired lung function, patients that obtaining lung tissue samples may not be feasible.

Respiratory epithelial expression of integrin αvβ6 in chronic progressive allograft rejection

Abstract Background Obliterative bronchiolitis (OB) is the major cause of morbidity and mortality after lung transplantation. One initiating event in the development of obliteration of the airway lumen is epithelial injury. In our model of chronic rejection, initial ischemic injury and denudation of the epithelium occurs in the isografts, with eventual re-epithelialization and partial patency of the airway lumen. In contrast, allografts do not recover epithelium, and the airway lumen becomes obliterated. We hypothesized that because integrin αVβ6 is expressed in healing epithelium, integrin αVβ6 expression would be greatly increased in isografts, but not in allografts. Methods Using a rat tracheal allograft rejection model as a source of 4- to 5-μm tissue sections, we compared integrin staining in allografts vs isografts from animals at post-transplant Days 7, 14, 28, and 60. We analyzed the sections using immunohistochemistry after incubation with a specific monoclonal antibody E7P6 against integrin αVβ6. Negative control slides were processed identically, except that primary antibody was omitted. Results The sections from healing, re-epithelializing isografts showed intense staining when using the antibody recognizing integrin αVβ6, compared with the allografts studied. Days 7 and 14 isografts had increased epithelial expression of αVβ6. As the isograft epithelium recovered, the intensity diminished at Days 28 and 60. In allografts, at Days 7 to 60, we detected only a comparatively low-level of expression in injured epithelium. Conclusions Integrin αVβ6 is readily detectable in healing isografts. Integrin αVβ6 may be crucial in maintaining a viable epithelial cell layer, which is related to slowed progression of airway obliteration in OB.

A new large animal heterotopic lung and bronchial allograft model for research in obliterative bronchiolitis.

0 NE PROBLEM in the research of obliterative bronchiolitis is the lack of a proper large animal model. Various rodent models have been studied, either with lung or heterotopic tracheal transplants.” In a previous study, obliterative bronchiolitis was found after lung transplantation in pigs,4 but the extent of the chronic lesions is limited. Al-Dossari et al recently investigated a lung transplantation model in minipigs with obliterative airway lesions.5 The disadvantage in lung transplantation models is a demanding surgical procedure. In heterotopic rodent models, the similarities or dissimilarities of obliterative airway lesions in tracheal transplant with the obliterative bronchiolitis lesion, in small airways are unknown. The aim of the current study is to develop a simple heterotopic large animal model for research of obliterative lesions in small airways caused by chronic alloimmune injury.