Iron chelation therapy and lung transplantation

Use of pulmonoplegia and delivery system during recipient surgery in lung transplantation

Lung transplantation in the United States has steadily grown over the last decade. Major attention has been with the understanding of lung ischemia-reperfusion injury and how it relates to primary graft dysfunction. In 2015, our institution implemented the use of a pulmonoplegia solution during recipient surgery of lung transplantation. A unique circuit utilizing the heart lung machine is used to deliver the pulmonoplegia solution. This system is considered to be a key contributing factor to the success of our lung transplant program.

Protective effects of deferoxamine mesylate preconditioning on pancreatic tissue in orthotopic liver autotransplantation in rats

BACKGROUND

Deferoxamine mesylate is known to ameliorate tissue ischemia-reperfusion injury. This study was designed to explore the impact of deferoxamine mesylate preconditioning (DMP) on pancreatic tissue and its possible effects during orthotopic liver autotransplantation.

METHODS

A modified orthotopic liver autotransplantation model was used to simulate pancreatic ischemia-reperfusion injury. Sprague-Dawley rats (0.25-0.30 kg) were randomly divided into normal control, autotransplantation (AT), systemic deferoxamine mesylate preconditioning (SDMP), and partial deferoxamine mesylate conditioning (PDMC) groups. The SDMP group was injected with deferoxamine mesylate (75-90 mg; 300 mg/kg), via the celiac artery at 24 and 48 hours before surgery. During surgery, the PDMC group underwent liver perfusion by means of deferoxamine mesylate solution (20 ml; 0.6 mmol/L) rather than Ringer's lactate solution, with no prior preconditioning. At 6, 24, and 48 hours after surgery, the rats were sacrificed to sample their pancreatic tissues for the expression of hypoxia-inducible factor-1α (HIF-1α) and malondialdehyde (MDA) content. The samples were subjected to blood chemistry analyses, light and transmission electron microscopic morphological studies, and quantitative measurement of HIF-1α expression.

RESULTS

The serum levels of amylase, lipase, and MDA in SDMP and PDMC groups were significantly lower than those in the AT group at 6, 24, and 48 hours after orthotopic liver autotransplantation (P < .05). Light and electron microscopic analyses showed much more severe pancreatic injury in the autotransplantation than in the SDMP and PDMC groups. The HIF-1α expression was increased in the SDMP and PDMC groups more than in the autotransplantation group (P < .05).

CONCLUSIONS

Deferoxamine mesylate preconditioning protected pancreatic tissue in orthotopic liver autotransplantation in rats. Inhibition of oxidative toxic reactions and up-regulated expression of HIF-1α protein are possible mechanisms.

Long-term outcome of lung and heart-lung transplantation for idiopathic pulmonary arterial hypertension

BACKGROUND

The survival after lung and heart-lung transplantation for idiopathic pulmonary arterial hypertension has been reportedly the lowest among the major diagnostic categories of lung transplant recipients.

METHODS

Retrospective analysis was performed for lung and heart-lung transplant recipients for idiopathic pulmonary arterial hypertension from 1982 to 2006. The patients were divided into 2 groups, based on the era; group 1: 1982 to 1993, and group 2: 1994 to 2006. Since 1994, we have introduced our current protocols including prostaglandin E1 and nitroglycerin for donor lung preservation, and lung protection with cold and terminal warm blood pneumoplegia as well as immunosuppression with alemtuzumab induction. These modifications were introduced in different years over a wide span of time (1994 to 2003).

RESULTS

Group 1 had 59 patients (35 +/- 1 years old, ranging 15 to 53, 20 male and 39 female) with 7 single lung, 11 double lung, and 41 heart-lung, whereas group 2 had 30 (43 +/- 2 years old, ranging 17 to 65, 9 male and 21 female) with 2 single, 20 double, and 8 heart-lung transplantations. The recipient age was significantly (p = 0.004) higher in group 2, and group 2 had significantly older (35 +/- 3 vs 26 +/- 1, p = 0.002) and more female donors (73% vs 41%, p = 0.007) compared with group 1. The actuarial survival was significantly (p = 0.004) better in group 2 with 86% at 1 year, 75% at 5 years, and 66% at 10 years compared with group 1 with 58% at 1 year, 39% at 5 years, and 27% at 10 years.

CONCLUSIONS

With our current pulmonary protection and immunosuppression, the long-term outcome of lung and heart-lung transplantation for idiopathic pulmonary arterial hypertension is excellent.

Disruption of Iron Homeostasis in the Lungs of Transplant Patients

BACKGROUND

Oxidative stress has been proposed as a mechanism of injury underlying obliterative bronchiolitis. Catalytically reactive iron is a potential source of reactive oxygen species in transplanted tissue. Using samples acquired from surveillance bronchoalveolar lavage (BAL), we tested the postulate that there is a disruption of iron equilibrium in transplanted lung, which can worsen with time.

METHODS

A control group of 5 healthy, non-smoking volunteers underwent BAL. Five bilateral lung transplant patients underwent surveillance BAL with transbronchial lung biopsies. The BAL fluid concentrations of protein, albumin, total iron, lactoferrin, ferritin, transferrin receptor and total iron binding capacity were measured.

RESULTS

The mean ages in the control and transplant groups were 25.0 +/- 2.4 and 34.6 +/- 5.0 years, respectively. Patients were transplanted for cystic fibrosis (n = 3), primary ciliary dyskinesia (n = 1) and bronchiolitis obliterans (n = 1). Surveillance bronchoscopies were performed at 100.6 +/- 63.3, 175.0 +/- 87.7 and 259.2 +/- 82 days post-transplant. No significant differences were noted in BAL protein, albumin and total iron binding capacity (TIBC) levels between the 2 groups. The BAL iron, transferrin, transferrin receptor, lactoferrin and ferritin levels were significantly elevated in transplant patients relative to controls. With time after transplantation, there were increases in lavage iron, transferrin receptor, lactoferrin and ferritin concentrations.

CONCLUSIONS

Abnormally high levels of iron and its homeostatic proteins were found in the lung allografts, and levels appeared to increase with time. This supports a disruption in the normal homeostasis of this metal after transplantation and a potential role for a catalyzed oxidative stress in bronchiolitis obliterans. The use of iron-depleting therapy is a possible means for preventing injury in the lung allograft.

Iron and the redox status of the lungs

Iron is an element essential for the survival of most aerobic organisms. However, when its availability is not adequately controlled, iron, can catalyze the formation of a range of aggressive and damaging reactive oxygen species, and act as a microbial growth promoter. Depending on the concentrations formed such species can cause molecular damage or influence redox signaling mechanisms. This review describes recent knowledge concerning iron metabolism in the lung, during both health and disease. In the lower part of the lung a small redox active pool of iron is required for reasons that are at present unclear, but may be related to antimicrobial functions. When the concentration of iron is increased in the lung (usually because of environmental exposure), iron is deleterious and contributes to a range of chronic and acute respiratory diseases. Moreover, aberrant regulation of iron metabolism, and/or deficient antioxidant protection, is also associated with acute lung diseases, such as the acute respiratory distress syndrome (ARDS). Iron, with the consequent production of reactive oxygen species (ROS), microbial growth promotion, and adverse signaling is strongly implicated as a major contributor to the pathogenesis of numerous disease processes involving the lung. Heme oxgenase, an enzyme that produces reactive iron from heme catabolism, is also briefly discussed in relation to lung disease.

Depolarization-associated iron release with abrupt reduction in pulmonary endothelial shear stress in situ

This study evaluated the roles of endothelial cell membrane potential and reactive oxygen species (ROS) in the increase of tissue free iron during lung ischemia. Oxygenated ischemia was produced in the isolated rat lung by discontinuing perfusion while ventilation with O2 was maintained. We have shown previously that tissue oxygenation is maintained in this model of ischemia and that biochemical changes are the result of an abrupt reduction in endothelial shear stress. With 1 hr oxygenated ischemia, generation of ROS, evaluated by oxidation of dichlorodihydrofluorescein (H2DCF) to fluorescent dichlorofluorescein, increased 8.0-fold, lung thiobarbituric acid reactive substances (TBARS) increased 3.4-fold, and lung protein carbonyl content increased 2.4-fold. Lung tissue free iron, measured in the lung homogenate with a fluorescent desferrioxamine derivative, increased 4.0-fold during ischemia. Pretreatment of lungs with thapsigargin abolished the increase in free iron with ischemia indicating that this effect is dependent on Ca2+ release from intracellular stores. Perfusion of lungs with high (25 mM) K+ to depolarize the endothelium also led to a significant increase in tissue free iron. Pretreatment of lungs with 35 microM cromakalim, a K+-channel agonist, significantly inhibited both ischemia-induced tissue oxidant injury and the increase in free iron with ischemia or with high K+ perfusion. A similar increase in free iron was observed when lungs were ventilated with either O2 or N2 during the ischemic period or were pre-perfused with an inhibitor of ROS production (diphenyleneiodonium). These results indicate that ROS generation is not required for ischemia-mediated iron release. Thus, ROS generation and iron release with ischemia are independent although both are subsequent to endothelial cell membrane depolarization.

Perfusão pulmonar anterógrada "versus" retrógrada na preservação pulmonar para transplante em modelo canino de viabilidade pulmonar pós-morte

A doação pulmonar após parada cardiocirculatória tem sido estudada experimentalmente na obtenção de órgãos para transplante, porém a severa lesão isquêmica/reperfusão exigem métodos de preservação que permitam viabilidade pulmonar. A perfusão do enxerto com solução cristalóide hipotérmica via anterógrada (artéria pulmonar) é o método de preservação mais utilizado, porém esta via não perfunde a circulação brônquica, permitindo a retenção sanguínea neste território capaz de desencadear fenômenos de lesão de reperfusão. Isto nos levou a testar os efeitos da perfusão anterógrada versus retrógrada (via átrio esquerdo, capaz de perfundir a circulação brônquica) em modelo canino de transplante unilateral cujos pulmões foram extraídos 3 horas após parada cardiorrespiratória. Doze cães doadores foram sacrificados com tiopental sódico e mantidos à temperatura ambiente sob ventilação mecânica durante 3 horas, após as quais os animais foram randomizados e os blocos cardiopulmonares perfundidos via retrógrada (n = 6) ou anterógrada (n = 6) com solução de Euro-Collins modificada e extraídos. Os receptores (n = 12) foram anestesiados, pneumonectomizados e submetidos a transplante pulmonar esquerdo recebendo enxertos perfundidos por via retrógrada (grupo I) ou anterógrada (grupo II). Após a reperfusão do enxerto, os animais foram mantidos sob ventilação mecânica (FiO2 = 1) por 6 horas, sendo então sacrificados. Durante este período obtiveram-se medidas hemodinâmicas e gasometrias arteriais, além de amostras de tecido pulmonar para dosagem de ATP intracelular. As medidas hemodinâmicas não diferiram entre os grupos. Nos animais do grupo I a PaO2 e PaCO2 foram superiores às do grupo II (p = 0,016 e p = 0,008, respectivamente). O ATP intracelular não diferiu entre os grupos, embora tenha se reduzido nas amostras obtidas na extração do enxerto do doador quando comparados aos valores após a reperfusão (p = 0,01) e ao término do período de avaliação (p = 0,01). Os autores concluem que, neste modelo experimental, a perfusão retrógrada hipotérmica resulta em função superior do enxerto após 3 horas de isquemia normotérmica sob ventilação mecânica.

Iron accumulation in lung allografts after transplantation

Lung transplantation has become a therapeutic option for end-stage pulmonary diseases, but after transplantation, infections and obliterative bronchiolitis (OB) are major causes of long-term morbidity and mortality. OB is a fibroproliferative disease, of poorly understood etiology, characterized by an irreversible decline in allograft function. Because diseases with tissue iron overload are characterized by fibrosis and end-organ failure, we studied the iron concentrations in BAL fluid and lung tissue in 10 lung allograft patients. BAL fluid revealed significantly elevated iron concentrations in allograft patients compared with five normal volunteers (135+/-16.54 micromol/L vs 33.65+/-7.48 micromol/L, respectively). Prussian blue staining of biopsy specimens of lung allograft tissue revealed an accumulation of iron primarily in alveolar macrophages. Immunohistochemical stains for ferritin revealed accumulation of the protein in macrophages, interstitium, vascular walls, and bronchiolar epithelium. Iron studies of the blood (serum ferritin and iron concentrations) revealed no evidence for systemic iron overload. In conclusion, patients with pulmonary allografts appear to have elevated concentrations of iron in lung tissue. This iron overload may place the allografts at increased risk of metal-mediated injury and fibrosis.

Protection of isolated lung from reperfusion injuries by rinsing with high colloidal osmotic solution with deferoaxmine

We examined the efficacy of rinsing isolated lungs subjected to prolonged hypothermic storage with a high colloidal osmotic pressure solution prior to ex vivo blood reperfusion in order to preserve physiologic functions, suppress peroxidation of mitochondrial membranes, and inhibit infiltration of neutrophils. Isolated rabbit lungs were flushed with a Rinse-1 solution (289 mOsm/kg H2O) to remove remaining blood and immersed in physiologic saline at 8 degrees C for 24 hr. The control group received blood reperfusion immediately after storage; the Rinse-1 group was rinsed with Rinse-1 solution before blood reperfusion and the Rinse-2 group with Rinse-2 solution (312 mOsm/kg H20) including deferoxamine. Reperfused blood was passed through an artificial membranous lung to reduce oxygen tension (PO2) to the venous level, and time-dependent changes in airway pressure (AWP), pulmonary artery pressure (PAP), and PO2, as a measure of gas-exchange capability were examined. We estimated the lipid peroxide level in mitochondrial membranes as thiobarbituric acid-reactive substances (TBARS), i.e., malonedialdehyde, and neutrophil infiltration into lung tissue by measuring myeloperoxidase activity after 60 min of blood reperfusion. The PO2 was significantly higher in both rinsed groups compared with the control, while neither AWP nor PAP was significantly different in the three treatment groups. Both mitochondrial TBARS and myeloperoxidase activity were significantly higher in the control group compared with either rinsed group. These results indicate that rinsing stored lungs with a solution of high colloidal osmotic pressure prior to blood reperfusion was effective in preserving physiologic function and inhibiting neutrophil infiltration. Addition of deferoxamine was markedly effective in reducing TBARS formation and lessening reperfusion injury of stored lungs.

The effect of a synthetic hexadentate iron chelator (CP130) and desferrioxamine on rabbit kidneys exposed to cold and warm ischaemia

The effect of CP130 (a synthetic hexadentate pyridinone iron chelator) on the formation of two markers of lipid peroxidation (TBA-reactive material and Schiff's bases) in rabbit kidneys following a 72 h period of cold (0-4 degrees C) ischaemia was investigated by either adding CP130 to the flush/storage solution (hypertonic citrate solution) or by administering the agent intravenously 15 min before removal of the organs. In both cases, CP130 blocked the adverse rises in lipid peroxidation caused by ischaemia and subsequent reoxygenation of the homogenates in vitro. Both CP130 and desferrioxamine (DFX) (administered intravenously 15 min before ischaemia and 5 min before reperfusion) were also found to significantly reduce post-ischaemic rates of in vitro lipid peroxidation in kidneys rendered warm ischaemic for 90 min followed by reperfusion for 5 or 60 min in situ. Kidneys exposed to warm ischaemia and reperfusion developed interstitial and intracellular oedema, congestion and haemorrhage. DFX administration had little effect on the histological outcome, whereas CP130 significantly reduced interstitial oedema (at 5 min reperfusion compared to the DFX-treated group), intracellular oedema (at 60 min reperfusion compared to the DFX-treated group) and congestion (at 5 min reperfusion compared with a control group not given any agent). It is concluded that while CP130 and DFX exhibited similar antioxidant properties, CP130 provided better protection from ischaemia/reperfusion injury at the histological level. Synthetic iron chelators may therefore be of benefit in clinical organ transplantation by protecting against tissue damage caused by prolonged ischaemia.