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Ann Thorac Surg 2001;72:709-713
© 2001 The Society of Thoracic Surgeons

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Original article: cardiovascular

Improved outcome with organs from carbon monoxide poisoned donors for intrathoracic transplantation

^a Transplant Unit, Papworth Hospital, Papworth Everard, Cambridgeshire, United Kingdom

Accepted for publication May 1, 2001.

Address reprints to Mr Luckraz, Papworth Hospital, Papworth Everard, Cambridgeshire CB3 8RE, United Kingdom
e-mail: heyman.luckraz{at}papworth-tr.anglox.nhs.uk

	Abstract

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Background. The success of intrathoracic organ transplantation has lead to a growing imbalance between the demand and supply of donor organs. Accordingly, there has been an expansion in the use of organs from nonconventional donors such as those who died from carbon monoxide poisoning. We describe our experience with 7 patients who were transplanted using organs after fatal carbon monoxide poisoning.

Methods. A retrospective study of the 1,312 intrathoracic organ transplants between January 1979 and February 2000 was completed. Seven of these transplants (0.5%) were fulfilled with organs retrieved from donors after fatal carbon monoxide poisoning. There were six heart transplants and one single lung transplant. The history of carbon monoxide inhalation was obtained in all of these donors.

Results. Five of 6 patients with heart transplant are alive and well with survival ranging from 68 to 1,879 days (mean, 969 ± 823 days). One patient (a 29-year-old male) died 12 hours posttransplant caused by donor organ failure. The patient who had a right single lung transplant did well initially after the transplant, but died after 8 months caused by Pneumocystis carinii pneumonia. All those recipients who were transplanted from carbon monoxide poisoned donors and ventilated for more than 36 hours, survived for more than 30 days. Moreover, these donors were assessed and optimized by the Papworth donor management protocol.

Conclusions. Carbon monoxide poisoned organs can be considered for intrathoracic transplantation. In view of the significant risk of donor organ failure, a cautious approach is still warranted. Ideally, the donor should be hemodynamically stable for at least 36 hours from the time of poisoning and on minimal support. A formal approach of invasive monitoring and active management further improves the chances of successful outcome.

	Introduction

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Currently, there are nearly 600 patients awaiting intrathoracic organ transplant in the United Kingdom. During the past year, only 390 such transplants were carried out in the 9 designated transplant centers [1]. Furthermore, up to 30% of patients on the waiting list are reported to die while waiting for an appropriate organ [2]. This is mainly caused by a shortage of donor organs, hence the need to explore nonconventional donors. One such group is the victims of carbon monoxide (CO) poisoning. In 1998, 744 deaths were registered from CO poisoning in the United Kingdom, most of which (80%) were within the accepted age group for organ donation [3].

Although there have been reports of successful solid organ transplantation using organs from CO-poisoned donors, there have also been reports of donor organ failure resulting in early recipient death. Thus, the use of these organs for transplantation remains controversial, as there is very little data to draw any firm conclusions. In a recent survey, el Oakley and colleagues [4] reported that only 25% of British surgeons would consider using intrathoracic organs from CO-poisoned donors for transplantation. Furthermore, a 35% mortality has been reported by Tsui and colleagues [5] when CO-poisoned organs were used for heart or lung transplants, or heart and lung transplants. We describe our single center experience with CO-poisoned organs and review the data reported in the literature so far.

	Material and methods

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Methods
A retrospective review was carried out on prospectively collected data of all patients who had undergone intrathoracic organ transplantation at our institution. Since the conception of the program in 1979, 1,312 intrathoracic organ transplants have been completed, including six heart transplants and one right single lung transplant performed from donors who had fatal CO poisoning. The first CO-poisoned heart donor in our series was simply accepted on a reasonable blood pressure and visual inspection of the heart. All subsequent donors were rigorously assessed and managed according to the Papworth donor management protocol (Tables 1 and 2) [6].

The mean age of the 6 heart transplant recipient group was 38 ± 14.4 years, 5 of whom were males. Five of the recipients are still alive with survival ranging from 68 to 1,879 days (969 ± 823 days). Although the first donor was ventilated for only 8 hours before organ retrieval, the remaining donors were ventilated for at least 72 hours (96 ± 17 hours). Their electrocardiograms were normal. Postoperatively, the heart transplant recipients were extubated on average within 13 hours of their operation. Their hospital stay varied from 12 to 48 days (19.2 ± 15.9 days). The longest hospital stay was a result of postoperative complication of sternal wound infection.

The heart recipients have had an average of 10 cardiac biopsies, with grade 1A rejection occurring in two biopsies. There was no clinical or histologic evidence of tissue damage as a sequela of exposure to carbon monoxide.

The lung transplant patient was a 56-year-old male who had cryptogenic fibrosing alveolitis and underwent right single lung transplant in November 1998. The donor was ventilated for 36 hours and the gas exchange before organ explant, on 30% inspiratory oxygen, was PO₂ to 17.4 KPa and PCO₂ to 4.4 KPa. The donor chest radiograph was normal. The histology of the unused left lung revealed foci of mononuclear inflammatory cell infiltrate around the small airways, but clear alveolar spaces. These changes were nonspecific and were not directly related to carbon monoxide inhalation.

Postoperatively the patient was extubated within 3 hours with PO₂ to 12.0 KPa and PCO₂ 6.1 KPa on 60% FiO₂. His transbronchial biopsies at 1 and 2 months were unremarkable. Unfortunately his 6-month biopsy revealed granulomatous changes, which were later confirmed to be caused by Pneumocystis carinii. He died at 227 days postoperatively of acute respiratory distress syndrome secondary to bronchopneumonia.

The data from the 7 transplant recipients and their respective donors are summarized in Tables 3 and 4.

	Comment

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Carbon monoxide directly damages the tissues by its effect on oxygen delivery leading to hypoxia and indirectly through the production of oxygen free radicals, which oxidize nucleic acids [13, 14]. Turino [15] suggested that the organs most sensitive to the CO damage are the brain and the myocardium. At the myocardial level, CO binds with myoglobin and interferes with the oxygen transport to muscle mitochondria [16]. At the cellular level, the injury to the myocardium can be summarized as mitochondrial swelling, loss of limiting membrane, necrosis of the myofibrils, separation of intercalated discs, increase in lipid droplets, and edema of small arteries with blister formation [17]. In the lungs CO damage leads to congestion, edema, hemorrhage [18], endothelial cells swelling, and depletion of lamellar bodies in type II cells [19]. Parving and colleagues [20] also demonstrated an increase in vascular permeability by using radiolabelled I¹³¹.

There is, however, a poor correlation between blood carboxy-hemoglobin level, tissue carboxy-hemoglobin level, and the degree of organ damage [21]. Thus, the best way to assess the suitability of CO-poisoned organs is not the blood carboxy-hemoglobin level at admission and thereafter, but the pulmonary gas exchange and hemodynamic stability several hours after the injury.

There have been 12 reported cases of heart transplant [22–29] and 1 case of lung transplant [22] with CO-poisoned organs in the literature (Table 5). The lung transplant was successful, with improved clinical status in the patient who was still alive after 8 months [22]. Four early (30-day) and 2 late deaths were reported in the heart transplant group. Two of the early deaths were directly related to myocardial dysfunction secondary to carbon monoxide exposure. The first death was described by Karwande and colleagues [23] in 1989 when a 17-year-old male donor heart was used after CO poisoning. This heart showed clinical evidence of myocardial dysfunction with episodes of ventricular fibrillation and cardiac arrests requiring direct current cardioversion before explant. The electrocardiogram showed nonspecific changes. The recipient survived for 4 days but succumbed to poor ventricular function of the donor organ. The postmortem study of the heart revealed a dilated organ with petechial and confluent endocardial hemorrhages.

The late deaths were reported by Koerner and colleagues [24] and caused by adenocarcinoma of the pancreas 4 months posttransplant in 1 patient and multiorgan fungal sepsis at 10 weeks postoperatively in another.

Successful heart transplants from CO-poisoned donors were described by Iberer and colleagues [26], Roberts and colleagues [27], and Smith and colleagues [28]. The latter [28] recommended that CO-poisoned hearts being considered as donor organs should adhere to the following criteria for maximum success: (1) normal electrocardiogram and satisfactory echographic finding, (2) minimal rise in cardiac enzymes, (3) minimal inotropic support, (4) short ischemic time, and (5) avoidance of recipients with high pulmonary vascular resistance.

In our series, 1 of 6 heart transplant recipients died as a result of donor organ failure. This procedure was carried out in 1988, which took place before the introduction of the Papworth donor management protocol [6, 30–33], which is based on counteracting the pathophysiologic changes caused by brain stem death. Hence, the organ failure was probably caused by inadequate assessment and optimization. In the long-term survivors, the mean duration of ventilation of the donors (five hearts and one lung) was 86 ± 28 hours. This allowed time for irreversible organ damage to manifest when the donor was assessed for organ donation. These maneuvers provide a better assessment of the possible transplant organs. They also allow for better performance of borderline organs. Organs that fail to improve on this resuscitation protocol are rejected.

Organs from CO-poisoned donors can be used for intrathoracic transplantation. The decision to use these organs should not be based on the blood carboxy-hemoglobin levels but rather on the duration between injury and expected time of explantation (duration of donor ventilation), along with the hemodynamic performance of the heart, and the gas transfer for the lungs after appropriate resuscitation. The latter can be optimized by the Papworth donor management protocol. Hearts that require significant inotropic support despite optimization can be more readily rejected, whereas those that perform adequately on minimal inotropic support can be safely used.

	References

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