Historical references to the concept of human organ transplantation date back centuries and often cite the third century twin saints Cosmas and Damian, who are credited with the miraculous transplantation of the black leg of a deceased Ethiopian onto the body of a white recipient whose leg required amputation. This legend, which was memorialized by a famous painting, may seem fanciful, but no more so than the actual feat accomplished in the 1940s by the Russian physiologist Demikhov, who transplanted the head of one dog onto the neck of a second dog, with both the host and the donor head remaining alive and active for several days. It was Demikhov as well who experimented with canine pulmonary lobe transplantation and with heart-lung transplantation well before the era of cardiopulmonary bypass.¹ His technical prowess owed much to the prior work of Alexis Carrel, the French physiologist who won the Nobel Prize in 1912 for his pioneering work in developing techniques for end-to-end anastomosis of blood vessels and its use in the transplantation of whole organs.² In fact, the first “thoracic” organ transplant was described by Carrel in 1907, when he and his colleague Charles Guthrie performed a heterotopic heart-lung transplant onto the neck of a cat. When the graft died on the third day, Carrel attributed this to technical anastomotic problems, but he was probably witnessing a manifestation of acute rejection.³

It became obvious that lung transplantation posed unique obstacles. The lung is the only organ transplanted without reattachment of its systemic arterial blood supply (the bronchial arteries). Thus, one of the major anastomoses—the bronchial anastomosis—is rendered ischemic; it is also open to the external environment and very prone to infection. In addition, the lung is a fragile organ prone to injury and infection and also significantly more susceptible to rejection than other major organs.

Most experimental lung transplantations were conducted on a canine model. However, the dog, like other subprimate animals, is dependent on the Hering-Breuer reflex to maintain central respiratory control. With total denervation of both lungs, such as would occur with bilateral or unilateral lung transplantation and removal of the opposite lung, the dog cannot survive because of loss of the normal respiratory control mechanism. This problem made it difficult to assess the function of an experimentally transplanted lung when the animal was removed from the ventilator following transplantation. Only in a primate model, a complex and expensive undertaking, can the recipient animal remain alive for days or weeks solely on the function of transplanted lungs. In addition, as the authors can well attest, lung transplantation in a canine model is technically more challenging than in humans, partly because the atrial anastomosis tends to accumulate blood clots if there is any gap in the endothelial-to-endothelial apposition of the atrial anastomosis.

Early attempts at suppressing rejection included adrenocorticotropic hormone, cortisone, total body irradiation, and splenectomy. Hardy observed that survival in dogs undergoing single-lung transplantation could be prolonged for more than a week with the use of methotrexate and further extended to an average of 29 days when recipient animals were treated with azathioprine and cortisone.⁷

The ability of a transplanted lung to totally support an animal’s respiratory requirement was documented in the early 1960s in a model that involved ligation of the contralateral pulmo...