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Ann Thorac Surg 1995;60:1015-1020
© 1995 The Society of Thoracic Surgeons

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Original Articles: Cardiovascular

Perioperative Donor Bone Marrow Infusion Augments Chimerism in Heart and Lung Transplant Recipients

Pittsburgh Transplantation Institute and the Departments of Surgery and Pathology, University of Pittsburgh, Pittsburgh, Pennsylvania

	Abstract

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 
Background. We and others have demonstrated that a low level of donor cell chimerism was present for years after transplantation in tissues and peripheral blood of heart and lung recipients; it was associated, in the latter, with a lower incidence of chronic rejection. To augment this phenomenon, we initiated a trial combining simultaneous infusion of donor bone marrow with heart or lung allotransplantation.

Methods. Between September 1993 and January 1995, 15 nonconditioned patients received either heart (n = 10) or lung (n = 5) allografts concurrently with an infusion of unmodified donor bone marrow (3.0 x 10⁸ cells/kg), and were maintained on an immunosuppressive regimen consisting of tacrolimus and steroids.

Results. There was no complication associated with the infusion of donor bone marrow. Chimerism was detectable in 73% of bone marrow--augmented patients up to the last sample tested. Of the 5 control recipients who did not receive bone marrow infusion, only 1 had detectable chimerism by flow on postoperative day 15, which dwindled to an undetectable level by postoperative day 36. None of the patients had evidence of donor-specific immune modulation by mixed lymphocyte reaction.

Conclusions. The combined infusion of donor bone marrow and heart or lung transplantation, without preconditioning of the recipient, is safe and is associated with an augmentation of donor cell chimerism.

	Introduction

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 
See also page 1020.

We and others have recently demonstrated that a low level of donor cells was detectable in the peripheral blood and tissues of long-surviving recipients of liver [1], kidney [2], heart [3], lung, and heart-lung [4] allografts. This phenomenon of donor cell chimerism, which occurs by seeding of the host's tissues with cells from the graft [5, 6], was associated with a lower incidence of chronic rejection in lung recipients [4]. To augment donor cell chimerism, we initiated a prospective trial combining the simultaneous infusion of unmodified donor bone marrow and transplantation of heart or lung allografts into nonconditioned recipients. Reported herein is the outcome of the first 15 patients in this study.

	Patients and Methods

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 
Between September 1993 and January 1995, 15 patients received combined infusion of donor bone marrow and transplantation of either heart (n = 10) or lung allografts (n = 5). The mean age of the recipients was 46.3 ± 9.1 years (range, 23 to 57 years) with a mean follow-up of 175 ± 102 days. These patients, all primary transplant recipients of cadaveric organs, were not conditioned by cytoablative or cytoreductive regimen before transplantation. Furthermore, all recipients had a panel reactive antibody titer of less than 10%, and none had a positive lymphocytotoxic crossmatch. The mean number of HLA mismatches was 4.5 ± 1.2 (range, 3 to 6), with no patient having complete HLA compatibility with the donor.

Bone Marrow Preparation and Infusion
Details of bone marrow preparation are described elsewhere [7]. Briefly, thoracolumbar vertebrae were retrieved from the donor. Marrow cells from chipped-off cancellous bone were passively released into a processing medium, filtered, washed, and resuspended in a suspension medium at a concentration of 2 x 10⁷ cells/mL. The cell suspension was stored at 4°C until infusion. Cell viability was determined by trypan blue dye exclusion, and samples of processed bone marrow cells were retained for microbial testing and routine progenitor cell assays. When the recipient was ready to receive bone marrow, a total of 3.0 x 10⁸ unmodified cells/kg of body weight were resuspended in 200 mL of the suspension medium and infused over a period of 15 to 20 minutes via a central venous line. The bone marrow was usually infused between 6 to 10 hours after revascularization of the transplanted organ.

Immunosuppression
Immunosuppression consisted of tacrolimus (FK506 [Prograf]; Fujisawa USA, Deerfield, IL) and steroids, as previously described [8]. During the first postoperative month, the dosage of tacrolimus was targeted to maintain whole blood trough levels of 15 to 20 ng/mL which, depending on the side effects and history of rejection, was gradually reduced to achieve levels of 5 to 15 ng/mL. Methylprednisolone (1 g) was given intraoperatively before revascularization of the organ. Except in the first heart recipient, this was followed in all other patients by a short course of steroid recycle starting on postoperative day (POD) 1 with 200 mg/day and tapering to 20 mg/day by POD 5. Further steroid reductions were individually tailored according to allograft function. Azathioprine was added if there was recurrent or recalcitrant rejection, or when renal dysfunction necessitated the administration of a lower than required dose of tacrolimus. Rejection was treated initially with steroid boluses (1 g methylprednisolone/day x 3), whereas OKT3 was reserved for steroid-resistant rejection.

In Vitro Monitoring
Mononuclear cells from recipients' peripheral blood (PBMC) were obtained preoperatively and biweekly in the first postoperative month, and bimonthly thereafter for detection of donor cells and for immunologic monitoring.

Detection of Chimerism
FLOW CYTOMETRY.
For immunocytochemical staining, primary mouse--anti-human monoclonal antibodies directed against the polymorphic epitopes of either HLA class I or class II (to distinguish donor from recipient HLA alleles) were used. These primary monoclonal antibodies were labeled by either fluorescein isothiocyanate- or phycoerythrin-conjugated goat--anti-mouse secondary antibodies. The specificity and optimal dilution of these antibodies were determined using donor splenocytes and the recipient's pretransplantation PBMC. Single or two-color flow cytometric methods were used to identify the donor cells and their lineage, respectively. Fifty thousand events were acquired at each determination, and the frequency of donor cells less than 0.5% was considered below the reliable detection threshold.

POLYMERASE CHAIN REACTION.
In addition to the flow cytometric analysis, polymerase chain reaction, as previously described [1, 3, 5], was used for detection of donor DNA in the recipient's PBMC. This method is more sensitive than the flow cytometric technique: it can reliably detect one donor cell within 10⁴ to 10⁵ recipient cells [7]. Oligonucleotides for either the sex determining region of the Y chromosome or the appropriate mismatched HLA alleles were used as primers.

Immune Monitoring
The in vitro immune status of the recipients, before and after transplantation, was assessed by the proliferative response of their PBMC to mitogens (concanavalin A, phytohemagglutinin), and recall antigens (tetanus toxoid) by mixed lymphocyte reactions (MLR) and by cell-mediated lymphocytotoxicity assays. The MLR cultures were carried out using -irradiated donor splenocytes and third-party PBMC as stimulators (5 x 10⁴ cells), and recipient PBMC as responders (5 x 10⁴ cells). The cells were cultured at 37°C for 6 days in 5% CO₂ in air. (³H)-thymidine (1 µCi) was added to each well at the beginning of the final 20 hours, and its degree of incorporation was determined by liquid scintillation counting. For cell-mediated lymphocytotoxicity assays, phytohemogglutinin-activated ⁵¹Cr-labeled donor splenocytes and third-party PBMC were used as targets to evaluate the effector function of 5- to 6-day MLR-cultured recipient's PBMC. Various effector:target ratios ranging from 10:1 to 40:1 were used.

	Results

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 
Clinical Course
BONE MARROW AUGMENTED PATIENTS.
The infusion of donor bone marrow was well tolerated. None of the 15 recipients had graft-versus-host disease or complications related to the infusion of donor bone marrow. All patients, except 1, are alive with good allograft function (Table 1). The single death occurred in a heart recipient (patient 5) who died at home of a pulmonary embolus on POD 267. One week before his death, a routine right heart catheterization revealed normal cardiac function. At autopsy, there was no evidence of acute or chronic rejection in the transplanted heart (Fig 1). In 1 heart recipient (patient 10), who had been receiving aspirin preoperatively, a duodenal perforation developed on POD 3. In another heart recipient (patient 1), a benign duodenal ulcer developed on POD 237 that was successfully treated, whereas an additional heart recipient (patient 8) had Acinetobacter sepsis from a pneumonia on POD 92, which resolved after appropriate therapy.

View larger version (146K): [in this window] [in a new window]   Fig 1. . Histopathology of an endomyocardial biopsy specimen of a bone marrow and heart transplant recipient obtained after death at 267 days after transplantation. There was no cellular infiltration, suggesting that the death of this patient was due to nonimmunologic causes. Although the exact cause of death is still unknown, a relatively large thromboembolus in the pulmonary artery was detected at autopsy. (x 40 before 51% reduction.)

CONTROLS.
Heart or lung recipients for whom bone marrow was not available, due to our inability to obtain permission to retrieve cadaveric vertebral bodies, were used as contemporaneous controls. All 4 heart recipients are alive with good graft function, whereas the single lung recipient (patient 20) died on POD 104 due to complications related to preservation injury. This lung recipient required perioperative support with an extracorporeal membrane oxygenator because of primary graft failure.

Rejection
In the 10 heart-bone marrow recipients, the rate of rejection (grade 3A [9]) during the first 100 days after transplantation was 0.5 episodes, as compared with 1.0 (p = 0.27 by Fisher's exact test) in a historical control group of 26 heart recipients, who received an identical immunosuppressive regimen without bone marrow infusion. Only 1 heart recipient (patient 5), who did not receive steroid induction during the perioperative period (no steroid recycle during the first 5 postoperative days), had steroid-resistant rejection that required a 5-day course of OKT3 for its resolution. Furthermore, 3 additional heart recipients required azathioprine because of persistent low-grade ( grade 2) rejection and high serum creatinine levels that precluded the use of therapeutic doses of tacrolimus. Of the 5 lung-bone marrow recipients, 3 had mild to moderate rejection (grade > II [10]) on POD 11, 32, and 53 respectively, whereas 2 had a rejection-free postoperative course.

Donor Chimerism
Detection of donor cells was feasible in all bone marrow--augmented and nonaugmented patients by either flow cytometry or polymerase chain reaction. Control patients had no evidence of donor-cell chimerism in their PBMC at the most recent sample tested (Table 2). On the contrary, 11/15 study patients (73%) exhibited stable donor cell chimerism for up to 220 days after transplantation. It must be emphasized, however, that bone marrow--augmented recipients who were negative by polymerase chain reaction for donor cell chimerism in the last sample tested were positive in all previous analyses.

	Comment

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

The clinical use of donor bone marrow to prolong the survival of organ allografts was first attempted in kidney transplant recipients. Monaco and associates [15] first reported the use of antilymphocyte globulin and delayed (25 days after organ transplantation) donor bone marrow infusion in a kidney transplant recipient. The patient had no rejection during the postoperative follow-up until she died 8 months after transplantation of fatal peritonitis, secondary to perforated sigmoid diverticulitis. There was evidence of donor red cell chimerism; however, it did not persist after the first month, and no white cell chimerism was detected for up to 2 months after transplantation. Barber and associates [16] used a similar regimen in recipients of cadaveric donor kidneys who were preconditioned with antilymphocyte globulin, cyclosporine, azathioprine, and prednisone before adjuvant donor bone marrow infusion. Graft survival in the bone marrow--augmented patients was significantly better than in contemporaneous controls, and other clinical evidence of benefit was also present, including a reduced need for immunosuppression and a lower incidence of rejection in bone marrow--augmented chimeric recipients. Furthermore, donor cell chimerism was detected in 50% to 56% of patients 3 to 12 months after transplantation [17]. However, using a similar approach, Rolles and colleagues [18] were unable to show any distinct advantage that was afforded by delayed bone marrow transplantation to liver allograft recipients.

In 1984, Kahn and co-workers [19] reported the combined simultaneous infusion of donor bone marrow to 6 heart transplant recipients who were preconditioned (7 to 13 days earlier) with a total of 5.4 to 6.0 Gy of total lymphoid irradiation. Four patients died within 7 months of either primary graft failure (n = 1), chronic rejection (n = 1), or infection (n = 2). Furthermore, in the 2 patients who survived for 2 to 4 years after transplantation, donor-specific hyporeactivity (by MLR) was evidenced in 1, whereas it was not tested in the other [19]. The higher incidence of infection in patients in this study was attributed to a combination of high dose of steroids and total lymphoid irradiation.

These clinical studies were based on the premise that ``space'' needs to be created by preconditioning of the host with cytoreductive or cytoablative therapy, thus allowing for engraftment of donor bone marrow with subsequent establishment and perpetuation of chimerism. However, we and others have recently demonstrated that donor chimerism is a naturally occurring phenomenon after transplantation of solid organs, including the liver [1], kidney [2], heart [3], and lung [4]. This low level of donor cell chimerism was present in all long-term surviving kidney [2] and liver [1] recipients. Its beneficial effects were most noticeable in lung allograft recipients, in whom donor cell chimerism was associated with a lower incidence of bronchiolitis obliterans [4]. These observations provided the foundation for the initiation of the current study, in which unmodified MHC-mismatched donor bone marrow cells were infused into heart or lung recipients at the time of organ placement without any preconditioning of that host or deviation from the routine drugs and their therapeutic doses that were required for maintenance of adequate immunosuppression.

The preliminary data from this pilot study indicate that the infusion of unmodified donor bone marrow concurrently with heart or lung transplantation is safe, and is associated with an increased level of donor cell chimerism. Furthermore, the early immunologic events after cardiac transplantation appear to have been altered by the infusion of donor bone marrow. Although not statistically significant, there was a trend toward a lower incidence of rejection within the first 100 days after transplantation in the bone marrow--augmented heart recipients as compared with similarly treated historical controls. However, there was no in vitro evidence of donor-specific hyporeactivity in the serial MLR analysis performed during the first 6 months after transplantation.

Although the eventual effect of the augmented chimerism remains speculative, it is conceivable that its presence would enhance the acceptance and survival of the graft and reduce the incidence of chronic rejection.

	Acknowledgments

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 
We thank Michael Amaya, BSN, Ann Lee, MSN, Terri L. Rapp, BSN, Jan D. Manzetti, PhD, Gerene S. Bauldoff, MSN, and Wendy Donato-Deis, BSN, for their clinical assistance; Troy S. Seskey, BS, Joshua E. Phipps, BS, and Charles M. Vasko for processing bone marrow and blood samples for chimerism study; Mary C. Pavlick, BA, and Richard A. Banas, MS, for their help in immune monitoring; Merrit L. Lutz for her help with data collection; Jo B. Harnaha, BA, for her help with preparation of the manuscript; and Rhonda J. White and Aurelia M. Tambourine for their excellent secretarial assistance.

Support in part by the American College of Surgeons Faculty Fellowship to Si M. Pham, and National Institutes of Health grant DK 29961 to Thomas E. Starzl.

	Footnotes

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 
Presented at the Thirty-First Annual Meeting of The Society of Thoracic Surgeons, Palm Springs, CA, Jan 31--Feb 2, 1995.

Address reprint requests to Dr Pham, Suite C-700, PUH, 200 Lothrop St, Pittsburgh, PA 15213.

	References

Top Footnotes Abstract Introduction Patients and Methods Results Comment Acknowledgments References

 

1. Starzl TE, Demetris A, Thrice M, et al. Systemic chimerism in human female recipients of male livers. Lancet 1992;340: 876–77.[Medline]
2. Starzl TE, Demetris AJ, Trucco M, et al. Chimerism and donor specific nonreactivity 27 to 29 years after kidney allotransplantation. Transplantation 1993;55:1272–7.[Medline]
3. Schlitt HJ, Hundrieser J, Hisanaga M, et al. Patterns of donor-type microchimerism after heart transplantation. Lancet 1994;343:1469–71.[Medline]
4. Keenan RJ, Zeevi A, Banas R, et al. Microchimerism is associated with a lower incidence of chronic rejection after lung transplantation. J Heart Lung Transplant 1994;13:532.
5. Starzl TE, Demetris AJ, Murase N, et al. Cell migration, chimerism and graft acceptance. Lancet 1992;339:1579–82.[Medline]
6. Starzl TE, Demetris AJ, Trucco M, et al. Cell migration and chimerism after whole organ transplantation. Hepatology 1993;17:1127–52.[Medline]
7. Fontes P, Rao AS, Demetris AJ, et al. Bone marrow augmentation of donor-cell chimerism in kidney, liver, heart, and pancreas islet transplantation. Lancet 1994;344:151–5.[Medline]
8. Armitage JM, Kormos RL, Morita S, et al. Clinical trial of FK506 immunosuppression in adult cardiac transplantation. Ann Thorac Surg 1992;54:205–10.[Abstract]
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12. Ildstad ST, Sachs DT. Reconstitution with syngeneic plus allogeneic or xenogeneic bone marrow leads to specific acceptance of allografts or xenografts. Nature 1984;307:168–70.[Medline]
13. Slavin S, Strober S, Fukes Z, et al. Induction of specific tissue transplantation tolerance using fractionated total lymphoid irradiation in adult mice: long-term survival of allogeneic bone marrow and skin grafts. J Exp Med 1977;146:34–48.[Abstract/Free Full Text]
14. Caridis DT, Liegeois A, Barret I, et al. Enhanced survival of canine renal allografts of ALS-treated dogs given bone marrow. Transplant Proceed 1973;5:671–4.
15. Monaco AP, Clark AW, Wood ML, et al. Possible active enhancement of a human cadaver renal allograft with anti-lymphocyte serum (ALS) and donor bone marrow: case report of an initial attempt. Surgery 1976;79:384–92.[Medline]
16. Barber WH, Mankin JA, Laskow DA, et al. Long-term results of a controlled prospective study with transfusion of donor specific bone marrow in 57 cadaveric renal allograft recipients. Transplantation 1991;51:70–5.[Medline]
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This Article Abstract Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Si M. Pham Robert J. Keenan Robert L. Kormos Akihiko Kawai Brack G. Hattler Robert L. Hardesty Bartley P. Griffith Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Pham, S. M. Articles by Griffith, B. P. Search for Related Content PubMed PubMed Citation Articles by Pham, S. M. Articles by Griffith, B. P. Related Collections Related Article