Long-term survival of an extremity composite tissue allograft with FK506-mycophenolate mofetil therapy.

BACKGROUND: High-dose tacrolimus (FK506) monotherapy has significantly prolonged rat hindlimb allograft survival. With an eye toward direct clinical application, we used a large-animal extremity composite tissue allograft model to assess the antirejection efficacy and systemic toxicity of combination FK506-mycophenolate mofetil (MMF) treatment. METHODS: Radial forelimb osteomyocutaneous flap transplants were performed between size-matched outbred pigs assigned to one of two groups: 5 control pigs received no immunosuppression and 9 animals received a once-daily oral FK506-MMF-prednisone regimen. Rejection was assessed by visual inspection of flap skin and was correlated with serial histopathologic examination of skin biopsy specimens. RESULTS: In all control pigs the flap was completely rejected on day 7. Of the 9 pigs receiving treatment, 3 died from pneumonia on days 29, 30, and 83 without signs of rejection and another died from gastric rupture on day 42 with persistent mild rejection. The remaining 5 animals were free of rejection at the end of the 90-day follow-up period (P < 0.005 vs controls). Overall, 5 pigs had pneumonia, 4 septic arthritis, 3 toe abscesses, and 5 diarrhea and decreased weight gain. CONCLUSIONS: Combination oral FK506-MMF treatment provided a superior antirejection effect but more produced more toxicity than that previously demonstrated with cyclosporin A-MMF therapy in our model. Our results suggest that reduction of FK506 or MMF doses might decrease both infectious and drug-specific side effects while still providing adequate prophylaxis against rejection.

Pharmacokinetic advantage of intra-arterial cyclosporin A delivery to vascularly isolated rabbit forelimb. I. Model development.

Effective antirejection therapy with minimal systemic morbidity is required if limb transplantation is to become a clinical reality. We investigated whether i.a. infusion of cyclosporin A (CSA) into the vascularly isolated rabbit forelimb will distribute drug homogeneously to the tissues and produce higher local drug levels than same-dose i.v. treatment, thereby improving the therapeutic index. CSA 4.0 mg/kg/day was infused continuously via osmotic minipump into either the right brachial artery (i.a. group) or jugular vein (i.v. group) of New Zealand rabbits. Ligation of all muscles at the right mid-arm level was performed in the i.a. group to eliminate collateral circulation and simulate allografting, while leaving bone and neurovasculature intact. On day 6, CSA concentrations were measured in skin, muscle, bone, and bone marrow samples taken from different compartments of the right and left forearms in the i.a. group and right forearm only in the i.v. group. There were no significant differences between compartmental CSA levels in all tissues examined on the locally treated, right side during i.a. infusion, indicating that drug streaming from the catheter tip is not occurring in our model. During i.a. infusion, mean CSA concentrations were 4- to 7-fold higher in the right limb than in the left limb in all four tissues examined. Tissue CSA levels in the left limb were equivalent to those achieved during i.v. infusion, but CSA concentrations in blood, kidney, and liver were higher during i.a. infusion. These favorable, preliminary, single-dose pharmacokinetic results warrant further investigation in our novel rabbit model.

Pharmacokinetic advantage of intra-arterial cyclosporin A delivery to vascularly isolated rabbit forelimb. II. Dose dependence.

A vascularly isolated rabbit forelimb model simulating conditions of composite tissue allografting was used to determine the regional pharmacokinetic advantage achievable in extremity tissue components during i.a. cyclosporin A (CSA) administration. CSA was infused continuously via osmotic minipump into the right brachial artery of New Zealand rabbits at multiple doses ranging from 1.0 to 8.0 mg/kg/day. On day 6, CSA concentrations were measured in aortic whole blood, as well as in skin, muscle, bone, and bone marrow samples from both right and left forelimbs. The variation of right-sided mean CSA concentrations with dose was tissue dependent and saturable in the case of skin and bone, whereas left-sided tissue concentrations correlated significantly with systemic blood levels. At 1.0 mg/kg/day, there were no significant differences between right and left mean CSA concentrations for all four tissues examined. However, with a doubling of the i.a. dose, huge increases in local tissue CSA concentrations were produced with only very modest increases in systemic whole-blood and tissue drug levels, resulting in a 4-fold regional advantage (right/left ratio of CSA concentrations) in bone and bone marrow, 7-fold in muscle, and 14-fold in skin. With further dose increases to 8.0 mg/kg/day, the regional advantage decreased to 4-fold in skin, increased to 9-fold in bone marrow, remained relatively constant in bone, and initially decreased and then increased to 9-fold in muscle. These favorable pharmacokinetic results suggest that reduced, local doses of CSA might be useful in preventing extremity composite tissue allograft rejection with decreased systemic drug exposure.

Pharmacokinetics of intra-arterial delivery of tacrolimus to vascularly isolated rabbit forelimb.

A vascularly isolated rabbit forelimb model simulating conditions of composite tissue allografting was used to determine the regional pharmacokinetic advantage achievable in extremity tissue components during i.a. tacrolimus (FK506) administration. FK506 was infused continuously via osmotic minipump into the right brachial artery of New Zealand rabbits at 0.05, 0.1, and 0.2 mg/kg/day. On day 6, FK506 concentrations were measured in aortic whole blood, heart, lung, liver, kidney, spleen, and fat, as well as in skin, muscle, bone, and bone marrow samples from both right and left forelimbs. The relative tissue concentrations of FK506 in descending order were [spleen approximately lung approximately kidney] > [heart approximately skin approximately muscle] > [fat approximately bone marrow] > [liver approximately bone approximately blood]. In marked contrast to previous results with i.a. cyclosporin A infusion, only a minimal regional advantage of local FK506 delivery (mean right/left concentration ratios 1.0-1.4) was obtained in all forearm tissues over the dose range studied. For each limb tissue, left-sided FK506 concentrations significantly correlated with systemic blood levels, and the left-sided tissue-to-whole-blood concentration ratio did not vary significantly with dose. We conclude that FK506 is pharmacokinetically inferior to cyclosporin A for continuous i.a. administration to the vascularly isolated rabbit forelimb, and hypothesize that this difference is the result of differences in the distribution of each drug within whole blood. Our findings suggest that, despite its demonstrated efficacy in experimental and clinical transplantation, FK506 would not be an appropriate immunosuppressant to deliver via the i.a. route for prevention of limb allograft rejection.

Long-term composite tissue allograft survival in a porcine model with cyclosporine/mycophenolate mofetil therapy.

BACKGROUND: Low-dose cyclosporine (CsA)/mycophenolate mofetil (MMF) therapy has significantly reduced the frequency of rejection and drug-induced side effects in rat hindlimb allograft recipients. With an eye toward direct clinical application, we developed a large-animal extremity composite tissue allograft model to assess the antirejection efficacy and systemic toxicity of combination CsA/MMF treatment. METHODS: Radial forelimb osteomyocutaneous flap transplants were performed between size-matched, outbred pigs assigned to one of two groups: 5 control pigs received no immunosuppression, and 10 pigs received a once-daily oral CsA/MMF/prednisone regimen. Rejection was assessed by visual inspection of flap skin and correlated with serial histopathologic examination of skin biopsies. RESULTS: In all control pigs, the flap was completely rejected on day 7. Of the 10 pigs receiving treatment, one died from pneumonia and an another from an anesthetic complication on days 19 and 30, respectively, without signs of rejection. Two flaps were lost on days 25 and 29 from severe rejection. Three pigs were free of rejection at the end of the 90-day follow-up period, and three had stable mild-to-moderate rejection at 90 days (P= 0.0007 vs. controls). White blood cell and platelet counts, serum creatinine values, and liver function tests remained normal in all animals receiving immunosuppressive therapy. CONCLUSIONS: Our results, to our knowledge, demonstrate for the first time that rejection can be significantly delayed in a large-animal composite tissue allograft model including skin using only orally administered agents dosed according to clinically relevant strategies without significant drug-specific systemic side effects.

Rapid histochemical identification of motor and sensory fascicles: preparation of solutions.

We report a rapid and inexpensive staining method for identification of motor and sensory fibers within 1 hour (intraoperatively). This method should be easy to use in any hospital where frozen histologic sectioning is available.

Fatty acid synthetase activity in Mycobacterium phlei: regulation by polysaccharides.

The multienzyme complex from Mycobacterium phlei which catalyzes the synthesis of long chain fatty acids from acetyl-CoA and malonyl-CoA requires a heat-stable fraction (stimulating factor, SF) for activity. Fractionation of heat-treated M. phlei extracts affords two stimulatory subfractions, one of which (SF(2)) can be replaced by FMN. The other (SF(1)) is further separable into 3 polysaccharides (PS(I), PS(II), and PS(III)). PS(I) contains about 95% 3-O-methylmannose and 5% mannose; the sugar composition of PS(II) and PS(III) is about 55% 6-O-methylglucose and 45% glucose for both. Each of the three purified polysaccharides, in combination with FMN, substitutes for the crude stimulating factor. The polysaccharides exert their effect on the fatty acid synthetase by lowering the K(m) for acetyl-CoA about 50-fold.