Relation between K+ leakage and damage to band 3 in photodynamically treated red cells

Interaction of photosensitizers with liposomes containing unsaturated lipid

Small unilamellar liposomes were made of dipalmitoyl-phosphatidylcholine and dioleoyl-phosphatidylcholine, and photosensitized by a symmetrically or an asymmetrically substituted glycosilated tetraphenyl-porphyrin derivative. As differential scanning calorimetry and electron paramagnetic resonance spectroscopy (EPR) revealed these porphyrin derivatives were localized in different depth within the lipid bilayer. Both porphyrin derivatives were able to induce photoreaction and consequent structural changes in the membrane. 5-, 12-, or 16-doxyl stearic acid labeled lipid bilayers were applied and the efficiency of photoinduced reaction was followed by the decay of their EPR signal amplitude. Light dose-dependent destruction of nitroxide radical proved to be dependent on the position of spin label. In this process the porphyrin localized in closer connection with the double bond of unsaturated fatty acid was more effective. EPR signal decay was also dependent on the unsaturated fatty acid content of the liposome and the oxygen saturation of the solvent.

Positively charged porphyrins: a new series of photosensitizers for sterilization of RBCs

BACKGROUND

Photodynamic treatment could be a way to inactivate pathogens in RBCs. The objective of this study was to characterize the virucidal activity and RBC-damaging activity of a series of cationic porphyrins. Using the most efficacious photosensitizer, various in-vitro human RBC quality variables and in-vivo RBC survival in Rhesus monkeys were evaluated.

STUDY DESIGN AND METHODS

RBCs, spiked with 5 log of extracellular VSV, were treated with porphyrins (25 micro mol/L) and red light (100 W/m2) and essayed for virucidal activity. In-vitro RBC quality variables were assessed during 5 weeks of storage in various ASs. In-vivo survival was investigated with autologous RBCs in Rhesus monkeys.

RESULTS

Tri-P(4) was by far the best sensitizer of a series tested, giving the least hemolysis under conditions that resulted in 5 log-kill of extracellular VSV. Under our experimental conditions, the percentage hemolysis in treated cells was 5.1 +/- 1.1 percent after 5 weeks of storage in SAG-M compared to 1.9 +/- 1.1 percent in the untreated control. Storage in AS-3 resulted hemolysis of 2.3 +/- 1.9 percent. With the exception of IgG binding and potassium leakage, RBC quality variables remained unchanged after photodynamic treatment. Addition of reduced glutathione (GSH) during treatment reduced IgG binding. The 24-hour recovery and T50 of treated RBCs in Rhesus monkeys were satisfactory.

CONCLUSION

Porphyrin Tri-P(4) may be a suitable photosensitizer for sterilization of RBCs. However, further exploration to optimize the method is necessary to reach clinically acceptable goals.

Additive effects of dipyridamole and Trolox in protecting human red cells during photodynamic treatment

BACKGROUND AND OBJECTIVES

Photodynamic treatment (PDT) of red blood cell (RBC) suspensions has been reported to result in virus inactivation, but also in deterioration of cell quality. Recently, we have demonstrated the potential usefulness of the reactive oxygen species scavenger dipyridamole in selectively protecting RBCs against the harmful side-effects of PDT. Unfortunately, dipyridamole-conferred protection against long-term photohaemolysis was incomplete. In the present study, dipyridamole was applied in combination with Trolox (a hydrophilic vitamin E analogue) in order to augment RBC protection.

MATERIALS AND METHODS

Leucodepleted RBC suspensions (30% haematocrit) were treated with 1,9-dimethylmethylene blue (DMMB) and red light, and the effect of inclusion of dipyridamole and Trolox was assessed on potassium leakage as well as on short-term and long-term photohaemolysis. Possible interference of the scavenger cocktail with virus inactivation was examined using extracellular pseudorabies virus (PRV).

RESULTS

Treatment of RBC with DMMB and red light resulted in enhanced potassium leakage and both short- and long-term haemolysis. Dipyridamole and Trolox showed additive protective effects against induction of potassium leakage and photohaemolysis, suggesting different protection mechanisms for the two scavengers. Combined inclusion of dipyridamole and Trolox did not interfere with efficacy of PRV inactivation.

CONCLUSIONS

Combined inclusion of dipyridamole and Trolox results in substantially improved selectivity of photodynamic treatment of RBC suspensions.