Pathogen inactivation of platelets with a photochemical treatment with amotosalen HCl and ultraviolet light: process used in the SPRINT trial

BACKGROUND

A photochemical treatment (PCT) system has been developed to inactivate a broad spectrum of pathogens and white blood cells in platelet (PLT) products. The system comprises PLT additive solution (PAS III), amotosalen HCl, a compound adsorption device (CAD), a microprocessor-controlled ultraviolet A light source, and a commercially assembled system of interconnected plastic containers.

STUDY DESIGN AND METHODS

A clinical prototype of the PCT system was used in a large, randomized, controlled, double-blind, Phase III clinical trial (SPRINT) that compared the efficacy and safety of PCT apheresis PLTs to untreated apheresis PLTs. The ability of multiple users was assessed in a blood center setting to perform the PCT and meet target process specifications.

RESULTS

Each parameter was evaluated for 2237 to 2855 PCT PLT products. PCT requirements with respect to mean PLT dose, volume, and plasma content were met. Transfused PCT PLT products contained a mean of 3.6 x 10(11) +/- 0.7 x 10(11) PLTs. The clinical process, which included trial-specific samples, resulted in a mean PLT loss of 0.8 x 10(11) +/- 0.6 x 10(11) PLTs per product. CAD treatment effectively reduced the amotosalen concentration from a mean of 31.9 +/- 5.3 micromol per L after illumination to a mean of 0.41 +/- 0.56 micromol per L after CAD. In general, there was little variation between sites for any parameter.

CONCLUSIONS

The PCT process was successfully implemented by 12 blood centers in the United States to produce PCT PLTs used in a prospective, randomized trial where therapeutic efficacy of PCT PLTs was demonstrated. Process control was achieved under blood bank operating conditions.

Clinical safety of platelets photochemically treated with amotosalen HCl and ultraviolet A light for pathogen inactivation: the SPRINT trial

BACKGROUND

A photochemical treatment (PCT) method utilizing a novel psoralen, amotosalen HCl, with ultraviolet A illumination has been developed to inactivate viruses, bacteria, protozoa, and white blood cells in platelet (PLT) concentrates. A randomized, controlled, double-blind, Phase III trial (SPRINT) evaluated hemostatic efficacy and safety of PCT apheresis PLTs compared to untreated conventional (control) apheresis PLTs in 645 thrombocytopenic oncology patients requiring PLT transfusion support. Hemostatic equivalency was demonstrated. The proportion of patients with Grade 2 bleeding was not inferior for PCT PLTs.

STUDY DESIGN AND METHODS

To further assess the safety of PCT PLTs, the adverse event (AE) profile of PCT PLTs transfused in the SPRINT trial is reported. Safety assessments included transfusion reactions, AEs, and deaths in patients treated with PCT or control PLTs in the SPRINT trial.

RESULTS

A total of 4719 study PLT transfusions were given (2678 PCT and 2041 control). Transfusion reactions were significantly fewer following transfusion of PCT than control PLTs (3.0% vs. 4.1%; p = 0.02). Overall AEs (99.7% PCT vs. 98.2% control), Grade 3 or 4 AEs (79% PCT vs. 79% control), thrombotic AEs (3.8% PCT vs. 3.7% control), and deaths (3.5% PCT vs. 5.2% control) were comparable between treatment groups. Minor hemorrhagic AEs (petechiae [39% PCT vs. 29% control; p < 0.01] and fecal occult blood [33% PCT vs. 25% control; p = 0.03]) and skin rashes (56% PCT vs. 42% control; p < 0.001) were significantly more frequent in the PCT group.

CONCLUSION

The overall safety profile of PCT PLTs was comparable to untreated PLTs.

Platelet dose consistency and its effect on the number of platelet transfusions for support of thrombocytopenia: an analysis of the SPRINT trial of platelets photochemically treated with amotosalen HCl and ultraviolet A light

BACKGROUND

The SPRINT trial examined efficacy and safety of photochemically treated (PCT) platelets (PLTs). PCT PLTs were equivalent to untreated (control) PLTs for prevention of bleeding. Transfused PLT dose and corrected count increments (CIs), however, were lower and transfusion intervals were shorter for PCT PLTs, resulting in more PCT than control transfusions. PLT dose was analyzed to determine the impact of the number of PLTs transfused on transfusion requirements.

STUDY DESIGN AND METHODS

Transfusion response was compared for patients with all doses of >or=3.0 x 10(11) and the complementary subset of patients with any dose of fewer than 3.0 x 10(11). Analyses included comparison of bleeding, number of PLT and red blood cell (RBC) transfusions, transfusion intervals, and CIs between PCT and control groups within each PLT dose subset.

RESULTS

Mean PLT dose per transfusion in the PCT group was lower than in the control group (3.7 x 10(11) vs. 4.0 x 10(11); p<0.001). More PCT patients received PLT doses of fewer than 3.0 x 10(11) (n=190) than control patients (n=118; p<0.01). Comparisons of patients receiving comparable PLT doses showed no significant differences between PCT and control groups for bleeding or number of PLT or RBC transfusions; however, transfusion intervals and CIs were significantly better for the control group.

CONCLUSIONS

When patients were supported with comparable doses of PCT or conventional PLTs, the mean number of PLT transfusions was similar. Lower CIs and shorter transfusion intervals for PCT PLTs suggest that some PLT injury may occur during PCT. This injury does not result in a detectable increase in bleeding, however.

Amotosalen photochemical inactivation of severe acute respiratory syndrome coronavirus in human platelet concentrates

summary.  A novel human coronavirus causing severe acute respiratory syndrome (SARS) emerged in epidemic form in early 2003 in China and spread worldwide in a few months. Every newly emerging human pathogen is of concern for the safety of the blood supply during and after an epidemic crisis. For this purpose, we have evaluated the inactivation of SARS‐coronavirus (CoV) in platelet concentrates using an approved pathogen inactivation device, the INTERCEPT Blood System. Apheresis platelet concentrates (APCs) were inoculated with approximately 10⁶ pfu mL⁻¹ of either Urbani or HSR1 isolates of SARS‐CoV. The inoculated units were mixed with 150 µm amotosalen and illuminated with 3 J cm⁻² UV‐A light. The viral titres were determined by plaque formation in Vero E6 cells. Mixing SARS‐CoV with APC in the absence of any treatment decreased viral infectivity by approximately 0·5–1 log₁₀. Following photochemical treatment, SARS‐CoV was consistently inactivated to the limit of detection in seven independent APC units. No infectious virus was detected after treatment when up to one‐third of the APC unit was assayed, demonstrating a mean log₁₀‐reduction of >6·2. Potent inactivation of SARS‐CoV therefore extends the capability of the INTERCEPT Blood System in inactivating a broad spectrum of human pathogens including recently emerging respiratory viruses.

Amotosalen interactions with platelet and plasma components: absence of neoantigen formation after photochemical treatment

BACKGROUND

The INTERCEPT Blood System (Baxter Healthcare Corp., and Cerus Corp.) is a photochemical treatment (PCT) process that uses amotosalen (S-59) and ultraviolet A (UVA) illumination to inactivate a broad spectrum of pathogens.

STUDY DESIGN AND METHODS

To evaluate the potential of the process to create neoantigens, the amounts of residual amotosalen and photoproducts present in PCT platelets (PLTs) and PCT plasma were quantified. The initial amount of amotosalen was 150 micromol per L. After illumination with 3 J per cm2 UVA and before transfusion, a compound adsorption device was used to substantially reduce the amounts of free amotosalen and unreactive photodegradation products. Patient serum samples from Phase III clinical trials were assayed by enzyme-linked immunosorbent assay (ELISA) for antibodies to potential amotosalen neoantigens.

RESULTS

After PCT, 15 percent of the starting amount of amotosalen remains bound to PLTs, and 15 to 22 percent remains bound to plasma components. The majority of bound amotosalen is associated with lipid. Less than 1 percent of PLT-bound amotosalen and approximately 2 percent of plasma-bound amotosalen can be extracted into the water-soluble protein fraction. In seven Phase III clinical trials, 523 patients received more than 8000 units of PCT PLTs or PCT plasma. None of the patients exhibited clinical or laboratory manifestations of neoantigenicity. Furthermore, no other alteration of PLT membrane proteins was identified based on testing for lymphocytotoxic antibodies and PLT-specific alloantibodies.

CONCLUSION

These results indicate that no neoantigens were detected by ELISA after PCT, suggesting that transfusion of PCT PLTs or PCT plasma does not induce adverse immunologic responses.

Polymerase chain reaction inhibition assay documenting the amotosalen-based photochemical pathogen inactivation process of platelet concentrates

BACKGROUND

The INTERCEPT Blood System (Baxter Healthcare Corp.) for platelets (PLTs) uses amotosalen-HCl (S-59) in conjunction with ultraviolet A (UVA) light to inactivate contaminating pathogens by modifying the nucleic acids of pathogens. The success of this photochemical treatment (PCT) process can be documented indirectly with a high-performance liquid chromatography assay measuring the photodegradation of amotosalen and measurement of the UVA light dose delivered by the illumination system.

STUDY DESIGN AND METHODS

To develop an assay that documents the success of PCT directly on the effector molecule DNA, the effect of PCT on PLT-derived mitochondrial DNA (mtDNA) was examined. mtDNA-specific polymerase chain reaction (PCR) assays were tested with regard to their susceptibility for PCT, their reliability in terms of PCR performance, and the absence of polymorphic sites in primer hybridization loci.

RESULTS

Suitable PCR amplification targets were found in the regions of 16S rDNA, cytochrome c oxidase I, and cytochrome c oxidase III of mitochondria. Amplicon sizes between 868 and 1248 bp gave consistent signals before PCT and complete inhibition of the PCR signal after PCT. Amplicons of less than 300 bp were found to be transparent to PCT.

CONCLUSION

Based on PCT-mediated mtDNA modifications in PLTs, a PCR inhibition assay was established with a large amplicon documenting the success of PCT and a small amplicon serving as an internal control.

Leishmania inactivation in human pheresis platelets by a psoralen (amotosalen HCl) and long-wavelength ultraviolet irradiation

BACKGROUND

Leishmania spp. are protozoans that cause skin and visceral diseases. Leishmania are obligate intracellular parasites of mononuclear phagocytes and have been documented to be transmitted by blood transfusion.

STUDY DESIGN AND METHODS

This study examines whether Leishmania can be inactivated in human platelet (PLT) concentrates by a photochemical treatment process that is applicable to blood bank use. Human PLT concentrates were contaminated with Leishmania mexicana metacyclic promastigotes or mouse-derived Leishmania major amastigotes and were exposed to long-wavelength ultraviolet (UV) A light (320-400 nm) plus the psoralen amotosalen HCl.

RESULTS

Neither treatment with amotosalen nor UVA alone had an effect on Leishmania viability; however, treatment with 150 micromol per L amotosalen plus 3 J per cm(2) UVA inactivated both metacyclic promastigotes and amastigotes to undetectable levels, more than a 10,000-fold reduction in viability.

CONCLUSIONS

This study demonstrates the effectiveness of photochemical treatment to inactivate Leishmania in PLT concentrates intended for transfusion. Both metacylic promastigotes, which represent the infectious form from the sand fly vector, and amastigotes, which represent the form that grows in mononuclear phagocytes, were extremely susceptible to photochemical inactivation by this process. Thus, the photochemical treatment of PLT concentrates inactivates both forms of Leishmania that would be expected to circulate in blood products collected from infected donors.

Therapeutic efficacy and safety of photochemically treated apheresis platelets processed with an optimized integrated set

BACKGROUND

This multicenter, randomized, controlled, double-blind Phase III clinical study evaluated the therapeutic efficacy and safety of apheresis platelets (PLTs) photochemically treated (PCT) with amotosalen and ultraviolet A light (INTERCEPT Blood System, Baxter Healthcare Corp.) compared with conventional apheresis PLTs (reference).

STUDY DESIGN AND METHODS

Forty-three patients with transfusion-dependent thrombocytopenia were randomly assigned to receive either PCT or reference PLT transfusions for up to 28 days.

RESULTS

The mean 1- and 24-hour corrected count increments were lower in response to PCT PLTs (not significant). When analyzed by longitudinal regression analysis, the estimated effect of treatment on 1-hour PLT count was a decrease of 7.2 x 10(9) per L (p = 0.05) and on 24-hour PLT count a decrease of 7.4 x 10(9) per L (p = 0.04). Number, frequency, and dose of PLT transfusions; acute transfusion reactions; and adverse events were similar between the two groups. There was no transfusion-associated bacteremia. Four PCT patients experienced clinical refractoriness; however, only one exhibited lymphocytotoxicity assay seroconversion. Antibodies against potential amotosalen-related neoantigens were not detected.

CONCLUSION

PCT PLTs provide effective and safe transfusion support for thrombocytopenic patients.

Evaluation of processing characteristics of photochemically treated pooled platelets: target requirements for the INTERCEPT Blood System comply with routine use after process optimization

To ensure good performance of pathogen inactivation with the INTERCEPT blood system, specific target requirements must be met for platelet dose, volume, plasma content and residual red blood cells (RBCs) prior to photochemical treatment (PCT). A two-arm in vitro study was conducted to compare quality parameters of pooled platelet concentrates (PCs), either treated (test units) or nontreated (control units). PCs meeting European requirements were evaluated with reference to their compliance with INTERCEPT guard bands. Of 50 PCs (25 tests and 25 controls) meeting European quality requirements, 24% (three test and three controls units) did not reach INTERCEPT requirements, particularly in terms of sufficient volumes and RBC contamination. The buffy-coat optimization procedure assessed prior to this study ensured plasma contents well within target limits of 30 to 45%. Due to PCT-related in-process loss of 11% in volume (34.38 +/- 3.94) and in platelet dose (0.41 +/- 0.14), the mean platelet dose was significantly (P < 0.001) lower in test units: 3.1 +/- 0.3 versus 3.6 +/- 0.4 x 10(11). After treatment, six of the overall 25 test units (25%) would not have met the European guideline for platelet dose (3.0 x 10(11)). Before implementation of techniques for pathogen reduction, each centre should optimize processing steps during a validation procedure to ensure PC complying with INTERCEPT targets before and European targets after treatment. Besides buffy-coat optimization for sufficient plasma reduction, centrifugation profiles need to be optimized as well to prevent PC with low volumes and, in particular, with higher than acceptable RBC contamination.

Implementation of the INTERCEPT Blood System for Platelets into routine blood bank manufacturing procedures: evaluation of apheresis platelets

BACKGROUND AND OBJECTIVES

The INTERCEPT Blood System for Platelets utilizes amotosalen-HCl (S-59) in combination with ultraviolet A (UVA) light to inactivate viruses, bacteria, protozoa and leucocytes that may contaminate platelet concentrates (PCs). To facilitate implementation of this technique into routine blood bank manufacturing procedures, this study evaluated the impact of different time settings of photochemical treatment on in vitro platelet function.

MATERIALS AND METHODS

Platelets derived from apheresis (6.5-7.0 x 10(11) platelets) were resuspended in 240 ml of autologous plasma and 360 ml of platelet additive solution (PAS III) and split into two equal-sized PC units. Whereas one unit was not treated, the other was treated with 150 microm amotosalen and 3 J/cm2 UVA light followed by a compound adsorption device (CAD) step for reduction of residual amotosalen and photoproducts. In a first series of experiments (arm A, n = 7), PC units were photochemically treated after an overnight storage period of 16-23 h followed by a CAD step of 4 h. In a second series (arm B, n = 8), photochemical treatment occurred after a short storage time of 4 h with a subsequent CAD step of 16 h. Platelet function was evaluated by assaying blood gas analysis, glucose and lactate concentration, lactate dehydrogenase (LDH), hypotonic shock response (HSR) and the expression of CD62p, over a period of 7 days.

RESULTS

Neither of the photochemical treatment procedures showed differences for pH, pCO2, pO2, HCO3, glucose consumption or platelet activation until the end of day 7. Increased lactate values detected for the treated units of arm A at the end of the storage period were independent from the PCT time setting.

CONCLUSIONS

Photochemical pathogen inactivation with different initial resting periods between 4 and 23 h, and different CAD steps of 4 and 16 h, had no influence on the platelet in vitro function during 7 days of storage.