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1. Non‐phthalate plasticizer DEHT preserves adequate blood component quality during storage in PVC blood bags

Author

Per Sandgren, Felicia Daggert, Sonia Chatellier, Linda Larsson, Stefan Reichenberg, Michael Uhlin, Sara Ohlsson, Stella Larsson, Naïma Frizi, Jovan P. Antovic, Tove Friis-Christensen, Julia Derving, and B. Diedrich

Subjects
endocrine system, Erythrocytes, Phthalic Acids, 030204 cardiovascular system & hematology, Hemolysis, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Plasticizers, Diethylhexyl Phthalate, Humans, Platelet activation, Food science, Polyvinyl Chloride, Whole blood, Phthalate, Plasticizer, Hematology, General Medicine, Haemolysis, Polyvinyl chloride, chemistry, Blood Preservation, Toxicity, Fresh frozen plasma, 030215 immunology
Abstract

Background and objectives Commercial blood bags are predominantly made of polyvinyl chloride (PVC) plasticized with di(2-ethylhexyl) phthalate (DEHP). DEHP is favourable for storage of red blood cells (RBC). Historically, removal of DEHP from blood bags has been linked to unacceptable haemolysis levels. Oncoming regulatory restrictions for DEHP due to toxicity concerns increase the urgency to replace DEHP without compromising RBC quality. Di(2-ethylhexyl) terephthalate (DEHT) is one suggested substitute. The aim of this study was to compare PVC-DEHT to PVC-DEHP blood bags using additive solutions saline-adenine-glucose-mannitol (SAGM) and phosphate-adenine-glucose-guanosine-saline-mannitol (PAGGSM), to determine whether DEHT can maintain acceptable component quality. Materials and methods RBC concentrates (N = 64), platelet concentrates (N = 16) and fresh frozen plasma (N = 32) were produced from whole blood collected into either DEHT or DEHP plasticized systems. Using a pool-and-split study design, pairs of identical RBC content were created within each plasticizer arm and assigned either SAGM or PAGGSM. Storage effects were assessed weekly for 49 days (RBC), 7 days (platelets) and before/after freezing (plasma). Results Though haemolysis was slightly higher in DEHT, all study arms remained below half of the European limit 0·8%. K+ was lower in DEHT than in DEHP independent of additive solution. The metabolic parameters were not influenced by choice of plasticizer. Platelet activation/metabolism and plasma content were similarly preserved. Conclusion Our study demonstrates that the plasticizer DEHT provides adequate blood component quality. We propose DEHT as a strong future candidate for replacement of DEHP in blood bags.

Published
2020
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5. Optimized processing for pathogen inactivation of double‐dose buffy‐coat platelet concentrates: maintained in vitro quality over 7‐day storage

Author

Per Sandgren, Sara Ohlsson, Michael Uhlin, and B. Diedrich

Subjects
Blood Platelets, Amotosalen, Ultraviolet Rays, Chemistry, Double dose, Plastic materials, Hematology, General Medicine, Buffy coat, 030204 cardiovascular system & hematology, In vitro, Andrology, 03 medical and health sciences, 0302 clinical medicine, Increased risk, Blood Preservation, Furocoumarins, Blood Buffy Coat, Humans, Platelet, Pathogen inactivation, 030215 immunology
Abstract

BACKGROUND AND OBJECTIVE Efficient pathogen inactivation (PI) offers the possibility of increasing the number of buffy coats per pool without the concurrent increased risk of pathogen transmission. Here, we describe the findings of in vitro analyses of platelets from pools of eight buffy coats treated with amotosalen and UVA light (INTERCEPT Blood System for Platelets) using INTERCEPT disposable processing sets with plastic materials sourced from alternate suppliers and split afterwards to obtain two therapeutic transfusion doses. METHODS Double-dose platelet concentrates were prepared from pools of eight buffy coats in additive solution (SSP+) using either previous 6-lead or new 8-lead pooling sets and PI processing sets in previous or alternate supplier sourced plastics (AS). Platelets were treated with the INTERCEPT Blood System then stored for up to 7 days and tested for in vitro quality. RESULTS All tested units (n = 30) were in conformity with European guidelines. Using AS sets more effectively maintained glucose reserves (P

Published
2018
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8. Non‐phthalate plasticizer DEHT preserves adequate blood component quality during storage in PVC blood bags

Author

Larsson, Linda, primary, Sandgren, Per, additional, Ohlsson, Sara, additional, Derving, Julia, additional, Friis‐Christensen, Tove, additional, Daggert, Felicia, additional, Frizi, Naïma, additional, Reichenberg, Stefan, additional, Chatellier, Sonia, additional, Diedrich, Beatrice, additional, Antovic, Jovan, additional, Larsson, Stella, additional, and Uhlin, Michael, additional

Published
2020
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12. DEHT is a suitable plasticizer option for phthalate‐free storage of irradiated red blood cells.

Author

Larsson, Linda, Ohlsson, Sara, Derving, Julia, Diedrich, Beatrice, Sandgren, Per, Larsson, Stella, and Uhlin, Michael

Subjects
ERYTHROCYTES, PLASTICIZERS, POTASSIUM ions, GRAFT versus host disease, POLYVINYL chloride, POSTHARVEST diseases, GLUCOSE-6-phosphate dehydrogenase deficiency
Abstract

Background and Objectives: Due to increasing concerns about possible endocrine‐disrupting properties, the use of the plasticizer di(2‐ethylhexyl) phthalate (DEHP) will be banned in future blood storage. Di(2‐ethylhexyl) terephthalate (DEHT) provides sufficient red blood cell (RBC) quality during conventional blood bank storage. It is important that a new plasticizer also maintains acceptable quality during exposure to high cell stress, such as irradiation, which is commonly used to prevent graft‐versus‐host disease. Materials and Methods: A total of 59 RBC units were collected and processed in polyvinyl chloride (PVC)‐DEHT or PVC‐DEHP blood bags combined with either saline‐adenine‐glucose‐mannitol (SAGM) or phosphate‐adenine‐glucose‐guanosine‐saline‐mannitol (PAGGSM) additive solution. All units were X‐ray irradiated on day 2 post‐collection. Sampling for assessment of parameters of storage lesion was performed on day 2 pre‐irradiation and day 14 and 28 post‐irradiation. Results: Though irradiation increased cell stress, DEHT/PAGGSM and current common European preference DEHP/SAGM were equally affected up to 14 days post‐irradiation for all measured parameters. At day 28, haemolysis and microvesicle count were slightly increased in DEHT, whereas extracellular potassium ions, glucose, lactate, pH, mean corpuscular volume and microvesicle phosphatidylserine remained unaffected by plasticizer choice throughout storage. No individual unit exceeded 0.8% haemolysis, not even in DEHT/SAGM, the combination overall most affected by irradiation. Of the four combinations, membrane stability was least impacted in DEHP/PAGGSM. Conclusion: We demonstrate that DEHT is a suitable plasticizer for storage of RBCs after X‐ray irradiation cell stress. This strengthens the option of DEHT as a viable non‐phthalate substitute for DEHP. [ABSTRACT FROM AUTHOR]

Published
2022
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19. Non‐phthalate plasticizer DEHT preserves adequate blood component quality during storage in PVC blood bags.

Author

Larsson, Linda, Sandgren, Per, Ohlsson, Sara, Derving, Julia, Friis‐Christensen, Tove, Daggert, Felicia, Frizi, Naïma, Reichenberg, Stefan, Chatellier, Sonia, Diedrich, Beatrice, Antovic, Jovan, Larsson, Stella, and Uhlin, Michael

Subjects
*PLASTICIZERS, *ERYTHROCYTES, *BLOOD, *BLOOD platelet activation, *POLYVINYL chloride
Abstract

Background and objectives: Commercial blood bags are predominantly made of polyvinyl chloride (PVC) plasticized with di(2‐ethylhexyl) phthalate (DEHP). DEHP is favourable for storage of red blood cells (RBC). Historically, removal of DEHP from blood bags has been linked to unacceptable haemolysis levels. Oncoming regulatory restrictions for DEHP due to toxicity concerns increase the urgency to replace DEHP without compromising RBC quality. Di(2‐ethylhexyl) terephthalate (DEHT) is one suggested substitute. The aim of this study was to compare PVC‐DEHT to PVC‐DEHP blood bags using additive solutions saline–adenine–glucose–mannitol (SAGM) and phosphate–adenine–glucose–guanosine–saline–mannitol (PAGGSM), to determine whether DEHT can maintain acceptable component quality. Materials and methods: RBC concentrates (N = 64), platelet concentrates (N = 16) and fresh frozen plasma (N = 32) were produced from whole blood collected into either DEHT or DEHP plasticized systems. Using a pool‐and‐split study design, pairs of identical RBC content were created within each plasticizer arm and assigned either SAGM or PAGGSM. Storage effects were assessed weekly for 49 days (RBC), 7 days (platelets) and before/after freezing (plasma). Results: Though haemolysis was slightly higher in DEHT, all study arms remained below half of the European limit 0·8%. K+ was lower in DEHT than in DEHP independent of additive solution. The metabolic parameters were not influenced by choice of plasticizer. Platelet activation/metabolism and plasma content were similarly preserved. Conclusion: Our study demonstrates that the plasticizer DEHT provides adequate blood component quality. We propose DEHT as a strong future candidate for replacement of DEHP in blood bags. [ABSTRACT FROM AUTHOR]

Published
2021
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20. Pathogen inactivation of double-dose buffy-coat platelet concentrates photochemically treated with amotosalen and UVA light: preservation ofin vitrofunction

Author

B. Diedrich and Per Sandgren

Subjects
Blood Platelets, Amotosalen, Photosensitizing Agents, Ultraviolet Rays, Blood Safety, Hematology, General Medicine, Buffy coat, Pharmacology, Biology, In vitro, In vivo, Furocoumarins, Immunology, Humans, Platelet, Pathogen inactivation, Function (biology), Uva light
Abstract

The INTERCEPT Blood System for Platelets (PLT) utilizes amotosalen (S-59) in combination with ultraviolet A (UVA) light to inactivate viruses, bacteria, protozoa and leucocytes that may contaminate PLT concentrates. However, limited data are available on the quality of INTERCEPT-treated double-dose (DD) buffy-coat (BC) PLT units allowing a single treatment procedure to produce two pathogen-inactivated PLT units for transfusion.The objective of this study was to evaluate potential in vitro effects of the INTERCEPT treatment on pools of 7 BCs as compared to untreated units. Functional, phenotypic and mitochondrial properties of DD BC PLTs during storage over 7 days were studied.For some parameters measured, small yet significant differences were observed including PLT count (P 0·05), pH, pCO2 and glucose concentration. Throughout storage, no significant differences were observed in ATP levels, ESC, HSR reactivity and CD62P expression. Similarly, no differences were observed in the expression of PAC-1, CD42b and PECAM-1 at any time-points. The mitochondrial membrane potential (MMP) determined by JC-1-labelling was well maintained until day 7 in all treated and untreated units (90%). The release of sCD40L increased over time (P 0·01) in all units but without any significant differences between treated and untreated PLTs.Our data demonstrate that photochemical pathogen inactivation of DD-BC PLT concentrates with the INTERCEPT Blood System had no influence on the PLT in vitro quality over the 7 day of storage. However, whether in vivo efficacy of INTERCEPT-treated PLTs is affected may require clinical evaluation.

Published
2014
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22. High-yield Platelet units revealed immediate pH decline and delayed mitochondrial dysfunction during storage in 100% plasma as compared with storage in SSP+

Author

Per Sandgren and A. Stjepanovic

Subjects
chemistry.chemical_classification, Reactive oxygen species, biology, Caspase 3, Hematology, General Medicine, Mitochondrion, Andrology, Superoxide dismutase, chemistry.chemical_compound, chemistry, Biochemistry, Apoptosis, Platelet-rich plasma, Carbon dioxide, biology.protein, Platelet
Abstract

Background and Objectives Initial elevated and prolonged high carbon dioxide levels related to mitochondrial dysfunction are recently being suggested as a contributing factor to rapid pH decline in platelet (PLT) units. The use of different storage environments may influence this phenomenon. This study has two objectives (i) to investigate the relationship of mitochondrial function and apoptotic events with different storage environments capability of pH control and (ii) to examine the cause and relationship between pH decline in PLT units, carbon dioxide levels and mitochondrial function. Materials and Methods Platelet units were prepared for storage in (A) 70% SSP+, 300–400 × 109/unit, (B) 70% SSP+, 550–600 × 109/unit, (C) 100% plasma, 550–600 × 109/unit, and (D) additional 100% plasma, >600 × 109/unit. In vitro variables including mitochondrial function (JC-1), reactive oxygen species (ROS) and caspase 3 activity were analysed on days 2, 5 and 7. Results Glucose/lactate was higher, pH, ATP, Hypotonic shock response (HSR) and extent of shape change (ESC) decreased (P 80% maintenance of mitochondrial function until day 7. Conclusions The use of SSP+ instead of plasma may reduce the risk of triggering pro-apoptotic events in high-yield PLT units. A rapid decline in pH in PLT units cannot be explained with initial elevated and prolonged high carbon dioxide levels and mitochondrial dysfunction.

Published
2012
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23. In vitro effects on platelets irradiated with short-wave ultraviolet light without any additional photoactive reagent using the THERAFLEX UV-Platelets method

Author

Per Sandgren, H. Gulliksson, W. G. Struff, and F. Tolksdorf

Subjects
Infectivity, Chromatography, Chemistry, Significant difference, Hematology, General Medicine, In vitro, chemistry.chemical_compound, Biochemistry, Reagent, Lactate dehydrogenase, Ultraviolet light, Platelet, Irradiation
Abstract

Background A novel short-wave ultraviolet light (UVC) pathogen reduction technology (THERAFLEX UV-Platelets; MacoPharma, Mouvaux, France) without the need of any additional photoactive reagent has recently been evaluated for various bacteria and virus infectivity assays. The use of UVC alone has on the one hand been shown to reduce pathogens but may, on the other hand, have some impact on the platelet (PLT) quality. The purpose of this study was to determine the potential effects on PLT quality of pathogen inactivation treatment using the novel UVC method for PLT concentrates. Study Design and Methods Buffy-coat-derived PLTs suspended in SSP+ were irradiated with UVC light in plastic bags (MacoPharma) made of ethyl vinyl acetate, considered to be highly permeable to UVC light. The UVC-treated (test, n = 8) as well as the untreated (reference, n = 8) PLT units were stored in PLT storage bags composed of n-butyryl, tri n-hexyl citrate–plasticized polyvinyl chloride (MacoPharma) on a flat bed agitator for in vitro testing during 7 days of storage. Results No significant difference in PLT counts and lactate dehydrogenase between the groups was detected. During storage, glucose decreased more and lactate increased more in the test units. Statistically significant differences were found for glucose (P 6·8 (day 7) and swirling remained at the highest level (score = 2) for all units throughout storage. Conclusion Our results suggest that irradiation with UVC light has a slight impact on PLT in vitro quality and appears to be insignificant with regard to current in vitro standards.

Published
2010
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24. Storage of Buffy-coat-derived platelets in additive solutions: in vitro effects on platelets prepared by the novel TACSI system and stored in plastic containers with different gas permeability

Author

H. Gulliksson, Per Sandgren, A. Sjödin, and M. Hild

Subjects
Chromatography, Plasticizer, Phthalate, Mineralogy, Hematology, General Medicine, Buffy coat, In vitro, Polyvinyl chloride, chemistry.chemical_compound, chemistry, Permeability (electromagnetism), Platelet, Mean platelet volume
Abstract

Background The novel TACSI system is designed for automated preparation of platelets (PLTs) from pooled buffy coats (BCs). One TACSI device will handle 6 units at the same time. The aim of our in vitro study is to investigate the effects of using this automated equipment with subsequent storage in two different plastic containers and to compare these results with PLTs prepared by the OrbiSac system. Study design and methods Buffy-coat-derived PLTs (n = 8) were prepared by using the TACSI system, including storage in polyvinyl chloride (PVC)-based plastic containers with di, n-decyl phthalate (DnDP) (TACSI R) and BTHC (TACSI T)-based plasticizers. As a reference, the OrbiSac System was used to prepare PLTs (n = 8) with subsequent storage in a PVC plastic container with a citrate-based plasticizer (BTHC). In total, 16 TACSI and eight reference units, supplied by approximately 30% plasma and 70% SSP+, were analysed for various in vitro variables during the 7-day storage period. Results No significant difference in PLT counts, LDH, mean platelet volume (MPV) and adenosine triphosphate between the groups was detected. Glucose was lower (P 6·8 (day 7) and swirling remained at the highest level (score = 2) for all units throughout storage. Conclusion Platelets prepared by the TACSI system with subsequent storage in two different PVC-based plastic containers were equivalent to reference PLTs with regard to in vitro characteristics during 7 days of storage.

Published
2010
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25. Storage of buffy-coat-derived platelets in additive solutions at 4 °C and 22 °C: flow cytometry analysis of platelet glycoprotein expression

Author

M. Hansson, Per Sandgren, Agneta Shanwell, and H. Gulliksson

Subjects
chemistry.chemical_classification, medicine.diagnostic_test, Significant difference, Hematology, General Medicine, Buffy coat, Biology, Platelet membrane glycoprotein, Molecular biology, In vitro, Flow cytometry, Biochemistry, chemistry, medicine, Platelet, Platelet activation, Glycoprotein
Abstract

Background The aim of our in vitro study is to compare the effects on platelet membrane glycoproteins that play an important role in the main functions of platelets, when platelets are stored for a period of 21 days at 4 degrees C or 22 degrees C. Study design and methods Platelet concentrates (PC) were prepared from pooled buffy-coats (BC) for paired studies (total eight pools from 80 BCs) by using the OrbiSac system. We divided each pool into two PCs and stored them at 4 degrees C or 22 degrees C. Results The activation marker CD62 remained almost unchanged during storage in all units. The expression of CD63 was higher in PCs stored at 22 degrees C than in those stored at 4 degrees C. No significant difference in CD41 expression was detected over time. The expression of CD42b declined during storage and even more in PCs stored at 4 degrees C until day 21 [day 14: mean flourscence intensity: 32.5 +/- 13.1 vs. 46.5 +/- 19.1], but the percentage of platelets expressing CD42b remained high in platelets stored at 4 degrees C, but gradually decreased at 22 degrees C (day 14: 95.0 +/- 1.5 vs. 59.0 +/- 9.9). Storage at 4 degrees C reduced the rate of glycolysis and maintained the pH better after day 10 than in PCs stored at 22 degrees C (day 14: 7.009 +/- 0.067 vs. 7.233 +/- 0.125). The concentration of regulated upon activation of normal T-cells expressed and secreted was higher in PCs stored at 22 degrees C than at 4 degrees C (day 7: 414.7 +/- 32.3 vs. 49.6 +/- 19.0). No response to extent of shape change and no swirling were detected at 4 degrees C. Conclusion Platelets stored at 4 degrees C retain their in vitro characteristics better than those stored at 22 degrees C, except for parameters that reflect changes in shape. Storage at 4 degrees C is not associated with an increased expression of glycoprotein (GpIb, GpIIb/IIIa) and platelet activation markers (CD62p and CD63) as compared with storage at 22 degrees C.

Published
2007
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26. Storage of platelets in additive solutions: a pilot in vitro study of the effects of potassium and magnesium

Author

M. Langweiler, Jill Roger, Per Sandgren, Constance Pickard, H. Gulliksson, M. Vesterinen, I. Herschel, J. E. Tracy, Stella Larsson, and James P. AuBuchon

Subjects
Chromatography, Magnesium, Potassium, chemistry.chemical_element, Hematology, General Medicine, Buffy coat, Platelet transfusion, Apheresis, chemistry, Biochemistry, Blood product, Composition (visual arts), Platelet
Abstract

Background and Objectives Platelet additive solutions (PAS) have been shown to be suitable for extended platelet storage but have required the carryover of substantial (30%) amounts of plasma for success. Improving platelet quality by optimizing the composition of PAS may allow a reduction to be made in the amount of plasma carried over. Reducing the proportion of plasma carried over would facilitate some methods of viral inactivation and make available greater amounts of plasma for other needs. Materials and Methods Platelets from six pools of 25 buffy coat platelet units and five apheresis platelet units were aliquoted for storage in plasma, or converted to PAS units in either a specific additive solution (PAS-III), with 30% or 20% plasma, or a modification of PAS-III containing 5·0 mm potassium and 1·5 mm magnesium (PAS-IIIM), with 30% or 20% plasma. Units were stored at room temperature with agitation for 7 days with in vitro testing for biochemical, haematological and functional parameters. Results Storage of platelets in PAS-IIIM resulted in a reduced rate of glycolysis and better retention of pH, morphology score and ATP levels. Platelets initially showed less evidence of activation when stored in PAS-IIIM, with reduced P-selectin expression. Storage in PAS-IIIM with 20% (rather than the standard 30%) plasma appeared to result in the retention of in vitro properties, similarly to storage in standard PAS-III with 30% plasma. Conclusions Storing platelets in an additive solution containing magnesium and potassium improves the functionality of the platelets, as measured by in vitro testing, and may allow a reduction of the amount of plasma required to be carried over to the final unit.

Published
2002
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27. Aggregates in platelet concentrates

Author

Pieter F. Meer, L. J. Dumont, Miguel Lozano, Noemi Bondar, Janet Wong, Sue Ismay, Joanne Pink, Walter Nussbaumer, José Coene, H. B. Feys, Veerle Compernolle, Dana V. Devine, David Howe, Che Kit Lin, Jenny Sun, Juergen Ringwald, Erwin F. Strasser, Reinhold Eckstein, Axel Seltsam, Paolo Perseghin, Patrizia Proserpio, Shinobu Wakamoto, Mitsuaki Akino, Shigeru Takamoto, Kenji Tadokoro, Diana Teo, Pei Huey Shu, Sze Sze Chua, Teresa Jimenez‐Marco, Joan Cid, Emma Castro, Irene Muñoz, Hans Gulliksson, Per Sandgren, Stephen Thomas, Juraj Petrik, Kevin McColl, Hany Kamel, James Dugger, Joseph D. Sweeney, Jed B. Gorlin, Laurie J. Sutor, Doug Heath, and Merlyn H. Sayers

Subjects
Platelet Aggregation, media_common.quotation_subject, Immunology, Humans, Platelet, Hematology, General Medicine, Buffy coat, Art, Platelet Transfusion, Molecular biology, media_common
Abstract

P. F. van der Meer, L. J. Dumont, M. Lozano, N. Bondar, J. Wong, S. Ismay, J. Pink, W. Nussbaumer, J. Coene, H. B. Feys, V. Compernolle, D. V. Devine, D. Howe, C. K. Lin, J. Sun, J. Ringwald, E. F. Strasser, R. Eckstein, A. Seltsam, P. Perseghin, P. Proserpio, S. Wakamoto, M. Akino, S. Takamoto, K. Tadokoro, D. Teo, P. H. Shu, S. S. Chua, T. Jimenez-Marco, J. Cid, E. Castro, I. Mu~ noz, H. Gulliksson, P. Sandgren, S. Thomas, J. Petrik, K. McColl, H. Kamel, J. Dugger, J. D. Sweeney, J. B. Gorlin, L. J. Sutor, D. Heath & M. H. Sayers.

Published
2014

28. High-yield platelet units revealed immediate pH decline and delayed mitochondrial dysfunction during storage in 100% plasma as compared with storage in SSP+

Author

P, Sandgren and A, Stjepanovic

Subjects
Blood Platelets, Membrane Potential, Mitochondrial, Solutions, Plasma, Blood Preservation, Caspase 3, Platelet-Rich Plasma, Superoxide Dismutase, Humans, Carbon Dioxide, Hydrogen-Ion Concentration, Reactive Oxygen Species, Mitochondria
Abstract

Initial elevated and prolonged high carbon dioxide levels related to mitochondrial dysfunction are recently being suggested as a contributing factor to rapid pH decline in platelet (PLT) units. The use of different storage environments may influence this phenomenon. This study has two objectives (i) to investigate the relationship of mitochondrial function and apoptotic events with different storage environments capability of pH control and (ii) to examine the cause and relationship between pH decline in PLT units, carbon dioxide levels and mitochondrial function. Platelet units were prepared for storage in (A) 70% SSP+, 300-400 × 10(9) /unit, (B) 70% SSP+, 550-600 × 10(9) /unit, (C) 100% plasma, 550-600 × 10(9) /unit, and (D) additional 100% plasma,600 × 10(9) /unit. In vitro variables including mitochondrial function (JC-1), reactive oxygen species (ROS) and caspase 3 activity were analysed on days 2, 5 and 7. Glucose/lactate was higher, pH, ATP, Hypotonic shock response (HSR) and extent of shape change (ESC) decreased (P 0·001 on day 7), CD62P (P 0·001 on day 7) increased, the JC-1-positive PLTs were lower (P 0·001 on day 7), and ROS was higher (P 0·001 days 2-7) in the plasma (C) units as compared with the SSP+ (A) and (B) units. All plasma (D) units showed rapid pH and pCO(2) decline from day 2 but by means of80% maintenance of mitochondrial function until day 7. The use of SSP+ instead of plasma may reduce the risk of triggering pro-apoptotic events in high-yield PLT units. A rapid decline in pH in PLT units cannot be explained with initial elevated and prolonged high carbon dioxide levels and mitochondrial dysfunction.

Published
2012

29. In vitro effects on platelets irradiated with short-wave ultraviolet light without any additional photoactive reagent using the THERAFLEX UV-Platelets method

Author

P, Sandgren, F, Tolksdorf, W G, Struff, and H, Gulliksson

Subjects
Blood Platelets, Platelet Membrane Glycoprotein IIb, Bacteria, L-Lactate Dehydrogenase, Platelet Count, Ultraviolet Rays, Integrin beta3, P-Selectin, Adenosine Triphosphate, Glucose, Platelet Glycoprotein GPIb-IX Complex, Blood Preservation, Humans, Lactic Acid
Abstract

A novel short-wave ultraviolet light (UVC) pathogen reduction technology (THERAFLEX UV-Platelets; MacoPharma, Mouvaux, France) without the need of any additional photoactive reagent has recently been evaluated for various bacteria and virus infectivity assays. The use of UVC alone has on the one hand been shown to reduce pathogens but may, on the other hand, have some impact on the platelet (PLT) quality. The purpose of this study was to determine the potential effects on PLT quality of pathogen inactivation treatment using the novel UVC method for PLT concentrates.Buffy-coat-derived PLTs suspended in SSP+ were irradiated with UVC light in plastic bags (MacoPharma) made of ethyl vinyl acetate, considered to be highly permeable to UVC light. The UVC-treated (test, n=8) as well as the untreated (reference, n=8) PLT units were stored in PLT storage bags composed of n-butyryl, tri n-hexyl citrate-plasticized polyvinyl chloride (MacoPharma) on a flat bed agitator for in vitro testing during 7 days of storage.No significant difference in PLT counts and lactate dehydrogenase between the groups was detected. During storage, glucose decreased more and lactate increased more in the test units. Statistically significant differences were found for glucose (P0·01) and lactate (P0·05) on day 7. ATP levels were higher (P0·01 from day 5) in the reference units. With exception of day 7 (P0·01 reference vs. test), hypotonic shock response reactivity was not different between groups. Extent of shape change was lower (P0·01), and CD62P (P0·05 day 5) was higher in the test units. CD42b and CD41/61 showed similar trends throughout storage, without any significant difference between the units. pH was maintained at6·8 (day 7) and swirling remained at the highest level (score = 2) for all units throughout storage.Our results suggest that irradiation with UVC light has a slight impact on PLT in vitro quality and appears to be insignificant with regard to current in vitro standards.

Published
2010

30. Storage of Buffy-coat-derived platelets in additive solutions: in vitro effects on platelets prepared by the novel TACSI system and stored in plastic containers with different gas permeability

Author

P, Sandgren, M, Hild, A, Sjödin, and H, Gulliksson

Subjects
Blood Platelets, Male, Time Factors, Blood Buffy Coat, Plateletpheresis, Preservation, Biological, Humans, Female
Abstract

The novel TACSI system is designed for automated preparation of platelets (PLTs) from pooled buffy coats (BCs). One TACSI device will handle 6 units at the same time. The aim of our in vitro study is to investigate the effects of using this automated equipment with subsequent storage in two different plastic containers and to compare these results with PLTs prepared by the OrbiSac system.Buffy-coat-derived PLTs (n=8) were prepared by using the TACSI system, including storage in polyvinyl chloride (PVC)-based plastic containers with di, n-decyl phthalate (DnDP) (TACSI R) and BTHC (TACSI T)-based plasticizers. As a reference, the OrbiSac System was used to prepare PLTs (n=8) with subsequent storage in a PVC plastic container with a citrate-based plasticizer (BTHC). In total, 16 TACSI and eight reference units, supplied by approximately 30% plasma and 70% SSP+, were analysed for various in vitro variables during the 7-day storage period.No significant difference in PLT counts, LDH, mean platelet volume (MPV) and adenosine triphosphate between the groups was detected. Glucose was lower (P0·05) and lactate was higher (P0·05) in TACSI R vs. OrbiSac. With exception of day 7 (P0·05 TACSI R vs. OrbiSac), HSR reactivity were not different between groups. Extent of shape change was lower and CD62P higher in TACSI T when compared with TACSI R and OrbiSac units (P0·05). pH was maintained at6·8 (day 7) and swirling remained at the highest level (score=2) for all units throughout storage.Platelets prepared by the TACSI system with subsequent storage in two different PVC-based plastic containers were equivalent to reference PLTs with regard to in vitro characteristics during 7 days of storage.

Published
2010

31. Storage of buffy-coat-derived platelets in additive solutions: in vitro effects on platelets stored in reformulated PAS supplied by a 20% plasma carry-over

Author

Per Sandgren, A. Sjödin, H. Gulliksson, Jean-Marc Payrat, and V. Mayaudon

Subjects
Adult, Blood Platelets, Potassium, Organ Preservation Solutions, chemistry.chemical_element, Buffy coat, Cell Separation, Phosphates, chemistry.chemical_compound, Plasma, Humans, Platelet, Magnesium, Food science, Chemistry, Platelet Count, Erythrocyte fragility, Hematology, General Medicine, Hydrogen-Ion Concentration, Phosphate, In vitro, Osmotic Fragility, Glucose, Biochemistry, Blood Preservation, Composition (visual arts)
Abstract

Platelet additive solutions (PAS) have been shown to be suitable for extended platelet (PLT) storage. Depending on the PAS formulation, the percentage of plasma carry-over contributes to success. Improving PLT quality by optimizing the composition of PAS may allow a reduction to be made in the amount of plasma carried over to the final unit. Reducing the proportion of plasma carried over would probably decrease transfusion of unwanted antibodies and make greater amounts of plasma available for other needs.Platelets from eight pools of 25 buffy coats were aliquoted and prepared for storage in plasma and different PAS units: InterSol and three alternate PAS named PSM1, PSM2 and PSM3. All PAS units were supplied with a 20% plasma carry-over and stored at room temperature with agitation for 9 days with in vitro testing for metabolic, cellular and activation parameters. Results During storage, PLTs stored in InterSol displayed significantly lower glucose concentration (P0.01), lower adenosine triphosphate levels (P0.01), a higher mean PLT volume (P0.01), a lower response to hypotonic shock response activity (P0.01) and a higher CD62P expression (P0.01) when compared with PLTs stored in plasma and PSM1-3 solutions. pH was maintained at6.8 (day 9) and swirling remained at the highest level (score = 2) for all units throughout storage.Our results suggest that PLTs stored in PAS with addition of magnesium, potassium and glucose (PSM2 and PSM3) and 20% plasma carry-over maintained metabolic and cellular characteristics, equivalent to PLTs stored in 100% plasma during 9 days of storage. Our results also suggest that presence of potassium in addition to magnesium or alternatively the concentration of phosphate as well as the supply of additional glucose to normal plasma levels improve in vitro data of PLTs stored in PAS.

Published
2009

32. Storage of buffy-coat-derived platelets in additive solutions at 4 degrees C and 22 degrees C: flow cytometry analysis of platelet glycoprotein expression

Author

P, Sandgren, M, Hansson, H, Gulliksson, and A, Shanwell

Subjects
Blood Platelets, Cold Temperature, Hot Temperature, Time Factors, Gene Expression Regulation, Blood Preservation, Organ Preservation Solutions, Humans, Platelet Membrane Glycoproteins, Hydrogen-Ion Concentration, Flow Cytometry, Platelet Activation, Cell Shape
Abstract

The aim of our in vitro study is to compare the effects on platelet membrane glycoproteins that play an important role in the main functions of platelets, when platelets are stored for a period of 21 days at 4 degrees C or 22 degrees C.Platelet concentrates (PC) were prepared from pooled buffy-coats (BC) for paired studies (total eight pools from 80 BCs) by using the OrbiSac system. We divided each pool into two PCs and stored them at 4 degrees C or 22 degrees C.The activation marker CD62 remained almost unchanged during storage in all units. The expression of CD63 was higher in PCs stored at 22 degrees C than in those stored at 4 degrees C. No significant difference in CD41 expression was detected over time. The expression of CD42b declined during storage and even more in PCs stored at 4 degrees C until day 21 [day 14: mean flourscence intensity: 32.5 +/- 13.1 vs. 46.5 +/- 19.1], but the percentage of platelets expressing CD42b remained high in platelets stored at 4 degrees C, but gradually decreased at 22 degrees C (day 14: 95.0 +/- 1.5 vs. 59.0 +/- 9.9). Storage at 4 degrees C reduced the rate of glycolysis and maintained the pH better after day 10 than in PCs stored at 22 degrees C (day 14: 7.009 +/- 0.067 vs. 7.233 +/- 0.125). The concentration of regulated upon activation of normal T-cells expressed and secreted was higher in PCs stored at 22 degrees C than at 4 degrees C (day 7: 414.7 +/- 32.3 vs. 49.6 +/- 19.0). No response to extent of shape change and no swirling were detected at 4 degrees C.Platelets stored at 4 degrees C retain their in vitro characteristics better than those stored at 22 degrees C, except for parameters that reflect changes in shape. Storage at 4 degrees C is not associated with an increased expression of glycoprotein (GpIb, GpIIb/IIIa) and platelet activation markers (CD62p and CD63) as compared with storage at 22 degrees C.

Published
2007

34. Aggregates in platelet concentrates

Author

van der Meer, Pieter F., primary, Dumont, L. J., additional, Lozano, Miguel, additional, Bondar, Noemi, additional, Wong, Janet, additional, Ismay, Sue, additional, Pink, Joanne, additional, Nussbaumer, Walter, additional, Coene, José, additional, Feys, H. B., additional, Compernolle, Veerle, additional, Devine, Dana V., additional, Howe, David, additional, Lin, Che Kit, additional, Sun, Jenny, additional, Ringwald, Juergen, additional, Strasser, Erwin F., additional, Eckstein, Reinhold, additional, Seltsam, Axel, additional, Perseghin, Paolo, additional, Proserpio, Patrizia, additional, Wakamoto, Shinobu, additional, Akino, Mitsuaki, additional, Takamoto, Shigeru, additional, Tadokoro, Kenji, additional, Teo, Diana, additional, Shu, Pei Huey, additional, Chua, Sze Sze, additional, Jimenez‐Marco, Teresa, additional, Cid, Joan, additional, Castro, Emma, additional, Muñoz, Irene, additional, Gulliksson, Hans, additional, Sandgren, Per, additional, Thomas, Stephen, additional, Petrik, Juraj, additional, McColl, Kevin, additional, Kamel, Hany, additional, Dugger, James, additional, Sweeney, Joseph D., additional, Gorlin, Jed B., additional, Sutor, Laurie J., additional, Heath, Doug, additional, and Sayers, Merlyn H., additional

Published
2014
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35. Storage of platelets in additive solutions: a pilot in vitro study of the effects of potassium and magnesium

Author

H, Gulliksson, J P, AuBuchon, M, Vesterinen, P, Sandgren, S, Larsson, C A, Pickard, I, Herschel, J, Roger, J E, Tracy, and M, Langweiler

Subjects
Quality Control, Adenosine Triphosphate, Time Factors, Blood Preservation, Organ Preservation Solutions, Potassium, Humans, Magnesium, Pilot Projects, Platelet Transfusion, Hydrogen-Ion Concentration, Glycolysis, Specimen Handling
Abstract

Platelet additive solutions (PAS) have been shown to be suitable for extended platelet storage but have required the carryover of substantial (30%) amounts of plasma for success. Improving platelet quality by optimizing the composition of PAS may allow a reduction to be made in the amount of plasma carried over. Reducing the proportion of plasma carried over would facilitate some methods of viral inactivation and make available greater amounts of plasma for other needs.Platelets from six pools of 25 buffy coat platelet units and five apheresis platelet units were aliquoted for storage in plasma, or converted to PAS units in either a specific additive solution (PAS-III), with 30% or 20% plasma, or a modification of PAS-III containing 5.0 mm potassium and 1.5 mm magnesium (PAS-IIIM), with 30% or 20% plasma. Units were stored at room temperature with agitation for 7 days with in vitro testing for biochemical, haematological and functional parameters.Storage of platelets in PAS-IIIM resulted in a reduced rate of glycolysis and better retention of pH, morphology score and ATP levels. Platelets initially showed less evidence of activation when stored in PAS-IIIM, with reduced P-selectin expression. Storage in PAS-IIIM with 20% (rather than the standard 30%) plasma appeared to result in the retention of in vitro properties, similarly to storage in standard PAS-III with 30% plasma.Storing platelets in an additive solution containing magnesium and potassium improves the functionality of the platelets, as measured by in vitro testing, and may allow a reduction of the amount of plasma required to be carried over to the final unit.

Published
2002

39. In vitro and in vivo effects of potassium and magnesium on storage up to 7 days of apheresis platelet concentrates in platelet additive solution

Author

Per Sandgren, Leif Svensson, B. Diedrich, B. A. Jansson, H. Gulliksson, and Agneta Shanwell

Subjects
Blood Platelets, Time Factors, Cell Survival, Potassium, Organ Preservation Solutions, chemistry.chemical_element, Platelet Transfusion, Cell Physiological Phenomena, Andrology, In vivo, Humans, Magnesium, Glycolysis, Platelet, Platelet activation, Radioisotopes, Chemistry, Plateletpheresis, Hematology, General Medicine, In vitro, Pharmaceutical Solutions, Apheresis, Biochemistry, Blood Preservation
Abstract

Background and Objective Prolonged storage of platelets up to 7 days provides improved availability, logistical management and decreased wastage. Beside methods of bacterial detection, addition of magnesium and potassium to the platelet storage solution (SSP+) may further improve the quality of platelets with extended storage. Materials and Methods Apheresis platelets from 10 donors were divided and stored in two different platelet additive solutions (PAS) (Intersol and SSP+) for a paired comparison. A variety of in vitro platelet function and metabolic assays were performed both on day 1 and after 7 days of storage. For in vivo study, platelets were labelled with either 111Indium or 51Chromium after 7 days of storage and were injected into the corresponding donor. Serial blood samples were drawn for recovery and survival measurements. Results In vitro parameters for SSP+ showed significantly reduced glycolysis (lower glucose consumption and decreased production of lactate), a higher hypotonic shock response (HSR) and the extent of shape change reactivity and a lower degree of platelet activation by means of RANTES (regulated on activation, normal, T cell-expressed, and secreted), CD62p and CD63 expression. Platelet recovery on day 7 was higher for Intersol as compared to SSP+, 65 ± 11 vs. 53 ± 13% (P = 0·023), and survival showed no difference 4·2 ± 1·9 vs. 3·6 ± 1·4 days. Conclusion In vitro characteristics of platelets stored in PAS with addition of potassium and magnesium indicated higher quality, but this could not be verified by the in vivo parameters by means of recovery and survival.

Published
2007
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40. Abstracts of Articles in Part 1 of this issue.

Author

Sandgren, P., Mayaudon, V., Payrat, J.-M., Sjödin, A., and Gulliksson, H.

Subjects
*BLOOD donors, *BLOOD, *DONOR blood supply, *HEMATOLOGY, ABSTRACTS
Abstract

The article presents abstracts on articles related to medical topics which include "Factors influencing confidential unit exclusions in blood donors," by T. Kohlmann and colleagues, "Applied tension may help retain donors who are ambivalent about needles," by B. Ditto, C. R. France, and B. C. Holly, and "Blood product collection and supply: a matter of money?" by W. de Kort and colleagues.

Published
2010
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41. Storage of buffy-coat-derived platelets in additive solutions: in vitro effects on platelets stored in reformulated PAS supplied by a 20% plasma carry-over.

Author

Sandgren, P., Mayaudon, V., Payrat, J.-M., Sjödin, A., and Gulliksson, H.

Subjects
*BLOOD platelets, *PLASMA cell diseases, *ADENINE nucleotides, *BUFFY coat, *REGULATION of cell metabolism, *POTASSIUM, *GLUCOSE
Abstract

Background and Objectives Platelet additive solutions (PAS) have been shown to be suitable for extended platelet (PLT) storage. Depending on the PAS formulation, the percentage of plasma carry-over contributes to success. Improving PLT quality by optimizing the composition of PAS may allow a reduction to be made in the amount of plasma carried over to the final unit. Reducing the proportion of plasma carried over would probably decrease transfusion of unwanted antibodies and make greater amounts of plasma available for other needs. Study Design and Methods Platelets from eight pools of 25 buffy coats were aliquoted and prepared for storage in plasma and different PAS units: InterSol and three alternate PAS named PSM1, PSM2 and PSM3. All PAS units were supplied with a 20% plasma carry-over and stored at room temperature with agitation for 9 days with in vitro testing for metabolic, cellular and activation parameters. Results During storage, PLTs stored in InterSol displayed significantly lower glucose concentration (P < 0Æ01), lower adenosine triphosphate levels (P < 0Æ01), a higher mean PLT volume (P < 0Æ01), a lower response to hypotonic shock response activity (P < 0Æ01) and a higher CD62P expression (P < 0Æ01) when compared with PLTs stored in plasma and PSM1–3 solutions. pH was maintained at > 6Æ8 (day 9) and swirling remained at the highest level (score = 2) for all units throughout storage. Conclusion Our results suggest that PLTs stored in PAS with addition of magnesium, potassium and glucose (PSM2 and PSM3) and 20% plasma carry-over maintained metabolic and cellular characteristics, equivalent to PLTs stored in 100% plasma during 9 days of storage. Our results also suggest that presence of potassium in addition to magnesium or alternatively the concentration of phosphate as well as the supply of additional glucose to normal plasma levels improve in vitro data of PLTs stored in PAS. [ABSTRACT FROM AUTHOR]

Published
2010
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