Fuji surge technique and continuous in‐line filtration to improve the quality of single donor platelet concentrates

Moog, Rainer

doi:10.1002/jca.10040

Cited by 4 publications

(4 citation statements)

References 27 publications

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“…The study showed that 80·51% (95 in 118) of the products after modification was qualified (Table ). Previous study demonstrated that MCS+ was the highest capacity for leukodepletion compared with other two devices of Amicus and Accel (Bueno et al , ) because of a continuous‐filtration technique for leukodepletion (Seghatchian & Krailadsiri, ; Seghatchian et al , ; Moog, ). The modification on the MCS+ resulted in less than 1 × 10 8 L −1 leukocyte in the selected samples, which complied with the international standard requirements (MnU‐B, ).…”

Section: Discussionmentioning

confidence: 97%

Improvement of plateletpheresis via technical modification on the MCS+

Zhou

Liu

et al. 2015

Transfusion Medicine

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Section: Discussionmentioning

confidence: 97%

Improvement of plateletpheresis via technical modification on the MCS+

Zhou

Liu

et al. 2015

Transfusion Medicine

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“…Some of the common features shared by these systems are the possibility of obtaining a SDP (3.5 × 10 11 platelets [PLTs] per unit in our center), with an integrated leukodepletion system, as well as a plasma unit. For leukodepletion, the MCS Plus uses a continuous‐filtration technique 3,4 . Accel uses fluidized particle‐bed technology, 5‐7 whereas Amicus uses the elutriation principle 5,8‐12 .…”

Section: Methodsmentioning

confidence: 99%

“…One differential feature is that the Amicus uses saline for set priming at the beginning of the procedure, whereas the MCS Plus and the Accel use acid citrate dextrose‐A (ACD‐A). Various publications 4,9 , 10,13 have explained the function of these systems in great detail. The manufacturing companies configured the machines at their discretion to obtain the best possible results according to the objectives of the study.…”

Section: Methodsmentioning

confidence: 99%

A randomized crossover trial comparing three plateletpheresis machines

Bueno¹,

García²,

Castro³

et al. 2005

Transfusion

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“…All cytapheresis systems are capable to produce up to three white cell poor platelet units either in the apheresis procedure [9–12,14,15,25–34] or through an additional filtration step [27,29–31]. Multicomponent apheresis procedures using these techniques enable the concurrent collection of up to three platelet units alone or in combination with fresh frozen plasma fulfilling all quality criteria without the need of further manipulations [21,35–39].…”

Section: Multicomponent Collection Techniquesmentioning

confidence: 99%

Multicomponent apheresis

Zingsem

2010

ISBT Science Series

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Introduction: An increasing demand for blood components is opposed by a decreasing donor availability for the collection of the required blood components. Furthermore, current stem cell transplantation regiments require the collection of more than one similar or different component from one donor or patient. One strategy for maintaining the patients' supply with the required blood components can be the concurrent collection of more than one component from one donor by apheresis, thus multicomponent apheresis.Scope of multicomponent combinations: Combinations are possible for nearly every kind of blood components. In one session it is possible -depending on the apheresis device -to collect up to four plasma units alone, one or more plasma units and one or two red blood cell (RBC) units, one or more plasma units and one or more platelet units, one or more plasma units and one or two RBC units and one or more platelet units, one or two RBC units and one or more platelet units, two RBC units alone, one or more platelet units.Also in leucocytapheresis the collection of more than one blood component has become a routine procedure. Performing allogeneic stem cell apheresis can lead to a cell dose for two transplantations or to one unit of PBSCs and concurrently collected and frozen mononuclear cells used for donor lymphocyte infusions therapy. Autologous mononuclear cell products (e.g. PBSCs or monocytes for dendritic cell generation) usually are cryoconserved before use and require additional plasmaproteins for cryoconservation. The latter can be obtained by the concurrent collection of plasma during leucocytapheresis. Thus, the combination of cell and plasma units or of cell units of different dose or for different purpose are further examples for the implementation of multicomponent apheresis in tumor therapy. Conclusions:The understanding of apheresis technologies facilitates the use of multicomponent apheresis in the vast application field for tailoring the kind, quantity, and quality of blood components for patient care.

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Fuji surge technique and continuous in‐line filtration to improve the quality of single donor platelet concentrates

Cited by 4 publications

References 27 publications

Improvement of plateletpheresis via technical modification on the MCS+

Improvement of plateletpheresis via technical modification on the MCS+

A randomized crossover trial comparing three plateletpheresis machines

Multicomponent apheresis

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