An ecosystem of interconnected technologies to increase efficiencies in blood establishments: The example of the Blood and Tissue Bank of Aragón, Spain.

IF 1.8 4区医学 Q3 HEMATOLOGY Vox Sanguinis Pub Date : 2024-10-23 DOI:10.1111/vox.13752

Ana Isabel Pérez Aliaga, Irene Ayerra, Marcia Cardoso, Fernando Puente, Alfonso Aranda, José María Domingo, Rosa Plantagenet-Whyte

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Abstract

Background and objectives: Blood establishments face environmental, financial, demographic and societal challenges that may impair sustainable blood supply to patients. This study presents the technologies (devices and software) assembled in a global ecosystem implemented by the Blood and Tissue Bank of Aragón (BTBA), Spain, over the last decade to overcome these challenges.

Materials and methods: Descriptive yearly activity data (2013-2023) of BTBA were retrospectively collected to evaluate the impact of different technologies on blood processing efficiency, focusing on the production of blood components (red blood cell concentrates [RCCs], platelet concentrates [PCs]) and plasma. Operator satisfaction about the technologies introduced in daily routine work was also monitored.

Results: Between 2013 and 2023, the annual production decreased by 16.0% for RCCs and increased by 13.3% for PCs. From 2020, all PCs were treated with pathogen reduction technology, and no inventory stock-out was reported. The lowest PC expiry rate (0.2%) was observed after the implementation of the software for blood processing and PC stock management. The deployment of this software also improved plasma recovery: on average, an extra plasma volume of 9 mL was collected per donation in 2023 compared to 2015. A survey confirmed staff satisfaction.

Conclusion: The progressive implementation of automated and software-based solutions was key to increasing efficiencies in BTBA. This enabled the optimization of blood processing by maximizing productivity, enhancing traceability, reducing overproduction and wastage and increasing the yield of recovered plasma, while ensuring blood product safety and staff satisfaction.

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提高血液机构效率的互联技术生态系统：以西班牙阿拉贡血液和组织银行为例。

背景和目标：血液机构面临着环境、财务、人口和社会方面的挑战，这些挑战可能会影响对患者的可持续血液供应。本研究介绍了西班牙阿拉贡血液和组织库（BTBA）在过去十年中为克服这些挑战而在全球生态系统中采用的技术（设备和软件）：回顾性收集了阿拉贡血液和组织库的描述性年度活动数据（2013-2023 年），以评估不同技术对血液处理效率的影响，重点是血液成分（红细胞浓缩物 [RCC]、血小板浓缩物 [PCs]）和血浆的生产。此外，还监测了操作员对日常工作中采用的技术的满意度：结果：2013 年至 2023 年期间，浓缩红细胞的年产量减少了 16.0%，浓缩血小板的年产量增加了 13.3%。从 2020 年起，所有 PC 都采用了病原体消减技术，没有出现库存短缺的情况。实施血液处理和 PC 库存管理软件后，PC 过期率最低（0.2%）。该软件的部署还提高了血浆回收率：与 2015 年相比，2023 年每次捐献平均多回收 9 毫升血浆。一项调查证实了员工的满意度：逐步实施自动化和软件解决方案是提高 BTBA 效率的关键。这使血液处理得以优化，最大限度地提高了生产率，增强了可追溯性，减少了过量生产和浪费，提高了回收血浆的产量，同时确保了血液制品的安全和员工的满意度。

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来源期刊

Vox Sanguinis 医学-血液学

CiteScore

4.40

自引率

11.10%

发文量

156

审稿时长

6-12 weeks

期刊介绍： Vox Sanguinis reports on important, novel developments in transfusion medicine. Original papers, reviews and international fora are published on all aspects of blood transfusion and tissue transplantation, comprising five main sections: 1) Transfusion - Transmitted Disease and its Prevention: Identification and epidemiology of infectious agents transmissible by blood; Bacterial contamination of blood components; Donor recruitment and selection methods; Pathogen inactivation. 2) Blood Component Collection and Production: Blood collection methods and devices (including apheresis); Plasma fractionation techniques and plasma derivatives; Preparation of labile blood components; Inventory management; Hematopoietic progenitor cell collection and storage; Collection and storage of tissues; Quality management and good manufacturing practice; Automation and information technology. 3) Transfusion Medicine and New Therapies: Transfusion thresholds and audits; Haemovigilance; Clinical trials regarding appropriate haemotherapy; Non-infectious adverse affects of transfusion; Therapeutic apheresis; Support of transplant patients; Gene therapy and immunotherapy. 4) Immunohaematology and Immunogenetics: Autoimmunity in haematology; Alloimmunity of blood; Pre-transfusion testing; Immunodiagnostics; Immunobiology; Complement in immunohaematology; Blood typing reagents; Genetic markers of blood cells and serum proteins: polymorphisms and function; Genetic markers and disease; Parentage testing and forensic immunohaematology. 5) Cellular Therapy: Cell-based therapies; Stem cell sources; Stem cell processing and storage; Stem cell products; Stem cell plasticity; Regenerative medicine with cells; Cellular immunotherapy; Molecular therapy; Gene therapy.