A new direction in automated laboratory testing in Japan: five years of experience with total laboratory automation system management

Abstract BACKGROUND Historically, culture-based microbiology laboratory testing has relied on manual methods, and automated methods (such as those that have revolutionized clinical chemistry and hematology over the past several decades) were largely absent from the clinical microbiology laboratory. However, an increased demand for microbiology testing and standardization of sample-collection devices for microbiology culture, as well as a dwindling supply of microbiology technologists, has driven the adoption of automated methods for culture-based laboratory testing in clinical microbiology. CONTENT We describe systems currently enabling total laboratory automation (TLA) for culture-based microbiology testing. We describe the general components of a microbiology automation system and the various functions of these instruments. We then introduce the 2 most widely used systems currently on the market: Becton Dickinson's Kiestra TLA and Copan's WASPLab. We discuss the impact of TLA on metrics such as turnaround time and recovery of microorganisms, providing a review of the current literature and perspectives from laboratory directors, managers, and technical staff. Finally, we provide an outlook for future advances in TLA for microbiology with a focus on artificial intelligence for automated culture interpretation. SUMMARY TLA is playing an increasingly important role in clinical microbiology. Although challenges remain, TLA has great potential to affect laboratory efficiency, turnaround time, and the overall quality of culture-based microbiology testing.

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The Role of Total Laboratory Automation in a Consolidated Laboratory Network

Clinical Chemistry ◽

10.1093/clinchem/46.5.751 ◽

2000 ◽

Vol 46 (5) ◽

pp. 751-756 ◽

Cited By ~ 30

Author(s):

Richard S Seaberg ◽

Robert O Stallone ◽

Bernard E Statland

Keyword(s):

Cost Effective ◽

Turnaround Time ◽

Automation System ◽

Laboratory Automation ◽

Labor Costs ◽

The Core ◽

The North ◽

Laboratory Network ◽

Automation Systems ◽

Total Laboratory Automation

Abstract Background: In an effort to reduce overall laboratory costs and improve overall laboratory efficiencies at all of its network hospitals, the North Shore–Long Island Health System recently established a Consolidated Laboratory Network with a Core Laboratory at its center. Methods: We established and implemented a centralized Core Laboratory designed around the Roche/Hitachi CLAS Total Laboratory Automation system to perform the general and esoteric laboratory testing throughout the system in a timely and cost-effective fashion. All remaining STAT testing will be performed within the Rapid Response Laboratories (RRLs) at each of the system’s hospitals. Results: Results for this laboratory consolidation and implementation effort demonstrated a decrease in labor costs and improved turnaround time (TAT) at the core laboratory. Anticipated system savings are ∼$2.7 million. TATs averaged 1.3 h within the Core Laboratory and less than 30 min in the RRLs. Conclusions: When properly implemented, automation systems can reduce overall laboratory expenses, enhance patient services, and address the overall concerns facing the laboratory today: job satisfaction, decreased length of stay, and safety. The financial savings realized are primarily a result of labor reductions.

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Automation in haemostasis

Hämostaseologie ◽

10.5482/hamo-12-05-0002 ◽

2013 ◽

Vol 33 (04) ◽

pp. 295-298 ◽

Cited By ~ 2

Author(s):

A. Méndez ◽

S. Brunner-Agten ◽

A. R. Huber

Keyword(s):

Laboratory Testing ◽

Human Factor ◽

Clinical Chemistry ◽

Ancient Greece ◽

Medical Laboratory ◽

Laboratory Automation ◽

Positive Side ◽

Coagulation Testing ◽

Total Laboratory Automation ◽

Academic Personnel

SummaryAutomatia, an ancient Greece goddess of luck who makes things happen by themselves and on her own will without human engagement, is present in our daily life in the medical laboratory. Automation has been introduced and perfected by clinical chemistry and since then expanded into other fields such as haematology, immunology, molecular biology and also coagulation testing. The initial small and relatively simple standalone instruments have been replaced by more complex systems that allow for multitasking. Integration of automated coagulation testing into total laboratory automation has become possible in the most recent years. Automation has many strengths and opportunities if weaknesses and threats are respected. On the positive side, standardization, reduction of errors, reduction of cost and increase of throughput are clearly beneficial. Dependence on manufacturers, high initiation cost and somewhat expensive maintenance are less favourable factors. The modern lab and especially the todays lab technicians and academic personnel in the laboratory do not add value for the doctor and his patients by spending lots of time behind the machines. In the future the lab needs to contribute at the bedside suggesting laboratory testing and providing support and interpretation of the obtained results. The human factor will continue to play an important role in testing in haemostasis yet under different circumstances.

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Experimental fusion of different versions of the total laboratory automation system and improvement of laboratory turnaround time

Journal of Clinical Laboratory Analysis ◽

10.1002/jcla.22400 ◽

2018 ◽

Vol 32 (5) ◽

pp. e22400 ◽

Cited By ~ 5

Author(s):

Hee-Jung Chung ◽

Yoon Kyung Song ◽

Sang-Hyun Hwang ◽

Do Hoon Lee ◽

Tetsuro Sugiura

Keyword(s):

Turnaround Time ◽

Automation System ◽

Laboratory Automation ◽

Total Laboratory Automation ◽

Experimental Fusion

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Specimen Temperature Detection on a Clinical Laboratory Pre-Analytic Automation Track: Implications for Direct-from-Track Total Laboratory Automation (TLA) Systems

SLAS TECHNOLOGY Translating Life Sciences Innovation ◽

10.1177/2472630319881999 ◽

2019 ◽

Vol 25 (3) ◽

pp. 293-299

Author(s):

Caleb S. Roundy ◽

David C. Lin ◽

Paul J. Klopping ◽

Ammon T. Ence ◽

Anthony C. Krezel ◽

...

Keyword(s):

Clinical Laboratory ◽

Complementary Metal Oxide Semiconductor ◽

Oxide Semiconductor ◽

Automation System ◽

Laser Sensor ◽

Laboratory Automation ◽

Specimen Temperature ◽

Temperature Detection ◽

Temperature Detector ◽

Total Laboratory Automation

Clinical laboratory regulations require temperature monitoring of facilities, reagent and specimen storage, as well as temperature-dependent equipment. Real-time specimen temperature detection has not yet been integrated into total laboratory automation (TLA) solutions. An infrared (IR) pyrometer was paired with a complementary metal oxide semiconductor (CMOS) laser sensor and connected to an embedded networked personal computer (PC) to create a modular temperature detection unit for closed, moving clinical laboratory specimens. Accuracy of the detector was assessed by comparing temperature measurements to those obtained from thermocouples connected to battery-operated data loggers. The temperature detector was then installed on a pre-analytic laboratory automation system to assess specimen temperature before and after processing on an integrated thawing and mixing (T/M) robotic workcell. The IR temperature detector was able to accurately record temperature of closed, moving specimens on a pre-analytic automation system. The effectiveness of the T/M workcell was independently verified using the temperature detector. Specimen reroute on the pre-analytic automation track was identified as a potential risk for frozen specimens being inadvertently delivered to future, connected instrumentation. Automated IR temperature detection can be used to verify specimen temperature prior to instrument loading and/or sampling. Such systems could be used to prevent frozen specimens from being inadvertently loaded onto analytical instrumentation in TLA solutions.

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