Recent years have witnessed great development of TLA (Total Laboratory Automation) technology, however, its application hit the bottleneck of high cost and openess to other parties' instruments. Specifically speaking, the initial purchase of the medical devices requires large sum of money and the new system can hardly be compatible with existing equipment. This thesis proposes a new thought for system implementation that through incremental upgrade, the initial capital investment can be reduced and through open architecture and interfaces, the seamless connection of different devices can be achieved. This thesis elaborates on the standards that open architecture design should follow in aspect of mechanics, electro-communication and information interaction and the key technology points in system implementation.
Automation, Laboratory ; Computer Systems

Liquid level detection (LLD) is necessary for eliminating carry-over of needle's outside by limiting the depth the needle probes into liquid in auto clinical laboratory analyzers. This paper listed various demands of liquid-handling system under different situations; reviewed various LLD techniques, such as capacitive, air pressure, mechanical vibration, ultrasound, light reflection, CCD imaging etc.; briefly introduced the working principles, features, and limitation of the LLDs; and recapitulated the characteristics of contact and non-contact LLDs. Lastly, the next generation technique of LLD is prospected.
Automation ; Clinical Laboratory Techniques ; instrumentation ; methods

This paper introduces a kind of evaluation method in pipetting performance on new fully automated biochemistry analyzers by experiments. The performance of sample pipetting volume is confirmed by dye dilution method, the performance of reagent pipetting volume and dummy volume is done by weighing method. Meanwhile, researches and comparative researches on dummy volumes in different conditions have been made, providing valuable reference for clinical applications of automatic biochemistry analyzers.
Automation, Laboratory ; instrumentation ; methods ; Biochemistry ; instrumentation ; methods

In view of the fact that medical inspection equipment sold in the domestic market is mainly imported from abroad and very expensive, we developed a full-automatic fluorescence analyzer in our center, presented in this paper. The present paper introduces the hardware architecture design of FPGA/DSP motion controlling card+PC+ STM32 embedded micro processing unit, software system based on C# multi thread, design and implementation of double-unit communication in detail. By simplifying the hardware structure, selecting hardware legitimately and adopting control system software to object-oriented technology, we have improved the precision and velocity of the control system significantly. Finally, the performance test showed that the control system could meet the needs of automated fluorescence analyzer on the functionality, performance and cost.
Automation, Laboratory ; Equipment Design ; Fluorescence ; Software

BACKGROUND: For the efficient management of clinical pathology laboratory, not only the economic side but also the quality of test should be considered. Therefore, the authors investigated the status of laboratory in the management point including the status of technical personnel by survey and tried to find out the fundamental status of work environment, laboratory automation, computerization, and to evaluate the efficiency of management of clinical pathology laboratories in Korea. METHOD: The questionnaires included those for investigating laboratory management status, qualities of laboratory personnels, workloads, test items and numbers of tests performed annually. It contained 22 items with 32 detailed sub-questionnaires for laboratory personnel survey, and 9 items with 106 detailed sub-questionnaires for facilities. We sent those three times to 400 laboratories that were participating in the National External Quality Assessment Scheme in Korea and analysed the answers by descriptive statistics, ANOVA, t-test and correlation analysis. RESULTS: The replies were from 96 laboratories and 326 technical personnels. Among the 96 laboratories, there were 71 full time employed clinical pathologists. The annually performed number of tests were increased with the increased the size of laboratory, that was classified by number of personnels. As the laboratory size was increased, part time personnels, cases of test per technical personnel, automation and computerization, satisfaction for their work (58,2%) were increased but decreased satisfaction of salaries. CONCLUSIONS: We surveyed the present employee status of laboratory personnels and status of laboratory and offered fundamental data of clinical laboratory management in Korea.
Automation ; Automation, Laboratory ; Humans ; Korea* ; Laboratory Personnel ; Pathology, Clinical ; Surveys and Questionnaires ; Salaries and Fringe Benefits

It may be difficult to establish laboratory information system(LIS) on radioimmunoassay works, which may result in many technical problems on computerization. Recently we have developed integrated information system in the radioimmunoassay works of endocrine laboratory in Kyung Hee Medical center. We have used VAX-6510 with 64 MB main memory and VAX-6210 with 32 MB main memory (DEC; Digital Equipment INC) which are main computers of the hospital. Additional devices were only 4 terminals and 4 printers in the laboratory and the office. This system has measurably changed the allocation of technologists' time and effort, the number of the clerical support staff in the laboratory and the speed and accuracy of laboratory response. And physicians could easily obtain and compare the patients' current and past laboratory results with computerization. In this article we have focused on experience gained in the automation of radioimmunoassay works of endocrine laboratory. The authors suggest that this computerized system of endocrine laboratory could provide a progressive approach to total LIS and it could serve as a model for other hospitals.
Automation ; Clinical Laboratory Information Systems* ; Information Systems ; Memory ; Radioimmunoassay*

BACKGROUND: The transition from manual processing of patient samples to automated workflows in medical microbiology is challenging. Although automation enables microbiologists to evaluate all samples following the same incubation period, the essential incubation times have yet to be determined. We defined essential incubation times for detecting methicillin-resistant Staphylococcus aureus (MRSA), multi-drug resistant gram-negative bacteria (MDRGN), and vancomycin-resistant enterococci (VRE). METHODS: We monitored the growth kinetics of MRSA, MDRGN, and VRE between two and 48 hours on chromogenic media to establish the time points of first growth, single colony appearance, and typical morphology for 102, 104, 106, and 108 colony forming units/mL. Subsequently, we imaged plates inoculated with 778 patient samples after 20, 24, and 36 hours. RESULTS: The first growth, single colony appearance, and typical morphology time points were inoculum-dependent. First growth appeared after 6–18 hours, 4–18 hours, and 8–48 hours for MRSA, MDRGN, and VRE, respectively, and single colonies appeared at 12–18 hours, 6–20 hours, and 12–48 hours, respectively. Typical morphology was visible at 14–22 hours and 12–48 hours for MRSA and VRE, but was not determined for MDRGN. By examining patient samples, ≥98% of MRSA and MDRGN were visible 20 hours after the start of incubation. Following 24 hours of incubation, only 79.5% of VRE were clearly visible on the respective plates. CONCLUSIONS: An incubation time of 20 hours is sufficient for detecting MRSA and MDRGN. VRE growth is much slower and requires additional imaging after 36 hours.
Automation ; Automation, Laboratory* ; Bacteria* ; Gram-Negative Bacteria ; Humans ; Kinetics* ; Methicillin-Resistant Staphylococcus aureus ; Vancomycin-Resistant Enterococci

BACKGROUND: To cope with demands of ever-increasing test volumes, laboratories have implemented the total laboratory automation (TLA) system. The main goals of TLA are superproductivity, shortened turnaround time and universal availability of laboratory data throughout the hospital and/or hospital network. The TLA system was installed at Samsung Medical Center (SMC) in 1994; at Asan Medical Center (AMC) in 1995. To evaluate the benefits of TLA system, the comparative study between the laboratories with varying degree of TLA installation and Seoul National University Hospital (SNUH) without TLA installation was conducted. METHODS: Three laboratories of tertiary care university hospitals participated in this study; SMC (with the full TLA installation), AMC (with the TLA installation in outpatient laboratory) and SNUH (without TLA installation). To evaluate productivity of a TLA system, the productivity of a technologist and a laboratory person between laborotories with and without TLA systems, the comparison of productivity between TLA laboratories and non-TLA laboratories in AMC, and test numbers per hospital bed were obtained. To evaluate the qualitative aspects, the turnaround time (TAT) analysis was carried out. For overall performance index, the length of hospital stay was calculated and analyzed. RESULTS: The test numbers per technologist in AMC, SMC, and SNUH were 177,082.2, 161,966.7 and 95,752.5, repectively in 1997. The test numbers per laboratory personnel including physicians in AMC, SMC, and SNUH were 108,287.7, 118,682.5, and 67,304.3, repectively in 1997. Those per hospital bed were 6841.8, 12194.1, and 6192.0, repectively. The turnaround times of routine hematologic tests in AMC (Outpatient) and SMC were 75 minutes and 102 minutes, and those of routine chemistry tests were 49 minutes and 106 minutes. CONCLUSIONS: The laboratories with TLA installation showed much improved productivities in all categories analyzed; especially test numbers per hospital bed. The TLA system would be the vehicle of the laboratory to gain the superproductivity without sacrificing the quality of laboratory and to ensure the short turnaround time.
Automation, Laboratory* ; Chemistry ; Chungcheongnam-do ; Efficiency* ; Hematologic Tests ; Hospitals, University ; Humans ; Laboratory Personnel ; Length of Stay ; Outpatients ; Seoul ; Tertiary Healthcare

This paper is to introduce the conception, basic constitution and working flow of laboratory automatic systems, and the domestic and world developments of the laboratory pipelining systems. It analyses the problems and the preferred scheme which should be given careful consideration when a system is to be built in the hospital.
Automation ; Clinical Laboratory Information Systems ; Clinical Laboratory Techniques ; instrumentation ; Computer Systems ; Laboratories, Hospital ; standards ; Software ; Specimen Handling ; instrumentation ; methods

No abstract available.
*Algorithms ; Automation ; Clinical Laboratory Information Systems/*standards ; Humans ; Immunoassay/*methods ; Indicator Dilution Techniques ; alpha-Fetoproteins/*analysis