Evaluation of a pneumatic tube system carrier prototype with fixing mechanism allowing for automated unloading

Abstract Objectives A carrier prototype by Aerocom® (Schwäbisch Gmünd, Germany) for pneumatic tube systems (PTS) is able to transport 9 blood tubes which are automatically fixed by closing the lid. In this study, we examined the influence of the transport on blood sample quality using the carrier prototype comparing to courier transport and a conventional carrier (AD160, Aerocom®). Methods Triplicate blood samples sets (1 lithium heparin, 1 EDTA, 1 sodium citrate) of 35 probands were split among the transportation methods: 1. courier, 2. conventional carrier, and 3. carrier prototype. After transport 51 measurands from clinical chemistry, hematology and coagulation were measured and compared. Results Overall, 49 of the investigated 51 measurands showed a good concordance among the three transport types, especially between the conventional carrier and the carrier prototype. Focusing on well-known hemolysis sensitive measurands, potassium showed no statistically significant differences. However, between courier and both carrier types lactate dehydrogenase (LDH) and free hemoglobin (fHb) showed statistically significant shifts, whereas the clinical impact of the identified differences was neglectable. The median concentration of fHb, for example, was 0.29 g/L (18 µmol/L), 0.31 g/L (19 µmol/L) and 0.32 g/L (20 µmol/L) for courier transport, conventional carrier and carrier prototype, respectively. These differences cannot be resolved analytically since the minimal difference (MD) for fHb is 0.052 g/L (3.23 µmol/L), at this concentration. Conclusions The carrier prototype by Aerocom® is suitable for transportation of diagnostic blood samples. The overall workflow is improved by decreasing hands-on-time on the ward and laboratory while minimizing the risk of incorrectly packed carriers.

[1]  L. Heinemann,et al.  Measurement Uncertainty Impacts Diagnosis of Diabetes Mellitus: Reliable Minimal Difference of Plasma Glucose Results , 2019, Diabetes Therapy.

[2]  C. Nielsen,et al.  Use of clinical data and acceleration profiles to validate pneumatic transportation systems , 2019, Clinical chemistry and laboratory medicine.

[3]  Chidambharam Choccalingam,et al.  The Effects of Sample Transport by Pneumatic Tube System on Routine Hematology and Coagulation Tests , 2018, Advances in hematology.

[4]  Laura Heireman,et al.  Causes, consequences and management of sample hemolysis in the clinical laboratory. , 2017, Clinical biochemistry.

[5]  P. Bagos,et al.  The impact of pneumatic tube system on routine laboratory parameters: a systematic review and meta-analysis , 2017, Clinical chemistry and laboratory medicine.

[6]  Yu Chen,et al.  Comparison of pneumatic tube system with manual transport for routine chemistry, hematology, coagulation and blood gas tests , 2017, Clinical chemistry and laboratory medicine.

[7]  A-Jin Lee,et al.  Effects of one directional pneumatic tube system on routine hematology and chemistry parameters; A validation study at a tertiary care hospital , 2017, Practical laboratory medicine.

[8]  Hüseyin Erdal,et al.  The Effect of Pneumatic Tube Systems on the Hemolysis of Biochemistry Blood Samples , 2017, Journal of emergency nursing: JEN : official publication of the Emergency Department Nurses Association.

[9]  C. Négrier,et al.  Pre-analytical effects of pneumatic tube system transport on routine haematology and coagulation tests, global coagulation assays and platelet function assays. , 2017, Thrombosis research.

[10]  A. Petersmann,et al.  Extending laboratory automation to the wards: effect of an innovative pneumatic tube system on diagnostic samples and transport time , 2017, Clinical chemistry and laboratory medicine.

[11]  P. Maboudou,et al.  Gentle blood aspiration and tube cushioning reduce pneumatic tube system interference in lactate dehydrogenase assays , 2016, Annals of clinical biochemistry.

[12]  Mario Plebani,et al.  Hemolyzed specimens: a major challenge for emergency departments and clinical laboratories , 2011, Critical reviews in clinical laboratory sciences.

[13]  G. Ellis,et al.  An episode of increased hemolysis due to a defective pneumatic air tube delivery system. , 2009, Clinical biochemistry.

[14]  J. Lüdemann,et al.  Considerably reduced centrifugation time without increased hemolysis: evaluation of the new BD Vacutainer SSTTMII Advance. , 2007, Clinical chemistry.

[15]  D. Yücel,et al.  Effect of in vitro hemolysis on 25 common biochemical tests. , 1992, Clinical chemistry.

[16]  A. Bayir,et al.  Hemolysis associated with pneumatic tube system transport for blood samples , 1969, Pakistan journal of medical sciences.

[17]  M. Fontenay,et al.  Impact of a pneumatic tube system transport on hemostasis parameters measurement: the experiment of Cochin universitary hospital (AP-HP, Paris, France). , 2017, Annales de biologie clinique.

[18]  Y. Benjamini,et al.  Controlling the false discovery rate: a practical and powerful approach to multiple testing , 1995 .