Challenging the 30-min rule for thawed plasma.

BACKGROUND AND OBJECTIVES: Frozen plasma (FP) is thawed prior to transfusion and stored for ≤5 days at 1-6°C. The effect of temperature excursions on the quality and safety of thawed plasma during 5-day storage was determined. MATERIALS AND METHODS: Four plasma units were pooled, split and stored at ≤-18°C for ≤90 days. Test units T30 and T60 were exposed to 20-24°C (room temperature [RT]) for 30 or 60 min, respectively, on days 0 and 2 of storage. Negative and positive control units remained refrigerated or at RT for 5 days, respectively. On Day 5, test units were exposed once to RT for 5 h. Quality assays included stability of coagulation factors FV, FVII, FVIII, fibrinogen and prothrombin time. Bacterial growth was performed in units inoculated with ~1 CFU/ml or ~100 CFU/ml of Serratia liquefaciens, Pseudomonas putida, Pseudomonas aeruginosa or Staphylococcus epidermidis on Day 0. RESULTS: Testing results of all quality parameters were comparable between T30 and T60 units (p < 0.05). Serratia liquefaciens proliferated in cold-stored plasma, while P. putida showed variable viability. Serratia epidermidis and P. aeruginosa survived but did not grow in cold-stored plasma. Positive and negative controls showed expected results. Overall, no statistical differences in bacterial concentration between T30 and T60 units were observed (p < 0.05). CONCLUSION: Multiple RT exposures for 30 or 60 min do not affect the stability of coagulation factors or promote bacterial growth in thawed plasma stored for 5 days. It is therefore safe to expose thawed plasma to uncontrolled temperatures for limited periods of 60 min.

Time-temperature indicators versus temperature indicators for transfusion practice: Application in the real hospital setting.

BACKGROUND AND OBJECTIVES: Temperature indicators (TIs) are used to monitor the surface temperature of red blood cell (RBC) units. We compared the utility of a newly developed time-temperature indicator (TTI) prototype, Freshzone TTI (FZTTI) (Freshzone, Seoul, South Korea) and two US Food and Drug Administration-approved TIs, Safe-T-Vue 10 (STV10; Temptime Corporation, Morris Plains, NJ) and Blood Temp 10 (BT10; Timestrip UK Ltd, Cambridge, UK). MATERIALS AND METHODS: FZTTI, STV10 and BT10 were attached to 91 RBC units after issue (including eight units that were stored in refrigerators in the ward before transfusion). The time for colour change (CC) was monitored based on the 30-min rule. The CC of FZTTI indicated the total time elapsed since the temperature of RBC units exceeded 10°C, and the CC of STV10 and BT10 indicated that the temperature of RBC units exceeded 10°C. RESULTS: In 83 units, the median time for CC differed significantly between FZTTI and the TIs (51.4 min in FZTTI vs. 13.9 min in STV10 and 10.5 min in BT10, both at p < 0.001). In addition, 95.2% (n = 79) of FZTTI tags changed colour after 30 min of issue, whereas 96.4% (n = 80) of STV10 and 98.8% (n = 82) of BT10 changed colour within 30 min of issue. In the eight units stored in refrigerators, the time for CC between the TTI and TIs was significantly different. CONCLUSION: FZTTI outperformed the TIs, indicating that it is a feasible option for use in transfusion practice.

Deviations in red cell blood component temperature during laboratory processing and at blood return monitored by a time-temperature indicator device.

OBJECTIVES: To evaluate the performance and utility of a time-temperature indicator (TTI) to determine the cumulative exposure time (CET) of red cell components (RCC) to temperatures above 10°C occurring within and outside the transfusion laboratory. BACKGROUND AND OBJECTIVES: Blood centres often use the '30 or 60-min rule' for accepting RCC exposed to room temperature (RT) back into inventory. Effective monitoring of these temperature deviations is however lacking. MATERIALS AND METHODS: A Timestrip PLUS® TP153 10°C (TS + 10) TTI was attached to RCC units after preparation of the unit in the blood bank or on issue to the ward, to track the CET > 10°C during laboratory processing and outside the transfusion laboratory. RESULTS: The mean CET of 153 RCC tracked within the laboratory was 56 min. Sixty-four (41.8%) and 34 (22.2%) of RCC had core temperature (CT) >10°C for more than 30 and 60 min, respectively. Among the 69 RCC that were returned unused, 27 (39.1%), 17 (24.6%) and 5 (7.2%) RCC units had CT >10°C for more than 30, 60 and 120 min respectively. CONCLUSION: A large proportion of RCC have CT >10°C exceeding 30 min during handling within the transfusion laboratory, as well as when RCC are returned unused from transfusion locations. Corrective measures should be implemented to better manage the cold chain to avoid undesirable consequences to blood transfusion. A temperature sensitive device that can also indicate CET can be employed to objectively monitor the period that RCC remained at a CT that exceeds 10°C.

Extending the 30-minute rule for red cell units - investigation of the bacterial risk of 60-minute exposures to ambient temperature.

BACKGROUND AND OBJECTIVES: In the UK, a significant proportion of red cell units is discarded due to the 30-min rule governing out of temperature control. Studies have shown that repeated warming to ambient temperature has little impact on red cell quality or bacterial growth. We aimed to validate extension of the rule to 60 minutes by investigation of repeated same, and different, day exposures on bacterial growth. MATERIALS AND METHODS: Red cell units were seeded individually at 100-1000 cfu/ml with Yersinia enterocolitica, Serratia liquefaciens, Pseudomonas putida, Staphylococcus epidermidis, Enterobacter cloacae and Bacillus cereus. Test units were exposed to 30°C for 30 or 60 min on a single occasion at days 15, 17 and 21, or thrice on day 15 of a 35-day storage period. A 10-fold increase in bacterial counts in tests versus controls maintained in cold storage was considered indicative of significant bacterial proliferation. RESULTS: Exposure of units to 30°C for up to 60 min had no substantial impact on the growth of bacteria and all mesophiles declined steadily in tests and controls. Only P. putida showed a near significant elevation in count on exposure for 60 min at day 35. CONCLUSIONS: Extension of the out of temperature rule for red cells to 60 min will potentially not compromise patient safety, although exposures to ambient temperatures should be minimized. Units returned to storage must not be reissued for at least 6 hours and not be exposed to ambient temperatures on more than three occasions.

Utility of temperature-sensitive indicators for temperature monitoring of red-blood-cell units.

BACKGROUND AND OBJECTIVES: The 30-min rule has been used to maintain a core temperature (CT) of red-blood-cell (RBC) units below 10°C during transportation. We evaluated the utility of temperature-sensitive indicators (TIs) to monitor the surface temperature (ST) of RBC units and to explore whether TIs can help with compliance with the 30-min rule by extrapolating or correlating temperature change with time. MATERIALS AND METHODS: Two US FDA-approved TIs, Safe-T-Vue 10 (STV10; Temptime Corporation, Morris Plains, NJ, USA) and Timestrip Blood Temp 10 (BT10; Timestrip UK Ltd, Cambridge, UK), were attached to 50 RBC units. After issue, their colour change indicating 10°C was monitored, and temperature excursions were measured by standard reading. In additional 18 RBC units, both ST and CT were monitored simultaneously. RESULTS: In 50 RBC units, 94% of STV10 and 100% of BT10 showed colour change indicating 10°C within 30 min; 4% of STV10 and 18% of BT10 showed it during transportation. The time for colour change indicating 10°C differed significantly between STV10 and BT10 (19·0 vs. 5·6 min, P < 0·001). In additional 18 RBC units, 83·3% of STV10, 100% of BT10 and 88·9% of CT reached 10°C within 30 min, and the time for colour change indicating 10°C was 24·4 min in STV10, 14·6 min in BT 10 and 24·2 min in CT (P < 0·001). CONCLUSION: In two TIs, the time for colour change indicating 10°C varied considerably. To enhance the utility of TIs, further improvement and standardization would be needed.

Are the 'rules' for times in set up and duration of red cell transfusion too strict?

OBJECTIVES: To discover if any adverse clinical effects have been reported to the UK haemovigilance scheme, Serious Hazards of Transfusion (SHOT) relating to delays in set up of transfusion or extended transfusion time for red cell units. BACKGROUND: Current guidance for duration of transfusion is based on outdated studies that do not reflect current UK Blood Service practices. Recent evidence suggests that the '30-min rule' could be extended without adverse effects. METHODS: Aggregated data from reports to SHOT covering a 5-year period (2010-2014) were reviewed in order to identify adverse clinical outcomes related to delay in set up of a red cell transfusion of more than 30 min after removal from cold storage, or total transfusion time of longer than 5 h. RESULTS: Five years of data from SHOT shows that there were no adverse clinical events related to delays in setting up transfusion or extended transfusion time between 2010 and 2014. There were a total of 382 reports which included 143 delays in set-up, and 239 episodes where transfusion took longer than 5 h. CONCLUSIONS: Delays in set up of transfusion and extended transfusion time did not result in any adverse clinical outcomes. Current guidance may be too stringent and lead to increased wastage.

Changing the 30-min Rule in Canada: The Effect of Room Temperature on Bacterial Growth in Red Blood Cells.

BACKGROUND: To maintain product quality and safety, the '30-min rule' requires the discard of red blood cells (RBCs) that are exposed to uncontrolled temperatures for more than 30 min. Recent studies suggest this rule may safely be extended to a 60-min rule. METHODS: A pool-and-split design study (N = 4) was run in parallel at Canadian Blood Services (SAGM RBCs) and Héma-Québec (AS-3 RBCs). RBCs were spiked with ∼1 colony-forming unit/ml of mesophilic and psychrophilic bacteria. Control units remained in storage at 1-6 °C for 42 days. Test 30 (T30) and T60 units were exposed to room temperature (RT) six times during storage, each time for 30 and 60 min, respectively. Bacterial proliferation was monitored. RESULTS: Mesophilic bacteria do not proliferate in RBCs. The growth of psychrophilic bacteria is not significantly different in RBCs exposed for 30 or 60 min to RT (p < 0.05). CONCLUSION: The study findings were the final evidence to support extension from a 30-min rule to a 60-min rule in Canada.