Investigation of the incident

Inspection of the two 250 mL bottles of heparinized saline being used in the induction area revealed that, despite both bottles being clearly labeled as heparinized saline, the label on one bottle covered another label. The original label indicated that the bottle contained a potassium chloride solution (4 mmol mL⁻¹); the second label indicated the technician who had added heparin to the bottle.

Analysis of the incident

There are several questions that immediately spring to mind in this case. Was the technician responsible for the error? Was the organization—the practice––in any way responsible for the error? How could this error be prevented in the future? However, before answering these questions, contextual details are needed.

All fluids used in this practice, on both the small and large animal sides of the hospital, were made in-house at a central location because the owners believed the size of the hospital made this a cost-effective practice. For those with direct patient care responsibilities it was never clear from week to week who in the central production facility actually produced the fluids or filled orders that were submitted by the various hospital sections. Fluid volumes of one liter or less were dispensed in glass bottles with rubber stoppers and were distributed from the central location in cardboard boxes.

Every Monday and Friday, late in the afternoon, technicians throughout the hospital restocked shelves with various supplies that had been ordered earlier in the morning, including fluids. Those technicians working in sections that used heparinized saline added heparin to bottles containing 250 mL of normal saline (0.9% NaCl) to make a saline solution containing 4 units mL⁻¹ of heparin. Another label was then affixed to the bottle indicating that heparin had been added, the date it was added, and by whom.

On any given day, the anesthesia service was responsible for anesthetizing 12 to 19 small animal patients, of which 80% were dogs, 15% were cats, and the remainder were birds, pocket pets, and reptiles. In this practice the anesthetic technique and drugs chosen for anesthesia were selected based on each patient’s health (physical status) and the procedure to be performed. In general, anesthesia consisted of premedicating patients prior to intravenous catheterization. After the premedication drugs had taken effect a catheter was inserted into a peripheral vein, usually a cephalic vein, the catheter was capped with an injection cap, and the catheter flushed with sterile heparinized saline usually administered with a 6- or 12-mL syringe.

Prior to induction of anesthesia, each patient’s heart was checked to ascertain rate and rhythm, and mucous membranes were assessed as to color and capillary refill time. Depending on the health status of each patient, anesthesia was induced with an injectable drug administered to achieve a plane of anesthesia suitable for orotracheal intubation. After intubating and securing the endotracheal tube, it would be attached to a breathing circuit, and a flow of oxygen started. At this point in the induction process the anesthetist would again check the patient’s heart rate and rhythm. If the patient’s condition was as expected, the anesthetist would turn on the vaporizer so as to start the delivery of inhalant anesthetic. The intravenous catheter was often flushed again at this time and then fluids were started to maintain intravascular volume during anesthesia.

Returning to the specific analysis of this case: the organization’s operating procedures, specifically those for the production and delivery of fluids, created latent conditions that set the technician up as the final common pathway for this error. To the technician’s credit he fully recognized his role in the error and accepted responsibility for it; there was no equivocation or attempt to place responsibility elsewhere. Of crucial importance, the technician explained how the error occurred.

Normal saline was the only fluid that had been ordered on the Monday morning prior to this incident. The technician picked up the order in its cardboard box at the central fluid production facility and took it to the anesthesia induction room. Here, as a matter of routine, every Monday and Friday afternoon, in the same location and at about the same time of day, the anesthesia technicians added heparin to bottles of normal saline to make heparinized saline. Concentrated potassium chloride was also kept in this location, but it had not been ordered that morning and the technician did not expect it to be in the box. That Monday afternoon the two anesthesia technicians were working together to make heparinized saline, but they were having a conversation about an issue unrelated to the task at hand. This scenario describes a skill-based error due to a slip, specifically a capture slip in that the technician’s attention was focused elsewhere and there was a failure of a timely check to make sure it was normal saline to which heparin was being added. It was also assumed that the box of fluids contained only normal saline because no other types of fluids had been ordered that morning. Adding heparin to normal saline was also a task performed routinely in the same familiar location twice a week.

There was no evidence that the technician intended to cause harm and the facts clearly showed that there were multiple factors that contributed to this error. In addition, the technician did not have a prior history of violations and he was intensely remorseful (see “Analysis of the person(s) at the sharp end: accountability” in Chapter 3 and Figure 3.5). Yes, the technician was responsible for the final step in the pathway to this error, but mitigating circumstances, especially the manner in which the practice made, labeled, and distributed fluids in-house (more specifically concentrated potassium chloride), and the failure at the central fluid production facility to correctly fill fluid orders, pointed to a failure of the system.

The practice owners acknowledged the mitigating factors inherent in the practice’s standard operating procedures, and recognized that any person tasked with the responsibility of making up heparinized saline within the environment of this practice, was just as likely to commit the same error. No one could predict when or how such an error would occur again, but the traps—the latent conditions—were all in place waiting to generate another fluid-related error. These facts demanded a closer look at the practice’s protocols and procedures concerning its fluid production and distribution processes.

As a consequence of this error, an evaluation of the system was undertaken. One immediate decision was to stop making and bottling potassium chloride solution and purchase it commercially so that there would be no chance of confusing it with normal saline. The commercial potassium chloride vials were then stocked in wards or service areas separate from all other fluids. In addition, the distinct packaging of the vials also helped prevent them from being confused with other fluids in use in the practice. For a short time the practice continued to produce normal saline and lactated Ringer’s solution, especially for use in large animal patients. However, as a result of this series of adverse incidents, and because of other complaints about in-house fluids (complaints that had been ignored up to then but that were becoming more prevalent) the practice pursued an in-depth analysis of the fluid production system itself. This found that there was a lack of quality control at a number of steps in the production process. Soon thereafter the practice switched to stocking only commercially produced fluids.

A cautionary note is necessary here. Switching from in-house produced fluids to those produced commercially does not assure safe practices or patient safety. Pharmaceutical houses, in an effort to develop brand identity and market loyalty, frequently use product labeling as a marketing strategy to achieve those goals. It is not unusual for a manufacturer to produce two very different classes of drugs and label them similarly. As a result, solutions such as potassium chloride continue to be administered to human patients when the injection of other drugs was intended (Charpiat et al. 2016). Figure 5.1 graphically demonstrates how similar packaging of three different types of fluids used for flushing intravenous lines or reconstituting antibiotics, can increase the likelihood that at some unknown point in time the wrong solution will be administered to a patient, possibly with fatal consequences (Lankshear et al. 2005).

As already mentioned, but worth repeating, had the practice approached the error as a technician-only problem and reprimanded or terminated him as the solution to the problem, there would almost certainly have been more fluid-associated patient harms or deaths at some point in the future, at a time no one could predict. However, by taking a systems approach to the problem the practice eventually discovered the root causes of this and other fluid-related problems and effectively solved the latent problems that placed all patients at risk of harm.

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