Heart failure is a clinical syndrome in which the structural or functional dysfunction of the heart occurs in either systole or diastole or both. The most common cause is coronary insufficiency, in which the heart is not able to circulate blood rapidly between body tissues and collect it and, as the result, a combination of clinical manifestations such as congestion, shortness of breath, weakness, and fatigue occurs (
1,
2).
The application of PA catheters has always been controversial among cardiac anesthesiologists PA catheters are commonly used in adults in centers where CPB facilities are available Proponents of PAC suggest that timing catheter placement, interpretation of PAC data, and appropriate initial intervention to monitor its data have significant consequences on selecting the appropriate treatment plan (
6).
Decreased mortality in high-risk surgical patients has been reported in patients with preoperative PAC and protocol-based interventions. The indications for installing a PA catheter are:
(1) Pulmonary hypertensions evaluation and diagnosis;
(2) diagnosing and investigating the cause of shock by evaluating ScvO2 and differentiating septic shock from cardiogenic;
(3) evaluation of patient volume status (accurate calculation of fluids based on gold direct therapy (GDT));
(4) evaluation of pericardial disorders such as cardiac tamponade;
(5) evaluation of right heart and some valvular and congenital diseases and heart shunts before and after surgery (
7).
Finally, with the PAC catheter, we are able to measure the parameters that help us in hemodynamic stability. These include ventricular function, pulmonary vascular resistance, ScvO2, CI measurement, the patient’s core temperature (difference in RV and LV function), and the measurement of cardiac filling pressure during injection of cardioplegia solution into the anterograde, which cannot be assessed with central vein line alone.
It is also possible to measure cardiac output every 30 to 60 minutes semicontiniously (
7).
In the anesthesia management of our patient, the CI of the monitor showed 2. L/min/m
2 in ICU ward. Comparing this number with the increase in lactate reported during the first hours after surgery and the percentage of intravenous mixed blood, which was above 80%, suggested that central visceral perfusion may have been impaired. It should be noted that the patient’s MAP pressure was 60 - 65 mmHg with norepinephrine. For the patient, 200 + 200 mL of normal saline was injected in a bolus for 15 minutes, and his CI reached 2.1 L/min/m
2 (
Table 1, ICU 2). Echocardiography performed by a fellow cardiologist showed no a change in the patient’s E.F. compared to that in the preoperative period (about 15%).
| Hemodynamic Changes | Operation Room | ICU 1 a | ICU 2 b | ICU 3 c | ICU 4 d |
|---|
| Cardiac index | 2.4 | 1.7 | 2.1 | 2.8 | 3.1 |
| MAP | 65 | 50 | 55 | 65 | 75 |
| Intravenous mixed blood oxygenation | 70% | 80% | 78% | 75% | 75% |
a Time that patient transferred to ICU
b Time after gold direct therapy
c Time after the patient was extubated
d Time that PA catheter removed
Due to the positive evaluation of the patient’s fluid challenge and CI improvement, a decision was made to extubate the patient, as the result of which the CI reached 2.8 L/min/m
2 a few hours later (
Table 1, ICU 3).
Despite the improvement of clinical symptoms, the drip of NEP incontinence continued, as the result of which CI reached 3.1 L/min/m
2 two days after the patient was extubated and the PA catheter was removed (
Table 1, ICU 4).
It should be noted that the amount of serum therapy according to GDT protocol was well-observed in this patient (
8), and lactate fell below two over time. Intravenous mixed blood oxygenation was reported to be about 75%.
An important measure that was implemented for this patient was his early extubation after the stabilization of cardiac and pulmonary symptoms (
9).
It should be noted that minimal sedation can cause a reduction in blood pressure of the patients like our case, and preferably drugs with greater cardiac stability are used. For our patient, fentanyl at a dose of l00 µg/kg/h, as well as the non-narcotic steroids drugs such as Apotel were used to control analgesia after extubating. In addition to safe anesthesia, the patient was discharged from the ICU at an appropriate time when his general condition was favorable. The month after surgery was determined. Our patient referred to the heart clinic the following month, and his rate was found to be EF: 25 - 30%; however, his clinical symptoms such as shortness of breath and chest pain and FC had been significantly improved.
Some studies have indicated that this method is also effective for patients like our critical patient.
Mythen and Webb (
10) concluded that the intraoperative optimization of the cardiac output increased the splanchnic blood flow among their study population. Subsequently, McKendry et al. (
11) reported that a flow-directed hemodynamic algorithm after cardiac surgery in the I.C.U. reduced complications and the length of hospital stay. Goepfert et al. (
12) showed that early goal-directed hemodynamic therapy based on the cardiac index, SVV, improved global end-diastolic volume index and had the potential to reduce complications and the length of ICU stay after cardiac surgery.
The finding from those studies was consistent with our study result in terms of using PA catheter. It was concluded that using PA catheter with advanced monitoring and GDT-based fluid therapy guaranteed a safe anesthesia in patients with severe heart failure and EF < 20%. Moreover, postoperative complications and the number of patients admitted to the ICU were significantly reduced.