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Kardiochirurgia i Torakochirurgia Polska/Polish Journal of Thoracic and Cardiovascular Surgery
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Perioperative care in elderly cardiac surgery patients

Ewa Kucewicz-Czech, Katarzyna Kiecak, Ewa Urbańska, Tomasz Maciejewski, Robert Kaliś, Waldemar Pakosiewicz, Tadeusz Kołodziej, Piotr Knapik, Roman Przybylski, Marian Zembala

Kardiochirurgia i Torakochirurgia Polska 2016; 13 (4): 340-346
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- Perioperative care.pdf  [0.17 MB]


Chronological and biological age differ significantly from each other. Chronological age is the parameter used in clinical practice. It has been widely accepted to divide the elderly subjects into four age categories: young-old age (65–74 years), middle-old age (75–84 years), oldest-old age (≥ 85 years), and longevity (≥ 90 years). No age is a contraindication for surgery if the clinical aim is not only to prolong life. The most important motivation for treatment is the preservation or improvement of the quality of life.
The philosophy of surgical treatment in seniors focuses on the rapid restoration of all physiological functions immediately after the procedure, which reduces the complication rates and the duration of hospital stay [1].
The occurrence of postoperative complications leads to a cascade of events resulting in disability, dependence, reduced quality of life, increased mortality, and a dramatic increase in treatment costs [2].
Seniors are characterized by different physiology, which justifies the individualization of the treatment process. One typical feature is reduced – hepatic perfusion, which leads to impaired drug metabolism. Furthermore, the number of drug-binding receptors is reduced, and the response to medications is thus delayed. Renal dysfunction extends the duration of drug elimination. Due to low albumin levels, the free drug fraction is increased, resulting in increased drug transport to the central nervous system (CNS). The volume of distribution is reduced due to the reduction of circulating blood volume by 20%, which is associated with higher drug levels. Seniors are also more susceptible to medications as a result of increased concentrations of water-soluble drugs (due to lower water content) and reduced concentrations of fat-soluble drugs (due to increased sequestration of anesthetics in the adipose tissue and later their extended release) [3]. Diastolic dysfunction is a typical feature of the aging heart [4].
The effect of general anesthesia on the brain is an increasingly debated issue. The hypothesis that general anesthesia contributes to the progression of neurodegeneration has not been confirmed. However, some studies indicate that excessively deep anesthesia may affect the rate of cognitive dysfunction and postoperative delirium. In addition, increasing evidence suggests that cognitive dysfunction is aggravated by the inflammatory process induced by anesthesia and surgery [5–7].
There is no single ideal method of providing anesthesia to this patient group. An optimal approach seems to consist in multimodal anesthesia with short-acting opioids, propofol, an inhaled anesthetic, and a myorelaxant that does not release histamine [8].


The aim of the study was to evaluate perioperative complications in patients aged ≥ 75 years who underwent cardiac surgery in comparison to outcomes in younger patients operated on during the same period.

Material and methods

We evaluated patients ≥ 75 years of age who underwent cardiac surgery at the Silesian Centre for Heart Diseases in Zabrze from the implementation of a standard of perioperative care in this age group in October 2009 until October 2014. The study group included 1446 patients. We excluded patients with acute aortic dissection who were subjected to emergency surgery. Patients ≥ 75 years of age were compared with patients below 75 years of age operated on during the same period (6913 patients).
The risk of renal, respiratory, and cardiac failure [9, 10] was evaluated during preoperative anesthesiology consultations.
For premedication, the seniors received melatonin (5 mg orally) on the evening before the surgery and another dose 1 h before being transferred to the operating theatre. In the study group, the induction of anesthesia was obtained with intravenous etomidate (0.2–0.3 mg/kg), sufentanil 50–100 µg (0.5–1 µg/kg), and rocuronium (1 mg/kg). In patients with hypotension, ketamine (1–2 mg/kg) was used instead of propofol. Anesthesia was maintained using continuous infusion of propofol (100–200 mg/h) and sufentanil (0.3–1 µg/kg/h) along with fractionated doses of rocuronium (0.1 mg/kg). Inhaled sevoflurane was also used at the same time, and was also administered during cardiopulmonary bypass (CPB).
Hemodynamic monitoring included ECG as well as direct blood pressure and central venous pressure measurements. Swan-Ganz catheters were placed in patients with low left ventricular ejection fraction (LVEF < 30%) or pulmonary hypertension and in patients undergoing complex procedures. We recorded deep body temperature and monitored urine output. We continuously monitored oxygen saturation and frequently measured arterial blood gases with lactate levels during the anesthesia. Mixed venous blood gases were measured if hemodynamic instability occurred. In patients with generalized atherosclerosis, carotid artery stenosis, or a history of stroke, we monitored regional CNS oxygen saturation with near-infrared spectroscopy (NIRS), which is the current standard [11]. An important aspect of management was to maintain normothermia both during the surgery and in the postoperative period. We also established the acceptable level ranges for blood glucose (6.5–8.5 mmol/l) and hemoglobin (≥ 5 mmol/l). Fluid balance was strictly monitored, and blood loss was replaced with colloid fluids. We maximally restricted the filling of the CPB circuit. During the initial phase of CPB, the patients received 250 mg of methylprednisolone. During CPB, the mean arterial pressure was kept at 70 mm Hg, and cardiac output was maintained at ≥ 2.4 l/m2. A lung-sparing ventilation strategy was used (tidal volume 6 ml/kg, positive end-expiratory pressure ≥ 5 cm H2O, FiO2 50%). Pharmacological and mechanical support of cardiovascular function was provided in accordance with the principles of goal-oriented therapy. The goal was defined as a normal lactate level and normal venous blood oxygen saturation, and, in patients monitored using a Swan-Ganz catheter, the goal was to achieve a cardiac index of at least 2.4 l/m2.
Analgesia was used from admission to the stay in the postoperative unit (morphine in fractionated doses, fixed doses of paracetamol). Antiemetic therapy included dexamethasone and ondansetron. The oxygen level in inspired air was adjusted based on transcutaneous oxygen saturation monitoring. For mechanical ventilation, the SIMV mode was initially used, followed by the bilevel or a proportional mode and, finally, continuous positive airway pressure (CPAP) with pressure support. The intubation tube was removed when the extubation criteria were met. Respiratory rehabilitation and patient mobilization strategies were initiated immediately after extubation. Patients received oral fluids two hours after extubation, and enteral feeding was initiated several hours later. Fluid balance was planned individually.
In younger patients, the approach to anesthesia and early postoperative treatment was decided by the anesthesiologist in charge of anesthesia and the physician on duty in the postoperative unit.
Patients aged ≥ 75 years were characterized by lower body mass index values, higher risk scores (EuroSCORE I), higher Canadian Cardiovascular Society (CCS) and New York Heart Association (NYHA) classes, and longer durations of hospital stay in comparison to younger patients (Tab. I). Among the seniors, there were more women, patients in NYHA class 3 or 4, patients with an unstable course of ischemic heart disease, left main coronary artery disease, diabetes, hypertension, preoperative renal failure, pulmonary disease, and carotid artery disease (Tab. II).
A comparison of procedures performed in both patient groups is presented in Table III.

Statistical analysis

Data were collected and initially evaluated in a spreadsheet. Verified data were transferred to the statistical software which was used for the proper analysis. Normal distribution of quantitative variables was checked using the Shapiro-Wilk test, while the non-parametric Mann-Whitney U test was used for non-normal variable distribution. For qualitative variables, a two-sided 2 test with the Yates correction was used. The results are presented in tables showing mean values and standard deviations for quantitative variables and numbers with percentages for qualitative variables. P < 0.05 was considered statistically significant. Statistical analysis was performed using the Statistica data analysis software system, version 10.1 (StatSoft, Inc.).


Table IV shows early postoperative complications in both study groups. Mediastinal revision was more common in older patients, as was low cardiac output syndrome requiring high catecholamine doses and mechanical support with an intra-aortic balloon. Other complications were also more frequently diagnosed in older patients, including pulmonary complications, acute renal failure (defined as serum creatinine level ≥ 200 µmol/l), type I neurological complications, and abdominal organ dysfunction (intestinal ischemia/necrosis, acute cholecystitis, acute pancreatitis, gastrointestinal bleeding). Atrial fibrillation and delirium were more common in older patients. Transfusion of more than 4 units of packed red blood cells was also more frequent in this group. The overall complication rate was higher in older patients (17.8%), and in-hospital mortality in this group was 3.8%.
The rate of prolonged mechanical ventilation, defined as patient dependence on the ventilator lasting more than 48 h, was the same in both groups (Tab. V). Gender and preoperative factors had no effect on the duration of mechanical ventilation (Tab. VI).
The mean duration of mechanical ventilation in our patients ≥ 75 years of age was shorter by more than 10 h compared to the mean value in a similar group of patients analyzed in 2003–2008 (Tab. VII).
The rate of postoperative delirium in patients ≥ 75 years of age operated on due to cardiac disease in 2003–2008 was 15.7%, i.e., nearly twice as high as in the present study group (Tab. VII).


The implementation of the Early Recovery After Surgery (ERAS) approach, used in general surgical, orthopedic, and other surgical units, has introduced some unrest into the monotonous standard of perioperative care in patients undergoing cardiac surgery. The idea was born and developed in Scandinavia, from where it later emanated to other parts of the world [12]. It seems that this philosophy of perioperative care may have an effect on the reduction of complication rates in all areas of surgery. This is even more likely due to the current trend to operate on older and older patients who tend to stay for a longer time in the postoperative unit, which results in postoperative delirium and increased severity of dementia, ultimately annihilating much of the initial effect of the surgery.
Years ago, some emotions in cardiac surgery were generated by the fast-track standard, but ultimately it focused on early extubation in low-risk patients.
The aging of society is a problem in developed and developing countries [13]. Patients referred for cardiac surgery also tend to be increasingly old. Frailty is a feature of the multidimensional syndrome associated with aging, characterized by a loss of physiological reserve and deficit accumulation [14]. As a result, these patients are helpless when trauma occurs.
In the present study, patients aged 75 years and above constituted 21% of the overall population undergoing surgery. For premedication, we used melatonin, which, according to various authors, restores the normal sleep and wake cycle, thus contributing to a reduction in the rate of delirium. This therapy was continued in the early postoperative period [15]. We avoided benzodiazepine use throughout the perioperative period. Statin treatment was not discontinued before the surgery, and statins were initiated in patients who had not previously received these drugs [16].
Short-acting drugs were used for multimodal, intravenous, and inhaled anesthesia. We also used sevoflurane, which is well known for its preconditioning properties.
Hemodynamic monitoring was performed according to the accepted standard, which was not modified in the evaluated age group. In the case of low cardiac output syndrome after the surgery, monitoring was supplemented with cardiac output measurements using the thermodilution method. Venous blood oxygen saturation and the lactate level were measured in order to enable early detection of impending hemodynamic destabilization. When treating heart failure, we were fully aware of a high likelihood of concomitant left ventricular diastolic dysfunction, which is characteristic for the evaluated age group. The treatment of choice for this type of heart failure is the administration of milrinone combined with norepinephrine. Fluid therapy in patients with diastolic heart failure is a real challenge. Adequate cardiac filling requires higher pressures, but the stiff myocardium is characterized by low end-diastolic volume. Low cardiac output syndrome is defined as the need to use two catecholamines in doses above 10 µg/kg/min each or epinephrine in a dose above 0.1 µg/kg/min or as a cardiac index below 2 l/min/m2 in two consecutive measurements. Such a condition was observed in 40% of the seniors undergoing surgery. Mechanical cardiac support was used in 5% of patients aged 75 years and above.
Modern sedation facilitates patient cooperation with the medical personnel, as it provides comfort, while allowing patients to communicate their needs. In order to achieve this condition, effective analgesia should be provided, nausea and vomiting should be avoided, and the ventilator’s operation should be synchronized with the patient’s spontaneous breathing. All patients who required deeper sedation and were ventilated for more than 24 h were evaluated daily to determine their readiness to be weaned from mechanical ventilation [17]. Despite many concomitant conditions and risks present in our seniors, the duration of postoperative mechanical ventilation did not differ between the groups. The only modifiable factor that affects the duration of postoperative mechanical ventilation is cardiopulmonary bypass, particularly its duration. Our results are consistent with often presented data indicating benefits of avoiding CPB in high-risk patients [18]. When evaluating the duration of mechanical ventilation in two different periods (2003–2008 versus 2009–2014), one should take into account the advances in surgical techniques, the increasing surgeon experience, and the introduction of protective mechanical ventilation. It seems, however, that the observed significant reduction in the duration of mechanical ventilation is also associated with the implementation of a standard of perioperative care for seniors.
Acute renal failure was treated in accordance with the standard approach introduced many years ago [19]. For more than 5 years, renal replacement therapy in the early postoperative period has been conducted under local anticoagulation using citrate [20].
An issue of ongoing debate in the medical literature is the optimal hemoglobin level during the perioperative period in elderly patients. On the one hand, every transfused unit of packed red blood cells is associated with an increase in mortality risk; on the other hand, anemia can cause acute postoperative renal failure, strokes, and respiratory failure [21]. In our study, indications for packed red blood cell transfusions were individualized, taking into account factors other than the hemoglobin level. The need for transfusion was considered in the context of the lactate level, venous blood oxygen saturation, and, in the perioperative period, also patient participation in rehabilitation. Despite the restrictive indications for transfusion, the need to use more than 4 units of packed red blood cells occurred in 22.55% of seniors and was significantly more frequent than in the case of younger patients.
Early postoperative delirium is associated with an increased risk of complications, prolonged duration of hospital stay, and increased mortality [22]. In our seniors, delirium was more than twice as frequent as in our younger patients. However, we were able to reduce the rate of delirium in comparison to the period before the implementation of the standard of perioperative care in seniors in 2009. In 2003–2008, postoperative delirium was observed in 15.7% of patients aged ≥ 75 years, as compared to 8% of patients at a similar age in the present study group.


Patients aged ≥ 75 years who undergo cardiac surgery have significantly more concomitant conditions involving other organs, which affects treatment outcomes (duration of hospital stay, mortality). The implementation of a standard of perioperative care in this age group reduced the duration of mechanical ventilation and lowered the rate of postoperative delirium.


Authors report no conflict of interest.


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Copyright: © 2016 Polish Society of Cardiothoracic Surgeons (Polskie Towarzystwo KardioTorakochirurgów) and the editors of the Polish Journal of Cardio-Thoracic Surgery (Kardiochirurgia i Torakochirurgia Polska). This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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