|Year : 2015 | Volume
| Issue : 1 | Page : 58-62
Perioperative prostate specific antigen levels among coronary artery bypass grafting patients: Does extracorporeal circulation and body temperature induce prostate specific antigen levels alterations?
Emmanuel Patris1, Konstantinos Giakoumidakis2, Vasileios Patris3, Manoj Kuduvalli3, Mihalis Argiriou4, Christos Charitos4, Christos Kalaitzis1, Stavros Touloupidis1
1 Department of Urology, School of Medicine, Democritus University of Thrace, Dragana, 68100 Alexandroupolis, Greece
2 Department of Cardiac Surgery, Cardiac Surgery ICU, "Evangelismos" General Hospital of Athens, Greece
3 Department of Cardiac Surgery, Heart and Chest Hospital, Thomas Drive, Liverpool L14 3 PE, United Kingdom
4 Department of Cardiac Surgery, "Evangelismos" General Hospital of Athens, 10646 Athens, Greece
|Date of Submission||20-Oct-2013|
|Date of Acceptance||10-Feb-2014|
|Date of Web Publication||6-Jan-2015|
Cardiac Surgery ICU, "Evangelismos" General Hospital of Athens, 45 47 Ipsilantou Street, 10646, Athens
| Abstract|| |
Purpose: The purpose of this study is to compare the perioperative total prostate specific antigen (tPSA) levels among coronary artery bypass grafting (CABG) patients with and without extracorporeal circulation (ECC), to investigate the changes overtime of tPSA in each group separately and to determine the effect of body core temperature on tPSA levels.
Materials and Methods: A prospective study was conducted. Our sample was allocated to: (a) Seven patients who underwent off pump CABG (Group I) and (b) 16 CABG patients with ECC (Group II). The levels of tPSA were measured preoperatively (baseline), intra-operatively and at the 4 th postoperative day. We compared the two groups on their tPSA levels and we investigated the changes of tPSA overtime in each group separately.
Results: Intra-operative serum samples were obtained in significantly lower body temperature in patients of Group II than in those of Group I (31°C vs. 36.9°C, P < 0.001). In each group separately , postoperative tPSA levels were increased significantly compared to the baseline values (2.55 ng/ml vs. 0.39 ng/ml for Group I, P = 0.005 and 4.36 ng/ml vs. 0.77 for Group II, P < 0.001). CABG patients with ECC had significantly lower intra-operative tPSA levels than the baseline values (0.67 ng/ml vs. 0.77 ng/ml, P = 0.008). We did not observe significant differences of tPSA levels between the two groups.
Conclusions: CABG surgery affects similarly the perioperative tPSA independently the involvement of ECC. Although all patients had significantly higher early postoperative tPSA levels, only those who underwent CABG with ECC had exceeded normal values and significantly decreased intra-operative tPSA. Hypothermia seems to be the causal factor of tPSA reduction.
Keywords: Cardiopulmonary bypass, coronary artery bypass, hypothermia, off-pump, prostate, prostate-specific antigen
|How to cite this article:|
Patris E, Giakoumidakis K, Patris V, Kuduvalli M, Argiriou M, Charitos C, Kalaitzis C, Touloupidis S. Perioperative prostate specific antigen levels among coronary artery bypass grafting patients: Does extracorporeal circulation and body temperature induce prostate specific antigen levels alterations?. Urol Ann 2015;7:58-62
|How to cite this URL:|
Patris E, Giakoumidakis K, Patris V, Kuduvalli M, Argiriou M, Charitos C, Kalaitzis C, Touloupidis S. Perioperative prostate specific antigen levels among coronary artery bypass grafting patients: Does extracorporeal circulation and body temperature induce prostate specific antigen levels alterations?. Urol Ann [serial online] 2015 [cited 2020 May 30];7:58-62. Available from: http://www.urologyannals.com/text.asp?2015/7/1/58/148619
| Introduction|| |
Prostate specific antigen (PSA) is a kallikrein-like serine protease, which is secreted by the epithelial cells of the prostate gland. Although the serum level of PSA is a widely used tumor marker of prostate cancer,  PSA is not a unique malignant indicator of the prostate gland. PSA may be elevated in some benign diseases of the prostate gland, such as hyperplasia, infections, prostate abscess and after manipulation, such as biopsy and transurethral resection of the prostate gland. 
In addition, PSA elevation has been associated with cardiac disorders and procedures and many authors have reported increased PSA levels after cardiopulmonary resuscitation,  acute myocardial infarction, [4-6] coronary artery stent implantation  and coronary artery bypass grafting (CABG) surgery. , Indeed, CABG involved extracorporeal circulation (ECC) seems to be strongly associated with increased postoperative PSA levels due to pelvic ischemia, which later is accompanied by prostate ischemia and prostatic epithelial cell damage. ,
The aim of this study was to compare the perioperative total prostate specific antigen (tPSA) levels among CABG patients with and without ECC, to investigate the overtime changes of tPSA in each group separately and to determine the effect of body core temperature on tPSA levels. Our study seeks to contribute to the limited body of knowledge regarding perioperative tPSA levels among CABG patients with and without ECC. In addition, this was the first study which attempted to examine the effects of core temperature on serum tPSA levels.
| Materials and methods|| |
Study design and participants
A prospective cohort study was conducted. A total of 23 consecutive male subjects who underwent CABG in one cardiothoracic center of a tertiary general hospital in Athens - Greece during April 2013 were enrolled in our study. Patients younger than 18 years old and those who had a history of malignancy of prostate or any other organ, previous pelvic and inguinal irradiation, open or transurethral surgery for benign prostatic hyperplasia and preoperative tPSA levels above 4 ng/ml (the upper normal limit) were excluded from the study. In addition, recent genitourinary track infection, acute and chronic prostatitis, any prior urological manipulations within 1 month, urolithiasis, previous cardiac surgery, taking medications affecting tPSA levels and traumatic urinary catheterization were among the other exclusion criteria.
The cohort was divided into two groups: (a) Seven patients who underwent CABG without ECC (Group I) and (b) 16 patients who underwent CABG with ECC (Group II).
Data collection - procedure
For data collection proposes we used a short structured questionnaire on basic demographic and clinical patient data. The questionnaire information included patients' age, a history of chronic obstructive pulmonary disease (COPD), diabetes mellitus, cancer and renal failure, previous cardiac surgery, current medications and an urological history, including a history of malignancy of prostate and any form of its treatment, previous pelvic and inguinal irradiation, open or transurethral surgery for benign prostatic hyperplasia, recent genitourinary track infection, acute and chronic prostatitis, prior urological manipulations within 1 month and urolithiasis.
In all patients shortly after general anesthesia was induced, an urologist placed a urinary 16 F Foley catheter (Foley two way silicone with thermistor ref 90051T Kendall Tyco/Healthcare). Serum samples of all patients were obtained preoperatively (baseline), intra-operatively (day 0) and postoperatively (day 4). Specifically, preoperative samples were taken at the morning of surgery, intra-operative samples were taken immediately after receiving the first bypass graft for the patients of the Group I and 15 min after reaching the temperature of 31°C, during the ECC, for the patients of the Group II. Postoperative sample were obtained during the 4 th postoperative day after urinary catheter removal. All serum tPSA were assayed at the Department of Biochemistry of our hospital using the chemiluminescent enzyme immunoassay method with reference range of 0-4 ng/ml. Intra-operative body core temperature was measured by the urinary catheter of each patient (urinary bladder temperature). It is well-known that urinary bladder temperature is among the most reliable and accurate methods of body core temperature measurement in critically ill patients. ,
The literature review reveals that an atraumatic urinary catheterization and general anesthesia are not associated with significant elevation in tPSA levels, , so we did not take into consideration these parameters. In addition, as mentioned above, the urinary catheters were removed on the 4 th postoperative day and none of the patients developed lower urinary tract symptoms. Aiming to ensure the reliability and validity of the data collection process, the samples were obtained by the same individual each time. In addition, the same individual took the demographic and clinical data based on the medical patient records review.
Continuous variables are presented as median (interquartile range [IR]), whereas categorical variables are presented as absolute and relative frequencies. The Chi-square test was used to compare the distribution of categorical variables between CABG patients without and with ECC and the Mann-Whitney test was used to compare continuous variables between the two groups. In addition, we used the Wilcoxon signed ranks test to compare the overtime changes of tPSA levels in each group separately. P <0.05 was considered to be statistically significant. Statistical analysis was performed using SPSS 19.0 for Windows (Armonk, NY: IBM Corporation).
The data collection was conducted after written permission from the ethics committee of the hospital. The investigation was carried out in accordance with the ethical standards of the responsible institutional committee for human experimentation and with the Helsinki declaration of 1975, as revised in 2008. Precautions took place to protect the privacy of research subjects and the confidentially of their personal information, including limiting the amount of personal information to the absolute minimum, assigning an identification number to each subject and attaching the identification number to the actual research information, removing the subject names as soon as data were analyzed and maintaining any identifying information and lists of identification numbers in a safe and locked file.
| Results|| |
The median age of patients who were undergone off pump CABG (Group I) and on pump CABG with cardiopulmonary bypass (Group II) was 66 (IR: 60-71) and 66.5 (IR: 59.5-73.75) years old respectively, a difference statistically not significant. As [Table 1] shows, the two groups were similar regarding the baseline patient characteristics (age, history of COPD, renal failure and diabetes mellitus). During obtaining serum samples to measure tPSA levels intra-operatively, core temperature was significantly lower in patients of the Group II compared with those in the Group I (31°C vs. 36.9°C, P < 0.001). In addition, hypothermia time for the patients of the Group II was depended on the number of grafts needed to be placed and ranged from 20 to 40 min (median 30 min).
|Table 1: Baseline demographic and clinical characteristics in each patient group|
Click here to view
The perioperative tPSA values for both groups are summarized in [Table 2]. Between the two groups we did not observe statistically significant differences at baseline and on days 0 and 4. Regarding the overtime changes in tPSA values for each group separately, we found a decrease in tPSA values intra-operatively (day 0) compared to preoperative (baseline) levels for patients of both groups, but only for the on pump CABG patients (Group II) this redaction was significant (P = 0.008). In addition, for both groups, tPSA levels were significantly higher postoperatively (day 4) compared with preoperative (P = 0.005 for Group I and P < 0.001 for Group II) and intra-operative levels (P = 0.005 for Group I and P < 0.001 for Group II). The overtime changes in tPSA levels in each patient group are also depicted at [Figure 1].
|Figure 1: Perioperative prostate specifi c antigen levels alterations in each patient group. Group I: Patients who underwent coronary artery bypass grafting without extracorporeal circulation, Group II: Patients who underwent coronary artery bypass grafting with extracorporeal circulation, PSA: Prostate specifi c antigen|
Click here to view
|Table 2: Perioperative PSA levels in each patient group and changes of PSA overtime in each patient group separately|
Click here to view
| Discussion|| |
Although we observed no significant differences of tPSA levels between the two groups at baseline and on days 0 and 4, our study indicated a significant increase of postoperative tPSA levels, in both groups, compared with the baseline and intra-operative levels. In addition, another important finding of the present study was the significantly lower tPSA levels intra-operatively in patients who underwent CABG with ECC compared with baseline values.
As aforementioned, we did not found significant differences on serum tPSA levels pre-, intra- and post-operatively when we compared the two groups. Contrary to our findings Parlaktas et al.  and Netto et al.  found significantly higher tPSA levels postoperatively in patients who underwent CABG with ECC compared with off pump patients and attributed these finding to the possible more pronounced ischemic damage of prostate tissue during ECC. It is known that CABG without ECC has been associated with a lower incidence of ischemia-reperfusion injury, lower postoperative complications of multiple organ dysfunction and reduced postoperative elevation of markers of systemic inflammatory response. ,[13-16] The different findings of our study could be explained by its small sample size.
The elevation of tPSA levels was not significantly higher in patients who underwent CABG with ECC when compared to off-pump patients. Nevertheless, we can claim that the higher tPSA levels on day 4 for patients of Group II have significance from a clinical point of view, given the presence of median tPSA levels above 4 ng/dl (the upper normal limit) in these patients. Considering this and in accordance with other authors ,, prostate cancer screening should be postponed or avoided in patients who underwent CABG with ECC during the early postoperative period and tPSA levels should not be as markers of prostate malignancy due to the raised tPSA levels of this period.
Another important finding of this study was the significant elevation of tPSA levels postoperatively in each patient group separately, a result that is in line with the study of Parlaktas et al.  In addition, Guvel et al.  and Coker et al.  investigating patients who underwent CABG with ECC found raised levels of tPSA postoperatively. In contrast, Netto et al.  have reported no serum tPSA rise in patients who underwent off pump cardiac surgery. It is well-known from the literature review that prostate ischemia during CABG is the causal factor for the elevated serum tPSA during the postoperative period. ,, Nevertheless, it is worth mentioning the significant postoperative increase of tPSA levels among the off pump CABG patients of our study. Although, the effect of ECC on tissue perfusion is arguably detrimental, cardiac surgery without ECC is also accompanied by hypotensive periods with hemodynamic instability, which lead to prostate hypoperfusion. This hypoperfusion may explain the elevated levels of tPSA postoperatively.
As aforementioned, we observed significantly lower levels of tPSA intra-operatively in CABG patients with ECC. This study is the first one which examined intra-operative tPSA levels alterations compared with the preoperative - baseline levels. Patients of Group II had a core temperature of 31°C during the intra-operative measurement of their tPSA levels, a temperature that was significantly lower compared with patients who underwent off pump CABG. It seems that core temperature induced tPSA alterations and hypothermia was associated with decreased levels of tPSA. Hypothermia implies slowing of cellular metabolism, given that for every 1°C drop in body temperature, cellular metabolism slows by 5-7%  and reduces the harmful effects of ischemia by decreasing the body's need for oxygen.  Consequently we could hypothesize that hypothermia is useful in preventing prostate tissue damage and in prostate cell protection  resulting on tPSA levels reduction during the hypothermic phase of CABG.
The present study is the first one which investigated the effect of body core temperature on tPSA levels in men who underwent CABG. In addition, is among the few studies which compared the perioperative tPSA levels in CABG patients with and without application of ECC. However, this study has some limitations. Firstly, the small sample size of our study and its selection by one cardiothoracic center limit the generalizability of the findings and potentially threaten the internal validity of the study. In addition, we did not observe tPSA levels for a longer than the 4 th postoperative day period and consequently we were unable to determine when these levels return to normal values postoperatively.
| Conclusions|| |
CABG surgery seems to affect similarly the perioperative tPSA levels independently the application of ECC. Although, the patients of both groups had significantly higher early postoperative tPSA levels compared with the baseline (preoperative) levels, only those who underwent CABG with ECC had exceeded normal values. In addition, these patients had significantly decreased intra-operative tPSA levels. It seems that hypothermia is the causal factor of this reduction due to the lower metabolic needs of prostate tissue, which prevent the hypoperfusion induced prostate cell damage. Further research, emphasizing in the effect of both hypothermia and ECC on tPSA levels, is needed to address the perioperative alterations of tPSA levels and the role of body core temperature on them.
| References|| |
Hagood PG, Parra RO, Rauscher JA. Nontraumatic elevation of prostate specific antigen following cardiac surgery and extracorporeal cardiopulmonary bypass. J Urol 1994;152:2043-5.
Parlaktas BS, Naseri E, Uluocak N, Elalmis AO, Erdemir F, Etikan I. Comparison of the effects of on-pump versus off-pump coronary artery bypass surgery on serum prostate-specific antigen levels. Int J Urol 2006;13:234-7.
Koller-Strametz J, Fritzer M, Gwechenberger M, Geppert A, Heinz G, Haumer M, et al
. Elevation of prostate-specific markers after cardiopulmonary resuscitation. Circulation 2000;102:290-3.
Patanè S, Marte F. Prostate-specific antigen and acute myocardial infarction: A possible new intriguing scenario. Int J Cardiol 2009;134:e147-9.
Patanè S, Marte F, Sturiale M, Dattilo G. ST-segment elevation and diminution of prostate-specific antigen in a patient with coronary spasm and without significant coronary stenoses. Int J Cardiol 2011;148:e31-3.
Açýkgöz Þ, Can M, Doðan SM, Mungan G, Aydýn M, Kelek S, et al
. Prostate specific antigen levels after acute myocardial infarction. Acta Biochim Pol 2011;58:541-5.
Ozcan T, Bozlu M, Muslu N, Gozukara KH, Seyis S, Akcay B. Elevation of the serum total and free prostate specific antigen levels after stent implantation in patients with coronary artery disease. Swiss Med Wkly 2009;139:672-5.
Netto NR Jr, Lima ML, Guedes MA, Patino LL, de Oliveira JB. Elevation of prostate specific antigen in cardiac surgery with extracorporeal cardiopulmonary circulation. J Urol 1998;159:875-7.
Fallis WM. Monitoring urinary bladder temperature in the intensive care unit: State of the science. Am J Crit Care 2002;11:38-45;47.
Lefrant JY, Muller L, de La Coussaye JE, Benbabaali M, Lebris C, Zeitoun N, et al
. Temperature measurement in intensive care patients: Comparison of urinary bladder, oesophageal, rectal, axillary, and inguinal methods versus pulmonary artery core method. Intensive Care Med 2003;29:414-8.
Erdogan K, Gurdal M, Tekin A, Kirecci S, Sengor F. The effect of urethral catheterisation on serum prostate-specific antigen levels in male patients with acute urinary retention. Yonsei Med J 2003;44:676-8.
Erdem E, Doruk E, Tunçkiran A, Bilgin E, Ulusoy E, Akbay E. General anesthesia does not affect the serum complexed and free prostate specific antigen levels. Swiss Med Wkly 2004;134:406-9.
Mishra M, Malhotra R, Mishra A, Meharwal ZS, Trehan N. Hemodynamic changes during displacement of the beating heart using epicardial stabilization for off-pump coronary artery bypass graft surgery. J Cardiothorac Vasc Anesth 2002;16:685-90.
Boening A, Friedrich C, Hedderich J, Schoettler J, Fraund S, Cremer JT. Early and medium-term results after on-pump and off-pump coronary artery surgery: A propensity score analysis. Ann Thorac Surg 2003;76:2000-6.
Khan NE, De Souza A, Mister R, Flather M, Clague J, Davies S, et al
. A randomized comparison of off-pump and on-pump multivessel coronary-artery bypass surgery. N Engl J Med 2004;350:21-8.
Murphy GJ, Angelini GD. Side effects of cardiopulmonary bypass: What is the reality? J Card Surg 2004;19:481-8.
Guvel S, Turkoz R, Egilmez T, Kilinc F, Yaycioglu O, Atalay H, et al
. Does ischemia-induced prostate damage during cardiac surgery involving cardiopulmonary bypass cause bladder outlet obstruction? Urol Int 2005;74:337-40.
Coker C, Sherwood RA, Crayford T, Saadeh F, Mulvin D, Brakenbury E, et al
. Ischemic damage to the prostate during cardiac surgery: A clinical model. Prostate 1997;32:85-8.
Kammersgaard LP, Jørgensen HS, Rungby JA, Reith J, Nakayama H, Weber UJ, et al
. Admission body temperature predicts long-term mortality after acute stroke: The Copenhagen Stroke Study. Stroke 2002;33:1759-62.
Hildebrand F, Giannoudis PV, van Griensven M, Chawda M, Pape HC. Pathophysiologic changes and effects of hypothermia on outcome in elective surgery and trauma patients. Am J Surg 2004;187:363-71.
Alva N, Azuara D, Palomeque J, Carbonell T. Deep hypothermia protects against acute hypoxia in vivo
in rats: A mechanism related to the attenuation of oxidative stress. Exp Physiol 2013;98:1115-24.
[Table 1], [Table 2]