J Cerebrovasc Endovasc Neurosurg > Volume 17(3); 2015 > Article
Choi, Yoon, Yoo, Park, Kim, and Kim: Necessity of Surgical Site Closed Suction Drain for Pterional Craniotomy

Abstract

Objective

The aim of this study was to assess the benefit of using a prophylactic surgical site closed suction drain in pterional craniotomy.

Materials and Methods

A retrospective review was conducted on 607 consecutive patients who underwent a pterional craniotomy for treatment of intracranial anterior circulation aneurysms over a 5-year period. Between January 2000 and December 2004, 607 patients were divided into two groups, those who had a prophylactic suction drain during closure of the surgical site (drain group, DG) and those who did not (non-drain group, NDG). Head computed tomography (CT) was taken routinely on postoperative day (POD) 1, 7, and 14. Patients' demographics, incidence of surgical site complications, and courses of surgical site healing which were evaluated radiologically by the thickness of the surgical site myocutaneous layer, were analyzed between DG and NDG.

Results

Patients' demographics and characteristics did not differ significantly between the two groups. The head CT showed that the degree of changes in the postoperative surgical site thickness was 148% at POD 1, 209% at POD 7, and 198% at POD 14 in DG, and 118% at POD 1, 152% at POD 7, and 158% at POD 14 in NDG compared to the preoperative value. Postoperative surgical site hematoma was 7.9% (22/274) in DG and 2.4% (8/333) in NDG.

Conclusion

Prophylactic use of an epidural and/or subgaleal closed suction drain does not appear to be necessary for prevention of postoperative surgical site hematoma as well as for promotion of surgical site healing in pterional craniotomy.

INTRODUCTION

After Hippocrates and recently, the introduction of a portable closed suction drain by Redon and Jost in 1954, the surgical drain has been forever changed in its form and utility.20)21) Several retrospective and prospective studies spanning various surgical disciplines have examined the efficacy and complications associated with prophylactic closed suction drainage and have yielded inconsistent results as to whether or not it reduces the number of postoperative surgical site complications.1)2)3)5)15)16)21)26) In addition, there is increasing evidence that routine placement of a prophylactic closed suction drain does not decrease the rate of postoperative surgical site complications after various surgical procedures.2)3)5)6)14)15)16)21)
The necessity or utility of surgical site drains in a craniotomy is also controversial. Anecdotally, some neurosurgeons drain all craniotomy sites, while others do not. Epidural or subgaleal drains are commonly placed and connected to a closed vacuum system at the end of the craniotomy to prevent accumulation of intracranial and extracranial blood, and to promote healing of the surgical site. Paradoxically, the use of drains in a craniotomy may potentially increase the incidence of surgical site complications. However, few studies have reported on the necessity or advantage of surgical site drainage in craniotomy. Our sporadic and anecdotal experiences on surgical site complications in recent years have shown that a craniotomy without a surgical site drain had at least equal or better outcomes in terms of surgical site healing and complications, which encouraged us to conduct this study. One of the authors (CWP) had never used a routine surgical site drain for a pterional craniotomy since 2003. In this retrospective study, we compared the result of surgical site complications and healing processes in pterional craniotomy between a surgical site drain group (DG) and non-drain group (NDG) before and after 2003.

MATERIALS AND METHODS

Patient selection

From January 2000 to December 2004, a total of 652 pterional craniotomies were performed in 645 patients due to ruptured anterior circulation cerebral aneurysms by one of the surgeons who is part of this team of researchers (CWP). Of the 652 craniotomies, 45 cases (38 patients) involving patients who died before postoperative day 14, patients who had undergone a decompressive craniectomy, patients with a medical condition or on drug therapy likely influenced blood coagulation or immunosuppression, or the patient's data were incomplete were excluded. Patients were divided into 2 groups based on the use of a surgical site closed suction drain during closure of pterional craniotomy, the drain-group (DG) and the non-drain group (NDG). Patients' data including medical records and imaging study results were reviewed and analyzed in detail.

Operative methods and wound management

All pterional craniotomies were performed in the operating room using a laminar air flow system, as described by Yasargil et al.28) A compressive stocking was applied to every patient to prevent development of deep vein thrombosis, however subcutaneous heparin was not administered. Prophylactic antibiotics were administered to all patients: first generation cephalosporin (2 gm), was administered intravenously at the induction of general anesthesia followed by 1 gm every 8 hours for 3 days postoperatively. To prepare the scalp for incision, the whole scalp of each patient was shaved, prepared by iodine derivatives, and the surgical site was covered with antimicrobial film. At the end of the craniotomy, a drain was placed between the bone flap and the temporalis muscle flap in the DG group, then brought out through a separate stab incision and attached to the commercially available closed suction drain system (3.2 mm in outer diameter, round and transparent polyvinyl chloride tube with a 400 mL spring evacuator chamber; Hemovac, Zimmer, UK). After satisfactory hemostasis was achieved and layer by layer closure performed, a light adhesive dressing was applied. Other than the use of a drain, the surgical sites for patients of both groups (DG and NDG) were closed in exactly the same manner using identical suture materials.
The surgical site and dressing was inspected daily in all patients. The closed suction drain system was emptied every 8 hours and the amount was measured in the DG. The drain was removed under sterile conditions, when the volume of drainage was less than 50 mL during the last 24 hours. Most drains were removed within 48 hours after insertion. During removal, the tip of the drain was cut off approximately 2 cm from the end, placed in culture medium and sent to the clinical laboratory. A culture was taken to identify the presence of any microorganisms, which were then reported using standard laboratory techniques.

Evaluation of wound healing process

Computed tomography (CT) was checked routinely on postoperative day (POD) 1, 7, and 14 in all patients for early detection of clinically silent lesions and development of complications such as intra- and extra-axial hematoma, hydrocephalus, and cerebral infarction. To assess healing of the surgical site without bias, two of the authors who were blinded to the patients' grouping measured the thickness of the myocutaneous layer (in mm) from the surface of the skull to that of the scalp on the surgical site at or above the level of the zygomatic arch on the postoperative serial head CT slices using calipers. The results from the two neurosurgeons were then averaged. The thickest myocutaneous layer slice on each postoperative head CT was selected, and that value was compared with the corresponding preoperative head CT slice. The postoperative thickness of the myocutaneous layer was expressed as a % of the preoperative value (Fig. 1).

Extra-axial blood collection

In this study, a postoperative surgical site epidural hematoma was defined as extra-axial blood collection over 5 mm in maximum thickness underneath the pterional bone flap on head CT scan. The maximum thickness of hematoma was classified as small, medium, and large if less than 1 cm, between 1 and 2 cm, and more than 2 cm, respectively. However, extra-axial blood collection less than 0.5 cm in thickness was regarded as within the normal limit of postoperative changes.

Surgical site infection

A positive result in the culture of the drain tip without clinical findings of a surgical site infection in the DG was not considered a surgical site infection. The criteria for infection were limited to purulent or serous discharge from the surgical site with the clinical signs of inflammation including local heat, erythema, increasing tenderness, and swelling. Wound dehiscence was defined as spontaneous or iatrogenic separation of sutured edges requiring drainage of a small amount of serous discharge or pus.

Statistical analysis

Statistical analyses were performed using SPSS version 10.0 (SPSS Inc., Chicago, IL, USA). Values of continuous variables were presented as mean with standard deviation and categorical variables as counts with percentages. The Pearson chi-square test and Student's T test were used to compare the frequency distribution of categorical or continuous variables between DG and NDG. A p value of < 0.05 was considered statistically significant.

RESULTS

A total of 607 patients (607 craniotomies) who underwent pterional craniotomy for clipping of ruptured cerebral aneurysms were enrolled int this study. DG included 274 patients; 126 patients were male, and the male to female ratio was 1:1.17. The mean age was 49.2 (range, 26.0-75.0) years. NDG included 333 patients; 157 patients were male, and the male to female ratio was 1:1.2. The mean age was 51.5 (range, 25.0-76.0) years. There was no significant difference in the patients' basic demographics and clinical characteristics that might affect surgical site complications between DG and NDG (p > 0.05) (Table 1).

Surgical site healing process

In the DG, postoperative thickness of the myocutaneous layer was measured as 148% at POD 1, 209% at POD 7, and 198% at POD 14. In the NDG, the results were 118% at POD 1, 152% at POD 7, and 158% at POD 14. In the NDG, the rate of increase in thickness was less remarkable compared with DG, particularly at POD 7, and these differences were statistically significant (p < 0.05) (Table 2).

Extra-axial blood collection

None of the patients in either group had a comorbidity related to blood coagulation disorders, which could influence the extra-axial blood collection. Based on our definition described in the Materials and method section, 22 (7.8%) of the 274 patients in the DG developed epidural hematomas; they were small in 10 patients, medium in nine, and large in three, while 8 (2.4%) of 333 patients in the NDG group presented with epidural hematomas.
They were small in size in six patients, and one was medium and the other was large. Statistically significant difference in the incidence of postoperative epidural hematoma was observed between the two groups (p < 0.05) (Table 3). All but two epidural hematomas were managed conservatively. Surgical evacuation was required for one epidural hematoma in the DG and one in the NDG.

Surgical site infection

None of the patients in either group had a comorbid condition increasing the risk of surgical site infection, such as immunodeficiency and/or suppression and uncontrolled diabetes mellitus (DM). A total of 102 patients in both groups had a medical history of type II DM (50 patients [18.2%] in the DG and 52 patients [15.6%] in the NDG), but during the perioperative period all patients' blood sugar levels were adequately controlled without any clinically evident complications and/or sequelae from diabetes. Three (0.4%) of 607 patients showed signs of a surgical site infection throughout their hospital stay. In the DG, two (0.7%, 2/274) patients showed signs of a surgical site infection. Despite meticulous wound care, one of them required surgical wound debridement. In the NDG, only one (0.3%, 1/333) patient presented with a superficial infection which was resolved by antibiotics and intensive surgical wound management without surgery. No statistically significant difference in the rate of surgical site infections was observed between the two groups (p > 0.05) (Table 3).

DISCUSSION

An extensive review of the literature was performed in an attempt to define and compare the surgical site healing process and the incidence of surgical site complications with or without use of a closed suction drain in various surgical procedures. However, few studies have reported on the surgical site healing process and complications including infection related to the use or non-use of a closed suction drain during craniotomy, thus the necessity or advantages of using a closed suction drain for a craniotomy remained elusive. Accordingly, we decided that it was necessary to conduct a comparative study between two patient populations, DG and NDG, who have undergone pterional craniotomies. To the best of the authors' knowledge, this is the first report in English to determine the necessity of a surgical site closed suction drain for pterional craniotomy.
Results of this study concerning the rate of hematoma formation and healing process at the surgical site might seem to contradict what was initially hypothesized, particularly in that the DG would have a lower incidence of hematoma formation at the surgical site and would heal better than the NDG. Although the use of a drain in a variety of surgical wounds has a long history, it very often falls into the realm of the surgeons' habit, rather than based in science or evidence-based medicine in surgical practice. The utility of a prophylactic closed suction drain in surgical sites may be questionable in craniotomies, however, neurosurgeons have routinely used surgical drains to avoid surgical site hematomas and seromas, and/or to promote faster surgical site healing.
In a general surgery report, suction drains greatly improved the apposition of a large skin flap to surgical wounds to the underlying raw tissue surface while obliterating surgically created dead spaces, draining their exudates, and promoting rapid adherence and healing of the surgical sites.1) Waugh and Stinchfield, who published the first article describing the use of a closed suction drain in a prospective controlled survey examining orthopedic surgical wounds, reported that complete hemostasis was very difficult, and the use of a suction drain could improve surgical wound healing through reducing the formation of a hematoma in the dead space. They reported a 1% incidence of surgical site infections in patients with a closed drain system versus 3% in matched cases without a drain26). While this result did not reach statistical significance due to the sample size, the potential to decrease the surgical site infection rate with a prophylactic suction drain was deemed encouraging. An orthopedic surgeon also reported on the use of a suction drain that could reduce pain and edema at surgical sites in the postoperative period, promote surgical site healing, and decrease infection risk26). Royster reported that a suction drain was specifically helpful after head and neck procedures in which the incidence of seroma and hematoma formation was higher in non-drained surgical wounds.
In contrast, other investigators have found that the insertion of a drain at the end stage of surgery, particularly in orthopedic surgery, did not significantly affect the incidence of surgical site complications. Browett et al.,3) who studied the use of drains in orthopedic surgery, found them to be of no use. Cobb, who evaluated the use of surgical site drain tubes in hip fracture patients, concluded that their use was rather detrimental.5) In 1998, Kim et al.15) reported that there was no benefit in placement of drains in orthopedic surgical wounds and found that placement of drains required more frequent surgical wound care due to oozing from the surgical site, which resulted in broad petechiae. In vascular, general, and orthopedic surgeries, the results of prospective randomized trials did not show any benefit with regard to use of surgical wound drains.2)9)12)16)21) In a large prospective study of 23,949 general surgical wounds, 14,243 clean wounds without drains had a lower infection rate than 2,503 clean wounds with drains.6) Esler et al.,10) in a prospective, randomized study, reported no significant difference between closed suction drain and non-drain groups in postoperative surgical site swelling, petechiae, and fever occurrence. Guangming et al.11) also reported that an epidural drain did not prevent formation of epidural hematomas and subgaleal CSF collection after supratentorial craniotomy, and Walid et al.25) reported no increased risk of wound infection in patients who had a drain, whereas some reported its impact on the prevalence of postoperative fever.
In literature review, the main reason for use of a drain is the surgeon's fear of hematoma formation at the surgical site, and it has been a general belief that by reducing the formation of a hematoma, surgical site healing would be improved. Objective assessment of the surgical wound healing process is difficult and this would be one of the most complicated causes, making it difficult to prove the effect of a surgical wound drain. To date, there has been no defined method and/or generally accepted guideline for the objective and quantitative assessment of surgical wound healing in the English literature, particularly in neurosurgery. We measured the thickness of the myocutaneous layer (in mm) from the surface of the skull to that of the scalp at the surgical site as an objective and quantitative indicator of surgical wound healing. The authors hypothesized that because there is always surgical site swelling due to the accumulation of exudates in the pterional craniotomy scalp flap, changes in the thickness of the myocutaneous layer might be a good indicator for the objective and quantitative assessment of surgical wound healing. In the current study, quantitative assessment of surgical site healing evaluated by the changes in the thickness of the myocutaneous layer during pterional craniotomy tells us that the healing process in the NDG is significantly superior to that of the DG.
Insertion of a closed suction drain into the space beneath the bone flap and/or subgaleal layer in craniotomies, including the pterional approach, is a common clinical practice among neurosurgeons. We placed a closed suction drain within the subgaleal space in the DG. This study also measured collection of the size of the hematoma in the epidural space, and compared DG to NDG. The result was also significantly superior in the NDG. Although the exact reasons remain unclear, the authors assume that the major mechanism for our result is the negative pressure by the closed suction drain. Negative pressure created within a closed suction drain system causes oozing from the myocutaneous flap, which in turn can aggravate myocutaneous layer swelling and epidural blood collection. Another reason for our results is the authors presume there might be more attention to the hemostasis in NDG during closure of the operative site.
Evidence in the literature has demonstrated that it is not the surgical wound hematoma itself, but the inoculation of cutaneous bacteria that increases the postoperative morbidity and even mortality associated with surgical site drains. Magee, a general surgeon, showed how surgical wound drains caused a clinical infection with what would be a subinfective dose of bacteria if no foreign body such as a surgical drain might be present.17) In 1969, Jepsen et al.,14) a general surgeon and his team of researchers, who reported increased sepsis in drained surgical wounds, suggested that their result could be attributed to the foreign body effect of surgical drains, creating a direct route of infection into the surgical site by a drain, the decreased inoculum requirements with drains, and the condition of the surgical wound during surgery which necessitated use of a surgical drain. Stevens published the results of a study comparing wound complications among orthopedic procedures.22) The foreign body effect and decreased host immune response with surgical drains were of concern in his report.22) This is particularly evident when considering studies with surgical wound cultures positive for organisms before closure. Overgaard et al. reported that 4 of 81 orthopedic surgical wounds had positive cultures before closure, along with five closed suction drain tips and six tracks that tested positive for organisms.19) The incidence of positive surgical site cultures increases steadily the longer the drain is left in place. Willemen et al.27) reported that 25% of cultures were positive 48 hours after knee arthroplasty, while Drinkwater and Neil reported culture positivity rates of 18% at 48 hours and 21% at 72 hours following orthopedic joint surgeries.8)
This study can be applied to craniotomies for these reports, because few studies have reported on surgical site healing or infection rates with or without closed suction drains in craniotomies. Even if there is not enough space between the scalp and surgical bone flap, when surgical site healing is delayed, an infection can develop within the swollen myocutaneous layer and travel directly to the meninges through the narrow gaps and holes rendered by the craniotomy. Then surgical site infection after craniotomy can potentially spread into the subdural space and/or brain parenchyma. Although our results showed no statistically significant difference in the rates of surgical site infection between DG and NDG, 2 of 274 in the DG showed overt infections at the surgical site with considerable pus discharge, and one of them required wide wound debridement while only 1 of 333 in the NDG presented with a superficial surgical site infection with a little serous oozing and tiny pus discharge from the wound margin which was managed and cured without surgery. In addition, if our method of measuring the thickness of the myocutaneous layer was reasonable, our result demonstrated that the surgical site healing process was significantly better in the NDG than the DG. Therefore, the findings of the current study may indicate that use of a drain for a pterional craniotomy is not necessary.
Beyond epidural hematoma formation and surgical site infection, various and numerous studies have reported fatal complications and potentialities such as sub- or epidural hematoma and blood loss involving a closed suction drain during craniotomy.4)13)18) Toshniwal et al.23) reported bradycardia following application of negative pressure to the subgaleal drain and Van Roost et al.24) reported harmful upward herniation syndrome and pseudohypoxic brain swelling after uneventful brain surgery, likely related to suction drainage. Other risks due to the use of drains are non-serious complications such as skin allergy, newly developed stab wound, and meshing of the drain line.
It should be noted that our study has several limitations as follows, and a few of them might substantially influence the results of the current study: 1) This report has limitations inherent to a retrospective study where clinical data were exclusively dependent on medical records and radiography as well as being non-randomized. Then we might not consider important clinical factors that could significantly influence surgical site healing, such as peripheral artery disease, chronic inflammation, and sensory neuropathy7), injecting considerable bias into our results; 2) It was also difficult to make a completely fair comparison between the pre- and post-operative head CT scans due to difference in the level of the corresponding slice; 3) Although comparison of the thickness of myocutaneous layers seems objective, quantitative, and straightforward, there are more proper and valid clinical indicators for the pterional craniotomy site healing process besides the thickness of the myocutaneous layer. 4) The authors assume that there may be several clinical conditions such as the total amount of traction exerted on the scalp and temporalis muscle during the pterional craniotomy, cerebral vasospasm, and activity status of the patient, likely influencing the changes in the thickness of the myocutaneous layer.

CONCLUSION

This study shows that there is no advantage in using a closed suction drain for a pterional craniotomy. Scientific evidence supporting the use of a closed suction drain during pterional craniotomy appears to be limited. Real evidence on the usefulness or uselessness of a closed suction drain during pterional craniotomy remains to be evaluated by a prospective, randomized, and controlled multi-institutional study.

NOTES

Disclosure: The authors declare that they have no vested interest that could be construed to have inappropriately influenced this study.

References

1. Alexander JW, Korelitz J, Alexander NS. Prevention of wound infections. A case for closed suction drainage to remove wound fluids deficient in opsonic proteins. Am J Surg. 1976 7;132(1):59-63;
crossref pmid
2. Beer KJ, Lombardi AV Jr, Mallory TH, Vaughn BK. The efficacy of suction drains after routine total joint arthroplasty. J Bone Joint Surg Am. 1991 4;73(4):584-587;
crossref pmid
3. Browett JP, Gibbs AN, Copeland SA, Deliss LJ. The use of suction drainage in the operation of meniscectomy. J Bone Joint Surg Br. 1978 11;60-B(4):516-519;
crossref pmid
4. Chan KW, Datta NN. Iatrogenic acute subdural hematoma due to drainage catheter. Surg Neurol. 2000 12;54(6):444-446;
crossref pmid
5. Cobb JP. Why use drains? J Bone Joint Surg Br. 1990 11;72(6):993-995;
crossref pmid
6. Cruse PJ, Foord R. A five-year prospective study of 23,649 surgical wounds. Arch Surg. 1973 8;107(2):206-210;
crossref pmid
7. Diegelmann RF, Evans MC. Wound healing: an overview of acute, fibrotic and delayed healing. Front Biosci. 2004 1;9:283-289;
crossref pmid
8. Drinkwater CJ, Neil MJ. Optimal timing of wound drain removal following total joint arthroplasty. J Arthroplasty. 1995 4;10(2):185-189;
crossref pmid
9. Dunlop MG, Fox JN, Stonebridge PA, Clason AE, Ruckley CV. Vacuum drainage of groin wounds after vascular surgery: a controlled trial. Br J Surg. 1990 5;77(5):562-563;
crossref pmid
10. Esler CN, Blakeway C, Fiddian NJ. The use of a closed-suction drain in total knee arthroplasty. A prospective, randomised study. J Bone Joint Surg Br. 2003 3;85(2):215-217;
crossref pmid
11. Guangming Z, Huancong Z, Wenjing Z, Guoqiang C, Xiaosong W. Should epidural drain be recommended after supratentorial craniotomy for epileptic patients? Surg Neurol. 2009 8;72(2):138-141; discussion 141
crossref pmid
12. Healy DA, Keyser J 3rd, Holcomb GW 3rd, Dean RH, Smith BM. Prophylactic closed suction drainage of femoral wounds in patients undergoing vascular reconstruction. J Vasc Surg. 1989 8;10(2):166-168;
crossref pmid
13. Higazi I. Epidural hematoma as complication of ventricular drainage. Report of a case and review of literature. J Neurosurg. 1963 6;20:527-528;
crossref pmid
14. Jepsen OB, Larsen SO, Thomsen VF. Post-operative wound sepsis in general surgery. II. An assessment of factors influencing the frequency of wound sepsis. Acta Chir Scand Suppl. 1969 396:80-90;
pmid
15. Kim YH, Cho SH, Kim RS. Drainage versus nondrainage in simultaneous bilateral total hip arthroplasties. J Arthroplasty. 1998 2;13(2):156-161;
crossref pmid
16. Lewis RT, Goodall RG, Marien B, Park M, Lloyd-Smith W, Wiegand FM. Simple elective cholecystectomy: to drain or not. Am J Surg. 1990 2;159(2):241-245;
crossref pmid
17. Magee C, Rodeheaver GT, Golden GT, Fox J, Edgerton MT, Edlich RF. Potentiation of wound infection by surgical drains. Am J Surg. 1976 5;131(5):547-549;
crossref pmid
18. Meguro T, Terada K, Hirotsune N, Nishino S, Asano T. Postoperative extradural hematoma after removal of a subgaleal drainage catheter--case report. Neurol Med Chir (Tokyo). 2007 7;47(7):314-316;
crossref pmid
19. Overgaard S, Thomsen NO, Kulinski B, Mossing NB. Closed suction drainage after hip arthroplasty. Prospective study of bacterial contamination in 81 cases. Acta Orthop Scand. 1993 8;64(4):417-420;
crossref pmid
20. Redon H, Jost , Troques . Closure under reduced atmospheric pressure of extensive wounds. Mem Acad Chir (Paris). 1954 Mar-Apr;80(12-14):394-396;
pmid
21. Reilly TJ, Gradisar IA Jr, Pakan W, Reilly M. The use of postoperative suction drainage in total knee arthroplasty. Clin Orthop Relat Res. 1986 7;(208):238-242;
crossref
22. Stevens DB. Postoperative orthopaedic infections. A study of etiological mechanisms. J Bone Joint Surg Am. 1964 1;46:96-102;
crossref pmid
23. Toshniwal GR, Bhagat H, Rath GP. Bradycardia following negative pressure suction of subgaleal drain during craniotomy closure. Acta Neurochir (Wien). 2007 10;149(10):1077-1079; discussion 1079
crossref pmid pdf
24. Van Roost D, Thees C, Brenke C, Oppel F, Winkler PA, Schramm J. Pseudohypoxic brain swelling: a newly defined complication after uneventful brain surgery, probably related to suction drainage. Neurosurgery. 2003 12;53(6):1315-1326; discussion 1326-7
crossref pmid pdf
25. Walid MS, Abbara M, Tolaymat A, Davis JR, Waits KD, Robinson JS 3rd, et al. The role of drains in lumbar spine fusion. World Neurosurg. 2012 Mar-Apr;77(3-4):564-568;
crossref pmid
26. Waugh TR, Stinchfield FE. Suction drainage of orthopaedic wounds. J Bone Joint Surg Am. 1961 10;43-A:939-946;
crossref pmid
27. Willemen D, Paul J, White SH, Crook DW. Closed suction drainage following knee arthroplasty. Effectiveness and risks. Clin Orthop Relat Res. 1991 3;(264):232-234;
28. Yasargil MG, Reichman MV, Kubik S. Preservation of the frontotemporal branch of the facial nerve using the interfascial temporalis flap for pterional craniotomy. Technical article. J Neurosurg. 1987 9;67(3):463-466;
crossref pmid
Fig. 1

Thickness of myocutaneous layer (in mm) from the surface of the skull to that of the scalp on the pterional craniotomy site at or just above the level of zygomatic arch on the head CT slice. A: Preoperative thickness of myocutaneous layer (a). B: Postoperative 7 day's thickness of myocutaneous layer (b). Postoperative thickness of myocutaneous layer value ; (b/a) × 100 (%).

jcen-17-194-g001.jpg
Table 1

Patients' demographic and clinical characteristics of DG and NDG

DG = drain group; NDG = non-drain group; DM = Diabetes mellitus

Variables DG NDG p value
Number of patient 274 333 0.285
Age (years) 49.2 (26-75) 51.5 (25-76) 0.374
Sex (M:F) 126 : 148 157 : 176 0.167
Immunosuppressive state 0 0
Uncontrolled DM 0 0
Table 2

Comparison of rate of increase in postoperative surgical site myocutaneous layer thickness between DG and NDG

DG = drain group; NDG = non-drain group

Postoperative DG (%) NDG (%) p value
Day 1 148 (± 36.9) 118 (± 28.7) 0.04
Day 7 209 (± 50.9) 152 (± 46.7) 0.027
Day 14 198 (± 48.5) 158 (± 37.9) 0.04
Table 3

Comparison of postoperative surgical site EDH and infection between DG and NDG

EDH = epidural hematoma; DG = drain group; NDG = non-drain group

DG (n = 274) NDG (n = 333) p value
Number of EDH
 Size of EDH
  Small 10 (3.6%) 6 (1.8%) 0.01
  Medium 9 (3.2%) 1 (0.3%) 0.005
  Large 3 (1%) 1 (0.3%) 0.04
 Total 22 (7.9%) 8 (2.4%) 0.02
Surgical site infection 2 (0.7%) 1 (0.3%) 0.287


ABOUT
BROWSE ARTICLES
EDITORIAL POLICY
FOR CONTRIBUTORS
Editorial Office
The Journal of Cerebrovascular and Endovascular Neurosurgery (JCEN), Department of Neurosurgery, Wonkwang University
School of Medicine and Hospital, 895, Muwang-ro, Iksan-si, Jeollabuk-do 54538, Korea
Tel: +82-2-2279-9560    Fax: +82-2-2279-9561    E-mail: editor.jcen@the-jcen.org                

Copyright © 2024 by Korean Society of Cerebrovascular Surgeons and Korean NeuroEndovascular Society.

Developed in M2PI

Close layer
prev next