Effects of Simultaneous versus Staged VAC Placement in the Treatment of Deep Neck Multiple-Space Infections at a Tertiary Hospital Over a Four-Year Period in China.

PURPOSE: Surgical drainage is an essential part of treatment for deep neck infections (DNIs) or deep neck multiple-space infections (DNMIs). With the emergence and application of new technologies and new materials, vacuum-assisted closure (VAC) in the treatment of DNMIs has been reported. However, reports on the timing of VAC placement are limited. Herein, we compared simultaneous versus staged VAC placement in the treatment of DNMIs. PATIENTS AND METHODS: Medical data from 24 patients with DNMIs who had received VAC treatment in the last five years were analyzed. The patients were classified into a simultaneous VAC placement group (11 patients) and a staged VAC placement group (13 patients) according to the timing of VAC placement when incision and drainage were performed.
RESULTS: No differences in baseline characteristics were found between the two groups. All patients in the two groups survived and recovered. The hospitalization duration (days), time to wound healing (days), number of debridement procedures, and disease course (days) in the simultaneous VAC placement group and staged VAC placement group were 10 (4-18) and 22 (8-35), 21 (4-39) and 50 (9-86), one (1-2) and two (1-4), and 31.5 (11-49) and 56 (19-98), respectively. The results in the simultaneous VAC placement group were better than those in the staged VAC placement group (P = 0.001, 0.016, 0.045, and 0.016, respectively). The numbers of VAC sponge changes in the simultaneous VAC placement group and staged VAC placement group were two (1-2) and two (1-4), respectively, with no statistically significant difference (P = 0.336).
CONCLUSION: Simultaneous VAC placement during incision and drainage may shorten the wound healing time, hospitalization duration, and disease course and may reduce the number of debridement procedures.

Introduction

Deep neck infections (DNIs) are a group of serious bacterial infections occurring in the potential spaces and fascia of the neck.1 The incidence of DNIs is not clear. Although many studies have shown that the incidence of DNIs has decreased due to the use of antibiotics and improvements in sanitary conditions,2–4 reports also indicate an increased incidence of DNIs in the last 10 years.5,6 Deep neck multiple-space infections (DNMIs) are the most serious among all types of DNIs and often spread further to cause mediastinal infections, invade the carotid sheath, and possibly compromise the airway, resulting in life-threatening conditions.7,8

Treatments for DNMIs include life-supporting measures, surgical drainage, and appropriate use of antibiotics. Among these treatments, surgical drainage is key.9 Although traditional extensive surgical drainage is effective for treating DNMIs, some limitations remain for this approach, ie, drainage depends on gravity, the locations for the drainage tube and incision are limited, dressing changes and wound irrigation more than once a day may increase patient suffering, and secondary wound infection may occur.10,11 In recent years, vacuum-assisted closure (VAC) in the treatment of DNIs or DNMIs has been reported12–15 and has shown positive efficacy, but no reports on the timing of VAC placement are available.

This study aimed to compare the effects of simultaneous VAC placement and staged VAC placement by retrospectively analyzing the medical data of DNMI patients who had received VAC treatment within the last five years.

Patients and Methods

Patients

This study was approved by the ethics committee of Peking Union Medical College Hospital (ethics approval No. JS2084). All patients included in the study signed an informed consent form before surgery. The medical data of patients with DNMIs who received VAC treatment at our hospital between January 2015 and December 2019 were collected, and medical records, imaging data, and bacteriological results were reviewed. Patients with DNMIs caused by tumors and trauma were excluded from the study. A total of 24 patients were included.

Surgical Procedures

Simultaneous VAC placement: All patients underwent general anesthesia following endotracheal intubation or tracheostomy for airway protection before neck incision and drainage. The appropriate incision was made according to the different sites of infection to ensure adequate exposure of the infected area and smooth drainage. The pus was collected during the surgery for bacterial culture and susceptibility testing. After the abscess cavity was exposed, blunt dissection of the infected spaces by fingers was performed for smooth drainage, and the necrotic tissues were removed (Figure 1A). Blunt dissection by fingers is a key step. On the one hand, separating tissues by fingers is safe and has little impact on the complex nerves and vascular tissues of the neck, which is increasingly important when facing unclear anatomical signs in deep neck multiple-space infections. On the other hand, this method is also very effective in opening every potential pus cavity, which promotes the treatment effect. After repeated rinsing of the surgical cavity and verifying that the cervical sheath was free from infections, foam material of appropriate size was placed according to the infected area, and transparent film completely covered the wound to ensure sealing. Then, the VAC device (V.A.C. ®, Kinetic Concepts Inc, San Antonio Texas, USA) was connected (Figure 1B).

Figure 1

Vacuum-assisted closure (VAC) in the treatment of deep neck infection. Simultaneous VAC: (A) The abscess cavity was exposed, and necrotic tissues were removed. (B) The foam material was then placed into the infected area, and the transparent film completely covered the wound to ensure sealing. In addition, the VAC device was connected. Staged VAC: (C) Infection wound failed to heal after conventional drainage and repeated debridement. (D) The VAC device was then placed into the infected area to facilitate wound healing. White arrows in (B and D) indicate the foam material and the transparent film, respectively.

Staged VAC placement: All patients in the staged VAC placement group had received conventional incision and drainage, and the VAC was placed in the same way as that in the simultaneous VAC placement group during repeated debridement (Figure 1C and D).

Evaluation Indicators

First incision time: the time from DNI onset to the first incision and drainage procedure (the time of puncture was not considered the incision time); hospitalization duration: the time from patient referral to our hospital to patient discharge from our hospital; wound healing time: the time from incision to reaching all four endpoints (self-healing, stitch removal, drainage tube removal, and tracheostomy cannula removal); disease course: the time from DNI onset to complete healing; number of debridement procedures: the number of debridement procedures performed in the operating room (bedside debridement was not included); and number of VAC changes: the number of VAC sponge changes.

Results

General Information

All 24 patients who underwent VAC placement were referred to our hospital (a central and tertiary hospital in Northern China) from other hospitals. The results for the simultaneous VAC placement group (11 patients) and staged VAC placement group (13 patients) were as follows: age of the patients: 58 (47–65) and 57 (41–79) years; sex ratio: 9:2 and 11:2; body mass index (BMI): 25.38 (22.09–31.63) and 24.76 (17.99–35.16) kg/m2; the proportion of patients with concomitant diabetes: 5/11 (54.5%) and 7/13 (53.8%); the time from onset to incision: seven (5–15) and 10 (4–21) days; and the proportion of patients undergoing tracheotomy: 5/11 (45.5%) and 8/13 (61.5%), respectively. All the differences between the two groups were not statistically significant (P=0.586, 0.648, 0.902, 0.528, 0.301, and 0.268, respectively) (Table 1).

Table 1

General Information

Patient Demographics	Simultaneous Placement (n=11)	Asynchronous Placement (n=13)	P value
Age (year)	58 (47–65)	57 (41–79)	0.586
Male/Female	9/2	11/2	0.648
BMI (kg/m2)	25.38 (22.09–31.63)	24.76 (17.99–35.16)	0.902
Diabetic ratio	6/11 (54.5%)	7/13 (53.8%)	0.528
Incision time after onset (days)	8 (5–16)	10 (4–21)	0.301
Tracheotomy	5/11 (45.5%)	8/13 (61.5%)	0.268

The ratios of patients with odontogenic infection (patients with a history of toothache and tooth extraction before onset) to patients with nonodontogenic infection in the simultaneous VAC placement group and staged VAC placement group were 6:5 and 6:7, respectively. The imaging and surgery results demonstrated that all the patients had DNMIs. In the simultaneous VAC placement group and the staged VAC placement group, involvement of the submental and submandibular spaces was observed in 9 and 12 patients, parapharyngeal space involvement was observed in 11 and 13 patients, retropharyngeal space involvement was observed in four and eight patients, prevertebral space involvement was observed in one and two patients, and mediastinal infection was observed in four and five patients, respectively. Multiple bacterial infections detected in the initial culture of secretions were found in two patients in the simultaneous VAC placement group and in four patients in the staged VAC placement group (Table 2). The results of initial bacterial culture of secretions from the 24 patients were as follows: Streptococcus anginosus (eight patients), Streptococcus constellatus (five patients), Acinetobacter baumannii (two patients), viridans group streptococci, Staphylococcus epidermidis, Streptococcus parasanguis, coagulase-negative Staphylococcus, and Stenotrophomonas maltophilia (one patient each). No pathogenic bacteria were found in the secretion cultures of eight patients.

Table 2

Characteristics of Infection

	Simultaneous Placement (n=11)	Asynchronous Placement (n=13)	P value
Odontogenic/Non-odontogenic	6/5	6/7	0.608
Involved Region
Submental and submandibular	9	12	0.619
Parapharyngeal	11	13	-
Retropharyngeal	4	8	0.472
Prevertebral	1	2	0.684
Mediastinal infection	4	5	0.443
Multiple bacterial infections	2	4	0.344
Negative of bacterial culture	3	2	0.262

Clinical Outcomes

The treatment for all 24 patients was successful, and no deaths occurred. The hospitalization duration (days), wound healing time (days), number of debridement procedures, and disease course (days) in the simultaneous VAC placement group and staged VAC placement group were 10 (4–18) and 22 (8–35), 21 (4–39) and 50 (9–86), one (1–2) and two (1–4), and 31.5 (11–49) and 56 (19–98), respectively. All the results in the simultaneous VAC placement group were better than those in the staged VAC placement group (P=0.001, 0.016, 0.045, and 0.016, respectively). The numbers of VAC sponge changes in the simultaneous VAC placement group and the staged VAC placement group were two (1–2) and two (1–4), respectively, and the difference between the two groups was not statistically significant (P=0.336) (Table 3).

Table 3

Evaluation of Efficacy

	Simultaneous Placement (n=11)	Asynchronous Placement (n=13)	P value
Hospital stays length (days)	10 (4–18)	22 (8–35)	0.001**
Healing length (days)	21 (4–39)	50 (9–86)	0.016*
Number of debridement	1 (1–2)	2 (1–4)	0.045*
Number of replacement	2 (1–2)	2 (1–4)	0.336
Disease course (days)	31.5 (11–49)	56 (19–98)	0.016*

Notes: *Statistical significance; **Significant statistical significance.

Discussion

Sufficient surgical drainage and clearance of necrotic tissues are particularly important in the treatment of DNIs or DNMIs.9 An extensive incision is necessary for the traditional approach, which depends on gravity for drainage and requires repeated dressing changes and debridement. The traditional approach is effective, but patients suffer from repeated dressing changes and debridement, infections require a long time for resolution, and the likelihood of nosocomial infection increases.16

Kostiuchenok (1986) first reported the use of VAC in the treatment of 116 patients with pyogenic infections in Russia and found that wound healing was promoted.17 Since then, VAC treatment has become popular for use in wound healing. Schuster et al14 and Gallo et al18 first reported the use of VAC in the treatment of facial infections and DNIs or DNMIs, and good efficacy was achieved in both studies. VAC is widely believed to promote wound healing and reduce infections by producing local negative pressure to absorb wound secretions and blood, thus promoting reparative granulation tissue formation.19,20 Balci et al21 and Chen et al12 reported 11 and seven cases of VAC in the treatment of necrotizing fasciitis of the head and neck, respectively. Cao et al11 reported seven cases of VAC in the treatment of serious deep neck and face infections. These three studies concluded that VAC had positive efficacy in the treatment of DNIs or DNMIs according to the descriptive analysis of the included cases. Unfortunately, these articles did not report whether differences in the timing of VAC placement cause differences in efficacy.

This study reported the use of VAC in the treatment of 24 patients with DNMIs, representing the largest number of enrolled patients undergoing VAC placement for DNI or DNMI treatment among currently available articles. This retrospective analysis showed that baseline disease characteristics between the two groups were comparable. The findings of this study demonstrated that the hospitalization duration, wound healing time, number of debridement procedures, and disease course in the simultaneous VAC placement group were significantly better than those in the staged VAC placement group. However, previous studies did not report the impact of VAC placement timing on efficacy. The meta-analyses performed by Sahebally et al22 Hyldig et al23 Wu et al24 and Gabriel et al25 were reviewed, and the results showed that simultaneous VAC placement during wound closure reduced the likelihood of surgical site infections, including those resulting from abdominal surgery, thoracic surgery, and breast surgery. A meta-analysis by Liu et al26 showed that in patients with infectious wounds such as diabetic foot ulcers, VAC can increase the proportion of diabetes patients with postoperative healing of foot wounds and foot ulcers and shorten the healing time compared with a traditional nonnegative pressure wound therapy dressing. These findings indicate that early VAC placement can reduce the incidence of wound (a clean wound or a contaminated wound) infection and promote wound healing. In theory, the mechanism of VAC in reducing infections and promoting wound healing involves improving the blood flow around wounds, reducing tissue edema, and stimulating the formation of reparative granulation tissue.19,20,27 However, whether VAC can reduce bacterial loads remains debatable.27–29 These findings can explain why DNMI patients who received simultaneous VAC placement had shorter healing times.

This study has the following limitations: this was a retrospective nonrandomized controlled study, and the sample size was not sufficiently large. Furthermore, in all patients who underwent VAC placement, the carotid sheath was found to be intact and free from infection during surgery; concomitant carotid sheath infection is one cause of fatal DNIs. Finally, the patients included in this study does not represent all patients with DNIs, especially those with fatal massive bleeding.

Conclusion

Although our study has some limitations, the findings demonstrate that simultaneous VAC placement may shorten the wound healing time, hospitalization duration, and disease course and may reduce the number of debridement procedures compared with staged VAC placement.