Preoperative irrigation and vacuum sealing drainage with antibiotic-containing drainage fluid of foot and ankle wounds improves outcome of reconstructive skin flap surgery
By observing the infection and soft tissue defect on the wound surface of the foot and ankle, this paper attempts to explore the effect of preoperative irrigation and vacuum sealing drainage with antibiotic-containing drainage fluid (abPI-VSD) on the bacterial quantity and the local inflammatory response at the flap, and further to provide a basis for applying this technique before a reconstructive skin flap surgery of foot and ankle wounds.
Seventy-five patients were randomly divided into two groups, and all surgeries were done by one physician. The flap reconstructions were done to 31 cases with the abPI-VSD being used (group A); the flap reconstructions were done to the rest 44 cases after wound cleaning using antibiotic irrigation solution without the use of the abPI-VSD (group B). Quantitative bacteriology was made to group A before and after the use of abPI-VSD; quantitative bacteriology was made to group B before and after wound cleaning. Then, the reconstructive skin flap surgery was done. After the surgeries, the time of local inflammatory response at the flap in both groups were recorded. The measured bacterial quantity was evaluated in logarithm and by t test.
The bacterial quantity was 3.2 ± 1.9 × 107 cfu/g in group A before the use of abPI-VSD and 2.3 ± 2.0 × 107 in group B (P > 0.05) before debridement. The bacterial quantity was 1.2 ± 2.0 × 104 cfu/g in group A after abPI-VSD and was 2.9 ± 4.0 × 106 in group B after wound cleaning (P < 0.05). The time of postoperative inflammatory response in the flap was 8 ± 2.5 days in group A and 13 ± 3.4 days in group B (P < 0.05).
abPI-VSD can distinctly reduce the bacterial quantity on the surface of the wound, provide a good condition of tissue bed for the flap reconstruction, and effectively control the local inflammatory response at the flap and hence improve the survival quality of the flap.
KeywordsFlap reconstruction Bacterial infection Inflammatory response
Preoperative irrigation and vacuum sealing drainage with antibiotic-containing drainage fluid
Preoperative irrigation and vacuum sealing drainage
Vacuum sealing drainage
Severe open foot or ankle injuries (open fractures) are associated with soft tissue defects that in some cases entail bone and tendon exposure. The soft tissue defects are commonly repaired by reconstructive skin flap surgery [1, 2, 3]. However, a considerable risk factor in reconstructive surgery is free or pedicle flap infection [4, 5, 6], which can reduce the quality of the flap or even lead to necrosis in part of the flap or in the entire graft [7, 8]. Consequently, ensuring that the wound contains minimal bacterial load is key to proper primary wound closure and optimal skin flap transplantation outcome [9, 10].
Several strategies have been employed to reduce or eliminate infections in physical trauma-induced open fractures. These include standard methods such as debridement and occlusive dressing [11, 12] as well as more novel approaches such as dermal regeneration matrices  and preoperative irrigation and vacuum sealing drainage [PI-VSD] [8, 14, 15, 16, 17], both of which may be accompanied by antibiotic prophylaxis, the application of antibiotic agents [10, 12, 14, 18], photodynamic therapy [19, 20], and the use of wound dressings that reduce biofilm formation . PI-VSD comprises irrigation of the wound followed by the placement of a drainage container over the open wound and the passage of sterile fluid under conditions of negative pressure. As a result, wound exudate, necrotic tissue fragments, and pus are effectively removed and the wound area is kept moist so as to emulate physiological conditions to promote healing and reduce healing time . Rapid elimination of infections and infection-prone material from the wound is critical in expediting primary wound closure by reconstructive surgery , which can be effectively achieved by PI-VSD. The modality also increases blood flow to the wound  and promotes the accumulation of leukocytes and fibroblasts in the wound that facilitate the healing process . Moreover, PI-VSD reduces edema and third space fluids, the frequency at which wound dressings require changing (and hence the workload of medical staff), and overall medical costs [15, 16, 24]. Accordingly, PI-VSD is increasingly being integrated into reconstructive surgery protocols for open fractures.
Of the abovementioned techniques, PI-VSD was shown to yield better results in open fracture patients than debridement and occlusive dressings. In a recent retrospective study, two cohorts of patients with Gustilo type IIIB open tibial fractures were compared with respect to occlusive dressing versus vacuum sealing drainage (VSD) . In the VSD group, only 10% of the patients exhibited flap failure and 6% had an infection, whereas these statistics were 33% and 11%, respectively, in the occlusive dressing group. Moreover, dermal regeneration matrices such as Medskin Solutions’ MatriDerm and Johnson & Johnson’s Integra are associated with a failure rate of up to 25%  and do not address the infection. Although PI-VSD is also associated with occasional mild drawbacks , the modality is safe  and is of adjuvant value for wound healing  and the outcome of reconstructive surgery .
The above referenced studies and others have demonstrated that PI-VSD can reduce the degree of infection [27, 28, 29], but no studies have examined the effect of PI-VSD with antibiotic-containing drainage fluid (abPI-VSD) on bacterial load and flap quality. Our work therefore focused on the effect of PI-VSD with gentamicin on the bacterial load in physical trauma-induced open foot and/or ankle wounds and the inflammatory response in the graft following reconstructive skin flap surgery. It was hypothesized that abPI-VSD would reduce bacterial load in the pre-surgical wound, reduce inflammation in the post-surgical flap, and improve flap quality. The main findings of the study were that abPI-VSD significantly reduced the incidence of secondary infections on the surface of open fracture wounds, augmented the post-operative quality of the transplanted tissue, and improved the surgical outcome. An optimized protocol for abPI-VSD was formulated.
Materials and methods
Patients and clinical presentation
The study was approved by the institutional review board of the No. 971 Hospital of the People Liberation Army and performed in accordance with the Declaration of Helsinki. Written informed consent was obtained from all patients prior to inclusion.
Seventy-five patients who were admitted at the Department of No. 971 Hospital of the People Liberation Army during the period April 2013 to January 2018 were included in the study. Hospitalized patients who presented with soft tissue defects at the foot and ankle, wound infection, and necrotic tissue on the wound surface were included in the study. Where necessary, the patients received upon admission to correct the water and electrolyte disbalance and hypoproteinemia and to improve nutritional status.
Patient demographics, injury characteristics, and study design
Patient demographics and injury characteristics
Mean ± SD age [years]
37.7 ± 7.3
36.5 ± 5.6
Size of the injury [cm2]
19.4 ± 5.3
21.1 ± 6.2
Mean ± SD time between injury and surgery [days]
15.8 ± 4.3
17.4 ± 6.7
Type of injury 
Traffic accident 
Crushing injuries from stones or machines 
Machine squeezing or twisting 
Metallurgical hot press 
Wound care, preoperative irrigation, and vacuum sealing drainage
Continuous irrigation was applied during the first 24–48 h at a volume of 4000–5000 mL/day. The solution was kept at 25–27 °C with a temperature controller (Sanyo, Osaka, Japan), and the irrigation was performed at a negative pressure of 20 kPa to avoid clogging of the drainage tube. After 2–3 days, when the amount of floccules in the drainage liquid had receded and the color had faded, irrigation was performed intermittently (3 times/day) at 2000–3000 mL/day and a negative pressure of 5 kPa. After 3–5 days, when the drained liquid had cleared up, the volume was further lowered to 1000–2000 mL/day. Intermittent irrigation (2 times/day) was continued for 3–5 days. After the drained liquid was free of bacteria (assessed by bacterial culture at the Department of Clinical Microbiology, NO. 971 Hospital of PLA), the PI-VSD was removed.
In group B, the wound was cleaned by debridement using gentamycin irrigation solution. Then, the skin flap transplantation was performed.
Determination of bacterial load
In group A, the bacterial load was determined before and after abPI-VSD, whereas in group B, the bacterial load was determined before and after debridement. Seventy-five percent of alcohol was used to disinfect the wound surface twice. Two parallel incisions were made in the center of the disinfection area, 1 cm in length and 1 cm in width, and a tissue biopsy (9–55 mg) was acquired from the wound surface center and weighed. The specimen was suspended in sterile saline solution at a 1:99 weight to volume ratio and homogenized in a glass homogenizer. The homogenate was serially diluted 10× with sterile saline solution (Siyao). A 10-cm diameter agarose plate was inoculated with the 100 μL-fold dilution and incubated at 37 °C for 24 h. The number of bacterial colonies was counted under a microscope. The bacterial load in each wound was calculated as the number of bacterial colonies × 10 × dilution factor.
Pedicle flap reconstructive surgery
The reconstructive skin flap surgery was performed by one physician. All the wound surfaces were reconstructed using an antegrade and retrograde pedicle flap, local transplantation, subcutaneous tunnel, and cross leg flap.
Quantification of the extent of graft inflammation
After surgery, the local inflammatory response in and around the flap was monitored. Inflammation was determined by the time it took for the flap temperature to drop. The extent of inflammation in the pedicle flap was determined by the C-reactive protein (CRP) levels.
The bacterial number in each gram of tissue ± standard deviation cfu/g means that by using the statistical software SPSS (SPSS, Chicago, IL), take the logarithm of the bacterial number and conduct the independent-samples t test; P ≤ 0.05 is of statistical significance. The flap local inflammatory response time is measured by the independent-samples t test.
There were no statistical differences between the two groups with respect to gender, age, area of injury, and time frame between injury and surgery (P > 0.05).
The comparison of bacterial quantity between groups A and B (Table 2)
Bacterial quantity and flap local inflammatory reaction time
Before using PI-VSD, bacterial quantity
Pre-reconstructive surgery, bacterial quantity
Flap local inflammatory, reaction time [days]
3.2 ± 1.9 × 107 △
1.2 ± 2.0 × 104**
8 ± 2.5**
2.3 ± 2.0 × 107△
2.9 ± 4.0 × 106**
13 ± 3.4**
The bacterial quantity was 1.2 ± 2.0 × 104 cfu/g in group A after the use of abPI-VSD procedure and was 2.9 ± 4.0 × 106(P < 0.05) in group B after debridement using gentamycin irrigation solution.
Postoperative flap local inflammatory reaction time (Table 2)
After the surgery, time of flap local inflammatory response was observed and recorded, which is 8 ± 2.5 days in group A and 13 ± 3.4 days in group B (P < 0.05).
Between April 2007 and January 2009, our hospital treated 75 patients with a foot and/or ankle infection and soft tissue defects. abPI-VSD technique was adopted before all the surgeries to control bacterial growth and clean the wound. During the surgery, different pedicle flap coverage was chosen according to the location and size of the tissue defect. The wound was cured and the local blood supply was improved in one stage, and the patients recovered well from the foot and ankle infection, which displays a rather satisfactory effect.
Influence of wound surface bacterial quantity on the flap
Chang and Mathes  observed that the intracutaneous inoculation of Staphylococcus aureus to dog flap could cause flap necrosis. Pearl  found that compared to any other types of flaps, axial flaps and myocutaneous flaps have higher ability to eliminate the inoculated bacteria under flaps and that any type of flap, after treated by a small dose of phenoxybenzamine to increase its blood supply, has an obviously higher ability to eliminate bacteria, which demonstrates that the ability of myocutaneous flaps to eliminate bacteria is determined by blood supply.
Compared with any other types of flaps, myocutaneous flaps are abundant in blood supply and have higher ability to eliminate wound surface bacterial when the wound surface is considered to be moderate pollution (105/g tissue). However, myocutaneous flaps look bloated and swollen and damage the donor greatly, which limits its application in clinical practice. Most importantly, if the bacterial quantity is too large, myocutaneous flaps get infected easily and influence the survival quality of flaps, and even worse, cause flap necrosis or partial necrosis. Therefore, before reconstructing infection and soft tissue wound surface on the foot and ankle, measures such as local application of sensitive antibiotics or PI-VSD should be used to control bacterial growth.
Influence of PI-VSD application on wound surface bacterial quantity
In recent decades, with the theory of wound “moist healing”  being put forward, numerous studies have proven that PI-VSD technique can provide a moist environment for foot and ankle wound, helping the wound to heal and, in the meantime, reducing the bacterial quantity and alleviating the infection on the wound surface.
Weed et al.  found in animal studies that the use of VAC can decrease the bacterial quantity. Polykandriotis et al.  applied PI-VS D to 9 cases of hand injury and effectively cured the hand defects and prevented them from getting infected. PI-VSD turns open wound to closure wound, preventing the invasion of bacteria, and forms a slow liquid flow from the wound to the dressing, making the vital cells to be kept and wastes such as the flaccid cells and non-nutritious interstitial fluid to be suctioned and reducing the culture medium for bacterial survival and growth.
PI-VSD can reduce the foot and ankle wound surface infection, which might be related to the fact that a closure and moist environment is better for the immune cells in the organism to function . Compared to the dry wound surface formed under the traditional mullauflage, the moist wound surface formed under the enclosed dressing is better for the polymorphic nucleus eukopenia to infiltrate, which offers a good local environment for the immune cells to phagocytose and eliminate bacteria, and further reduces the bacterial quantity. We assume that vacuum sealing drainage therapy is in a position to become a reliable sealing technique for temporary soft tissue defect and bone exposure. The result of this experiment showed that vacuum aspiration effectively eliminate tissue degradation product and pollutant, decrease bacterial quantity, control infection, and improve the survival quantity of the flap.
Preoperative PI-VSD reduces damage to the donor and receptor site during surgery
For the infected wound surface on the foot and ankle, to apply PI-VSD before the surgery can not only clean the exudates and reduce the local tissue edema, but also promote the production of granulation tissue, speed the healing and epithelialization of the wound, and play a role in slow serial debridement. Clinical observation shows that after the use of PI-VSD and slow debridement of the wound surface, the granulation tissue is healthy and fresh (Fig. 2). Therefore, in regard to seriously infected wound surface, adopting preoperative PI-VSD and the relatively conservative serial debridement instead of radical debridement, and then doing the flap reconstruction, can retain important tissue as much as possible. On the premise of using PI-VSD to reduce the bacterial quantity on the wound surface, carrying on serial debridement decreases the damage to important structure in the donor during the surgery.
Musculocutaneous flaps and fasciocutaneous flaps used to cover the wound surface of ankle joint soft tissue can be divided into many types, including arteria peronea retrograde flap, medial crural flap, sural neurotrophy vessel flap, saphenous neurotrophy vessel flap, and cross-leg flap. The choice of flaps is determined by the conditions of ankle joint, pretibial and posterior tibial artery, and the soft tissue on the affected side and around the ankle joint. If there is soft tissue edema around the ankle joint, or the soft tissue or the artery is in a bad condition, the cross-leg flap with better tissue can be chosen for the reconstruction. For patients who need flap retrograding island transposition of sural neurotrophy vessel and saphenous neurotrophy vessel, the acerated ends of the sural nerve or the saphenous nerve on the flap lateral margin can be anastomosed with the medial plantar or lateral plantar nerve.
To merge an open infection on the ankle joint, according to the position of the focus and the condition of the infected side body, choose different musculocutaneous flap and fasciocutaneous flap to cover the wound, and at the same time renew the impermeability of the ankle joint cavity. According to the postoperative drug sensitive test, use local antibiotic solution perfusion and constant vacuum sealing drainage through tube to treat the joint infection, or use ozonated water or silver nitrate solution  to eliminate the bacterial.
The results of the experiment show that vacuum aspiration eliminate tissue degradation product and pollutant and control bacterial infection. The bacterial quantity was 3.2 ± 1.9 × 107 cfu/g in group A before the use of abPI-VSD and was 2.3 ± 2.0 × 107 cfu/g (P > 0.05) in group B before debridement, which illustrate that the degree of wound surface pollution in the two groups are the same. Group A used treatment measure to control bacterial growth for 5–7 days, and the bacterial quantity on wound surface reduces from 3.2 ± 1.9 × 107 to 1.2 ± 2.0 × 104 cfu/g (P < 0.05). The operative inflammatory response time was 8 ± 2.5 days in group A and 13 ± 3.4 days in group B (P > 0.05).
The experiment proves that the application of abPI-VSD before the surgery for foot and ankle infection and soft tissue defect can reduce the damage to the donor and the receptor site in the surgery, decrease distinctly the bacterial quantity on wound surface, and further reduce the local inflammatory response at the flap, which are helpful to the flap quality. PI-VSD technique with antibiotic-containing drainage fluid has great value in clinical application.
HLY offered an idea about this study. XG collected and analyzed the patient data and was a major contributor in writing the manuscript. JS participated in the proofreading of this article. All authors had read and approved the final manuscript and ensured that this is the case.
No sources of funding were declared.
Ethics approval and consent to participate
This study was conducted in accordance with the principles of the Declaration of Helsinki and approved by the medical ethics committee of No.971 Hospital of the People Liberation Army. All patients involved in this study gave informed written consent to participate.
Consent for publication
A written informed consent was obtained from all participants.
The authors declare that they have no competing interests.
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