Development of a Clinical Care Pathway

The perioperative care of all free flap patients at UW is guided by a streamlined clinical care pathway. This pathway begins preoperatively with significant counseling and an assessment of anticipated postoperative social work/nursing needs. Our head and neck cancer care team consents patient before surgery for peripherally inserted central catheter (PICC) and percutaneous endoscopic gastrostomy (PEG) placement; procedures that are performed while the patient is still anesthetized in the intensive care unit (ICU) the morning after surgery. PEG placement ensures that patients receive enteral tube feeds and medications within 24 hours of surgery, allowing the decreased use of intravenous fluids and avoiding the discomfort of a nasal tube. The PICC allows most new needle sticks to be avoided during their stay. Although these measures do not eliminate the recovery burden, anecdotally, they make the hospitalization and immediate home care much more tolerable. In addition, early ambulation and care by a focused head and neck nursing team has resulted in a 2-day reduction of hospital stay (average now 8.2 days) and increased levels of patient satisfaction within the first 6 months of implementation of the care pathway.

Overnight Intubation Versus Tracheostomy

Tracheostomy has traditionally been considered the mainstay of airway management following free tissue transfer to the head and neck. Many patients require this type of secure airway to avoid life-threatening obstruction; however, tracheostomy tube placement involves morbidity and complications. Therefore, at UW, we have shifted the airway management paradigm to reduce tracheostomy-related morbidity by avoiding tracheostomy in most of our head and neck free flap patients.

Tracheostomy tube complications include bleeding, infection, mucous plugging, tracheitis, aspiration-related pneumonia, and tracheal stenosis. Data suggest that there may be an increased risk of pulmonary complications in head and neck patients with tracheostomies, because tracheostomy is known to exacerbate aspiration, although it does improve pulmonary toilet. Avoiding a tracheostomy allows patients to speak earlier and maintain a strong cough. A tracheostomy may require increased nursing care and patient education and frequently complicates patients’ placement after surgery, because many US skilled nursing facilities are disinclined to approve the transfer of patients with tracheostomy tubes.

In a 2010 retrospective review published by our UW group, 37 patients who were nasally intubated following an oral cavity resection/free flap reconstructions were compared with 21 patients who underwent a tracheostomy following similar oral cavity reconstruction. The mean hospital stay (8.4 days vs 12.4 days) and the likelihood of requiring a feeding tube (19% vs 76%) at discharge were both independently increased in the tracheostomy group on multivariate analysis. There were no airway emergencies or secondary tracheostomies performed in the nasal intubation group.

Similarly, there seems to be a growing trend elsewhere in the literature toward the decreased use of tracheostomy tubes in patients undergoing head and neck free tissue transfer. In a 2014 report by Moubayed and colleagues, 66 patients underwent mandibulectomy with osteocutaneous free flap reconstruction without tracheostomy. There were no deaths or major safety events in the series, although 1 patient required an urgent secondary tracheostomy and 2 patients reported airway obstructive symptoms. A 2013 study by Coyle and colleagues reported outcomes of 50 patients undergoing free flap reconstruction with oncologic resections without a tracheostomy and a similar group of 50 patients who underwent an elective tracheostomy. There were no airway emergencies or secondary tracheostomies reported in the intubation group. In addition, the intubation group had a shorter ICU stay (1.4 days vs 3.7 days), shorter overall hospital stay (13 days vs 18 days), and a lower rate of pneumonia (10% vs 38%).

Since our 2010 publication, it has become our preference to avoid a tracheostomy in most patients undergoing free flap reconstruction. Defects for which we prefer overnight intubation include most defects of the oral cavity: large reconstructions of the oral tongue, and lateral and anterior floor of mouth; segmental mandibulectomy; as well as maxillectomy, external skin, skull base, or parotidectomy defects. Patients who we think will still benefit from an elective tracheostomy include patients who require free tissue transfer for total glossectomy defects, oropharyngeal defects (both pharyngeal and base of tongue), and hypopharyngeal defects. We are also prone to consider a tracheostomy in patients with very poor lung function, trismus, and bulky flaps that would significantly complicate reintubation. If the ease of reintubation is in question, we frequently assess laryngeal exposure with a postoperative direct laryngoscopy before the patient leaves the operating room.

Patients for whom a tracheostomy is deferred receive intravenous steroids (Decadron 10 mg intravenously every 8 hours for 24 hours) while in the ICU overnight, and then they are extubated on the first postoperative morning, unless significant airway swelling has developed. Using this approach, only a very few patients have required further airway management.

Postoperative Infections

One important clinical challenge following head and neck free tissue transfer is the high rate of postoperative infections. The location and nature of head and neck cancer resection often directly violates oral/pharyngeal surfaces and thus exposes wounds to a significant bacterial burden. This exposure places patients at high risk of wound infection, with an incidence of 8% to 45%. Limiting the rate of infection is critical in free flap surgery, because infection increases the risk of wound complications and microvascular failure. However, a consensus on the type and duration of antibiotic prophylaxis has not been uniformly established. In a landmark 1984 study, Johnson and colleagues reported that the rate of infection following head and neck cancer surgery, which was highest in oropharyngeal resections and free flap reconstructions, was greatly reduced by treating patients with 5 days of postoperative clindamycin and gentamicin (broad-spectrum gram-positive/gram-negative coverage). In 2014, the same author performed a literature review and proposed evidence-based recommendations for treatment with 24 hours of perioperative antibiotic therapy for clean-contaminated head and neck surgery. This proposal is consistent with current guidelines from the Infectious Disease Society of America (IDSA), Surgical Infection Society, and Society for Healthcare Epidemiology of America, all of which recommend 24 hours of antibiotic prophylaxis for major clean-contaminated procedures.

The authors recently analyzed and published changes to our prophylactic antibiotic protocol for patients undergoing head and neck free tissue transfer procedures. As we transitioned from prolonged courses of antibiotics, as Johnson and colleagues initially published, to the IDSA-recommended 24-hour duration, our data showed that within 30 days of surgery (which is the US Centers for Disease Control and Prevention defined time period for surgical site infection) 45% of the patients were treated for at least 1 infection: 22% at the flap inset site, 12% at donor site, and 17% at any other site (eg, pneumonia, urinary tract infection). The rate of infection in patients who received 24 hours of antibiotics was higher at 57% compared with a 42% rate in patients who received prolonged courses of antibiotics (most commonly 7 days) after surgery ( P = .01). Use of clindamycin alone relative to ampicillin-sulbactam increased the risk of postoperative infection (odds ratio [OR], 2.5; P = .01), which is presumably from limiting gram-negative bacterial coverage in patients who received clindamycin alone. In multivariate analysis, the other factor most strongly associated with postoperative infection was hypothyroidism (OR, 10.8; P <.001).

Some of these findings are in conflict with other recent studies, including a 2015 study by Khariwala and colleagues showing an increased rate of pneumonia in patients receiving longer courses of antibiotics with no reduction in surgical site infection in patients undergoing radial forearm flap reconstruction following a laryngectomy. In their analysis, obesity was the greatest risk factor and had the highest OR for developing a postoperative infection.

Postoperative antibiotic use does involve harm. The increasing frequency of antibiotic-associated complications (eg, drug reactions, Clostridium difficile infections), as well as the emergence of increasing multidrug-resistant bacteria, are intuitive reasons to avoid prolonged courses of antimicrobial therapy. However, recent data on the duration of perioperative antibiotic use are sparse in the head and neck free flap population. In our study, there was no clear correlation between antibiotic duration and C difficile infection or multidrug-resistant infection. However, this may be institutionally dependent.

In conclusion, data from our institution show a high rate of infection following head and neck free flap surgery despite adherence to the IDSA perioperative guidelines. Contributing to this high rate may be our inclusion of the full 30-day observation period, or it may represent our bias toward having a very low threshold for diagnosing postoperative infection and initiating treatment. Despite this result, our current preference is to adhere to the shorter IDSA-recommended 24 hours of broad-spectrum antimicrobial prophylaxis using ampicillin-sulbactam (first line) or clindamycin/levofloxacin (for gram-negative bacteria coverage) in patients with ampicillin allergy. The authors continue to maintain a very low threshold for prolonged antibiotic use (5 to 7 days) for patients with hypothyroidism or poor wound healing given supportive data from our recent report.

Postoperative Free Flap Monitoring

More than 20 different methods for free flap monitoring have been described in the literature. Methods range from a simple clinical examination and pinprick testing to using complex technological innovations, including methods using implantable Doppler ultrasonography, microdialysis probes, oxygen saturation probes, laser Doppler, fluorometry, implantable temperature probes, glucose/lactate monitors, handheld Doppler, scintigraphy, pH monitoring, impedance plethysmography, confocal microscopy, smartphone serial photoimaging, and several other techniques.

Despite this variety, the goals of monitoring remain singularly focused on reducing the rate of free flap loss. Monitoring techniques achieve this goal by heralding the risk of free flap compromise before overt clinical change, thus improving the chances of free flap salvage. Timely identification of a threatened flap increases the rate of salvage and decreases the risk of the no-reflow phenomenon.

Despite a high rate of free flap survival, clinicians at UW continue to place a high priority on meticulous monitoring to ensure our high rate of success. Over the past 20 years, many methods for free flap monitoring have been tried by the authors, but in our practice no method has been as reliable and accurate as simple skin prick testing. Our protocol calls for a nursing-performed clinical examination every hour for the first 24 hours while patients are in the ICU overnight. In addition, the flap is checked by a physician with a clinical examination and pinprick testing every 6 hours for a total of 72 hours. After 72 hours, the flap is checked twice daily without planned pinprick until discharge.

In order to facilitate pinprick monitoring, a concerted effort is made to develop a monitoring paddle during reconstruction. If a monitoring paddle is not used (a completely buried flap), then we use an implantable Doppler system on both the artery and the venous outflow. This use of the Cook implantable Doppler on buried flaps has been shown to be particularly valuable, as was shown in a 2011 retrospective review of 548 microsurgical cases in which the rate of salvage for buried flaps was improved significantly with use of the implantable Doppler versus a clinical examination alone (94% vs 40%). Continuous implantable Dopplers are also preferred following free flap take-backs that require revision of the microvascular anastomosis.

Fig. 1 shows the use of pinprick testing with a 25-gauge needle. A reassuring result is shown by the delayed (2 to 5 seconds) appearance of bright red blood. Fig. 2 shows a flap that is congested on pinprick testing. The 46-year-old patient underwent a composite oral cavity resection followed by reconstruction with an osteocutaneous radial forearm flap. On the first postoperative day, the patient was noted as having dark venous blood on pinprick testing. A subsequent take-back was significant for the twisting of the venous outflow tract causing venous obstruction. A revision venous anastomosis was performed and no further issues developed, resulting in successful free flap salvage.

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