Abstract
Background
Delayed gastric emptying (DGE) is a common complication of pancreaticoduodenectomy. We determined the efficiency of a new reconstruction technique, designed to preserve motilin-secreting cells and maximize the utility of their receptors, in reducing the incidence of DGE after pancreaticoduodenectomy.
Methods
From April 2005 to September 2014, 217 consecutive patients underwent pancreaticoduodenectomy at our institution. Nine patients who underwent total pancreatectomy were excluded. We compared outcomes between patients who underwent pancreaticoduodenectomy with resection of the pyloric ring followed by proximal Roux-en-y gastrojejunal anastomosis (group I, n = 90) and patients who underwent standard pancreaticoduodenectomy with the orthotopic reconstruction technique (group II, n = 118).
Results
Overall and clinically relevant rates of DGE were significantly lower in group I than in group II (10 and 2.2 % vs. 57 and 24 %, respectively; p < 0.05). Length of hospital stay as a result of DGE was shorter in group I than in group II. In univariate analysis, older age, comorbidities, ASA grade 4, operative time, preoperative diabetes, standard reconstruction technique, and postoperative complications were significant risk factors for DGE. In multivariate analysis, older age, standard technique, and postoperative complications were independent risk factors for DGE.
Conclusion
Our new reconstruction technique reduces the occurrence of DGE after pancreaticoduodenectomy.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Delayed gastric emptying (DGE), a common complication of pancreaticoduodenectomy (PD), has an incidence ranging from 3 to 61 %, depending on the reconstruction technique and definition used.1–19 Although DGE is non-fatal and self-limiting, it contributes significantly to increased patient discomfort, hospital length of stay, and medical costs. The pathogenesis of DGE after PD is multifactorial. Although perioperative risk factors and postoperative intra-abdominal complications contribute to the overall incidence of DGE, the disruption of neuro-humoral pathways remains the common denominator in all patients after PD that contributes to the occurrence of primary DGE.
Gastric motility is a coordinated process of myoelectrical activities involving the gastric reservoir, antral pump, pylorus, and duodenum. These activities are controlled by both entero-gastric neural reflexes and hormones released from the intestines that reach the stomach via the systemic circulation. Gastric emptying occurs during two distinct periods: the postprandial motility period that starts after each meal and the subsequent interdigestive period, during which the gastrointestinal tract produces rhythmically recurring cycles of activity that involve four phases. Phase III, known as the migrating motor complex (MMC), consists of forceful peristaltic waves that originate simultaneously in the stomach and the duodenum and propagate along the entire length of the small intestine. The main function of the MMC is to empty the stomach and small intestine from chyme residues, mucous, and bacteria.20–22 The recurrence of phase III at the end of the postprandial period is facilitated by the release of motilin hormone secreted from endocrine cells in the gastric antrum and duodenum.23 Motilin then reaches the stomach and small intestine via the systemic circulation, acting on receptors found at high concentrations on the smooth muscle and nerve endings in the gastric antrum, duodenum, and proximal jejunum.9,23,24 As the MMC activity reaches the small intestine, the velocity of propagation of the peristaltic waves declines from the proximal jejunum to the distal small intestine, which is most likely related to a decreased number of motilin receptors along the gastrointestinal tract.20
Standard PD entails the removal of the gastric antrum, head of the pancreas, duodenum, common bile duct, and the proximal 5 to 10 cm of jejunum. The magnitude of the resection and reconstruction disrupts the aforementioned neuro-humoral pathways that coordinate the myoelectrical activities responsible for gastric emptying.25–27 Impaired postprandial motor activity after PD has been explained by a significant reduction in levels of circulating gastrin and other gastrointestinal hormones normally secreted by the stomach and the duodenum.28 Furthermore, resection of the gastric antrum and duodenum has been shown to reduce the cyclic increase in plasma levels of motilin, thus impairing phase III activity in the efferent loop of the gastrojejunal anastomosis (GJA).29 However, effective stimulation of gastric emptying after PD can be achieved by a motilin receptor agonist such as erythromycin, which has been shown to enhance phase III gastric contraction via motilin receptors.19,30
Different techniques for GJA have been proposed to improve gastric emptying after PD.9,10,12,31–34 Pylorus-preserving PD (PpPD) was developed and widely used to improve patients’ nutrition and to reduce the complications related to standard PD.35–37 However, abnormalities of postprandial and MMC activities involving the afferent and efferent limb of the GJA, together with low amplitude and frequency, have been documented in up 70 % of patients after either standard PD or PpPD.29,38 Currently, no conspicuous technique has been described that can explicitly eliminate the incidence of primary DGE. The majority of techniques are used to construct the GJA on the first loop of the jejunum 25 to 30 cm distal to the pancreatojejunal (PJ) and hepatojejunal (HJ) anastomosis. Because the concentration of motilin receptors and the velocity of propagation of MMC activity decline from the proximal to the distal small intestine, we hypothesized that the effective stimulation of gastric emptying after PD may be achieved by preserving the gastric antrum and utilizing the proximal end of the first jejunal loop for reconstruction with the gastric antrum, followed by distal Roux-en-y PJ and HJ anastomosis.
In this prospective cohort pilot study, we examined whether the preservation of the gastric antrum with proximal Roux-en-y GJA reduces the incidence of DGE when compared to standard PD using the orthotopic reconstruction technique.
Materials and Methods
Patients and Study Design
Between April 2005 and September 2014, 217 consecutive patients underwent elective PD for benign and malignant periampullary diseases at our institution. Nine of the 217 patients who underwent total pancreatectomy were excluded from the study. Of the 208 patients who were included in the study, 90 were prospectively studied patients who underwent PD with the new technique from June 2011 to September 2014 (group I); the other 118 patients were historical patients who underwent standard PD with orthotopic reconstruction from April 2005 to June 2011 (group II). Data analysis was performed according to a protocol approved by the CHI St. Luke’s–Baylor St. Luke’s Medical Center Institutional Review Board. Results were compared between group I and group II.
Preoperative data included age, sex, American Society of Anesthesiologists (ASA) grade, preoperative serum albumin and total bilirubin levels, and the presence of preoperative biliary drainage, diabetes, and comorbidity (Table 1). Perioperative data included operative time, estimated blood loss, perioperative blood transfusion, type of PD, concomitant procedures including portal vein resection, and presence of biliary infection (Table 1). Postoperative outcomes included overall surgery-related complications other than DGE, serum glucose level, pathologic diagnosis, hospital length of stay, 30-day readmission rate, 90-day mortality rate (Table 2), and the overall incidence of DGE (Table 3).
Postoperative complications were graded by severity according to the classification system adopted for pancreatic surgery, which relies on the type of treatment used for each complication.39 Grade I complications included any deviation from the normal postoperative course not requiring pharmacologic treatment or intervention. Grade II complications required pharmacologic treatment such as blood transfusion or total parenteral nutrition. Grade III complications required interventional treatment without general anesthesia (IIIa) or with general anesthesia (IIIb). Grade IV complications were life-threatening complications that required ICU management. Postoperative pancreatic fistula (POPF) was classified as grade A, B, or C according to the International Study Group on Pancreatic Fistula (ISGPF).40 Grade A was defined as the leakage of fluid with high amylase content that had no clinical impact and that resolved spontaneously with conservative management. Clinically relevant POPF (grades B and C) was defined as the leakage of fluid in association with fever (38 °C), leukocytosis, and the need for therapeutic intervention.
The primary study end point was the rate and grade of DGE. The secondary end points were factors contributing to DGE, hospital length of stay, and readmission rate related to DGE.
Surgical Technique
In all group II patients, standard PD with antrectomy was the procedure of choice. The extent of lymph node dissection was performed according to the underlying disease. In patients with a benign or low-grade malignancy, such as chronic pancreatitis or intraductal papillary mucinous neoplasm, we performed D1 lymph node dissection (i.e., dissection of peripancreatic head lymph nodes). In patients with malignant disease, we performed D2 lymph node dissection (i.e., dissection of lymph nodes along the hepatoduodenal ligament, common hepatic artery, portal caval, and peripyloric region). Dissection of the lymph nodes along the superior mesenteric artery was preserved for tumor involving the uncinate process. After completion of the resection, reconstruction was performed by using the orthotopic approach shown in Fig. 1a, in which the proximal jejunal loop was rotated behind the root of the mesentery and placed within the duodenal bed. After completion of the pancreatojejunal anastomosis (PJA) and hepatojejunal anastomosis (HJA), a hand-sewn, isoperistaltic GJA was performed 25 to 30 cm distal to the HJA in two layers by using 3–0 polydioxanone (PDS) sutures and 4–0 silk sutures (Fig. 1a).
In group I patients who underwent PD with the new technique, the distal antrum was divided about 1 to 2 cm proximal to the pylorus ring, preserving more than 95 % of the stomach. The proximal jejunum was divided approximately 2 to 4 cm distal to the duodeno-jejunal junction. After completion of the resection, the proximal end of the first loop of jejunum was then brought through the transverse mesocolon, and the GJA was performed in two layers by using 3–0 PDS sutures and 4–0 silk sutures in an end-to-side fashion. The jejunum was then divided 35 to 40 cm distal to the GJA, and the distal limb was brought separately through the transverse mesocolon to be placed in the duodenal bed for reconstruction of the PJA and HJA (Fig. 1b). The two loops of jejunum were then anastomosed caudal to the transverse mesocolon by using a gastrointestinal stapling device.
In both groups, the PJA and HJA were completed in a similar fashion, as described previously.41 Briefly, an end-to-side, duct-to-mucosa, two-layer PJA was performed by using interrupted, non-absorbable prolene sutures. Depending on the size of the pancreatic duct, four to six 6–0 prolene sutures were placed within the pancreatic duct before placement of the posterior outer-layer sutures. The posterior outer-layer anastomosis was performed by using a horizontal mattress technique between the whole thickness of the pancreatic remnant and the seromuscular layer of the jejunum with 4–0 or 5–0 prolene sutures. Upon completion of the posterior outer layer, the duct-to-mucosa anastomosis was then completed. In patients with pancreatic duct diameter ≤3 mm, the anastomosis was performed over a 6-cm 5-F internal plastic stent (Kendall Argyle feeding tube, Tyco Healthcare, Mansfield, MA). The anterior outer layer of the anastomosis was then completed between the pancreas and the seromuscular layer of the jejunum by using 5–0 prolene sutures. After completion of the PJA, an end-to-side HJA was performed by using interrupted 5–0 PDS without a stent, approximately 5 to 10 cm distal to the PJA. A feeding jejunostomy tube was not placed. In all cases, two Jackson-Pratt silicon drains were introduced through separate stab incisions and were placed anterior and posterior to the PJA.
All procedures were performed by one senior hepatobiliary and pancreatic surgeon (OB) and assisted by two other senior surgeons (CFO, RPW).
Perioperative Management
Following the procedure, admission to the intensive care unit and length of stay were determined according to the patient’s clinical condition. The nasogastric tube (NGT) was removed on postoperative day 1 or 2, or when the volume of gastric output was less than 500 ml/day. In 10 patients, a nasogastric tube was not inserted. Total parenteral nutrition was used only in patients with grade C DGE or clinically relevant POPF. All patients were placed on proton pump inhibitor. In the majority of cases, erythromycin was administered intravenously at a dose of 250 mg every 6 h, which was converted to an oral formulation once an oral diet was tolerated. Serum amylase and drain-fluid amylase levels were measured on postoperative day 3. Drains were removed sequentially, if no evidence of pancreatic or bile leakage was present. Serum glucose level was maintained within normal limits by using an insulin sliding scale. When patients were clinically well and tolerated a solid diet, they were discharged from the hospital.
Delayed gastric emptying was defined according to the consensus definition proposed by the International Study Group of Pancreatic Surgery (ISGPS), using the web-based calculator (http://pancreasclub.com/calculator/). The severity of DGE was classified into 3 grades (A, B, or C) according to the ISGPS’s clinical criteria, based on the patient’s clinical course and postoperative management, such as the need for NGT in the postoperative period or the inability to tolerate solid oral intake. Grade A was defined as needing the NGT for more than 7 days or reinsertion of the NGT after postoperative day 3, or as being unable to tolerate a solid diet by postoperative day 7. Grade B was defined as needing for NGT for 8 to 14 days after surgery or reinsertion of the NGT after day 7, or as being unable to tolerate a solid diet by postoperative day 14. Grade C was defined as needing the NGT for more than 14 days or reinsertion of the NGT after day 14, or as being unable to tolerate a solid diet by day 21.
If evidence of DGE was present, then upper gastrointestinal contrast radiography was performed, and the time necessary for passage of the oral contrast agent from the esophagogastric junction into the jejunum was measured. Esophagogastroduodenoscopy (EGD) was performed to rule out mechanical obstruction of the GJA. A contrast computed tomography scan was performed if there was clinical evidence of infection contributing to DGE (i.e., fever, leukocytosis, and purulent drainage). Any suspicious intra-abdominal fluid collection that may have indicated an abscess was drained by interventional radiologists. The drainage fluid was sent for culture and amylase content analysis. The drains were removed when the fluid volume was <10 ml/day, the fluid amylase content was <3 times the upper limit of serum amylase, and the fluid collection was completely resolved, as determined by abdominal computed tomography scan.
Data Analysis
Continuous variables were assessed for normality by using the Shapiro-Wilk test. For normally distributed variables, values were expressed as the mean ± standard deviation, and the difference between the two groups was tested by using the Student t test. For abnormally distributed variables, values were expressed as the median (range), and non-parametric tests (i.e., Wilcoxon rank-sum test, Mann-Whitney test) were used to assess the differences between the two groups. For categorical variables, the Pearson chi-square test or Fisher exact test was used for statistical comparison. All statistical tests were two tailed, and a p value of <0.05 was considered significant.
Univariate analysis was performed by using a non-conditional logistic regression model, and data were expressed as an odds ratio for each independent variable (potential risk factors). The odds ratio, 95 % confidence interval, and p value were calculated. Variables with a p value of <0.25 in the univariate analysis were included in the logistic regression model for the multivariate analysis. In the next step, variables with a p value of <0.1 in the multivariate analysis were included in the final logistic regression model. In the final model, a p value <0.05 was considered statistically significant.
Results
Patient characteristics and preoperative data for group I (new technique) and group II (standard technique) patients are shown in Table 1. No significant differences were observed between the two groups with respect to age, sex, ASA grade, presence of comorbidities, or the number of patients who underwent preoperative endoscopic or percutaneous biliary drainage. Similarly, preoperative serum albumin and total bilirubin levels were comparable between the two groups. However, more patients in group I presented with preoperative diabetes than in group II (36.7 vs. 28.0 %, respectively; p = 0.045).
Intraoperative data for group I and group II patients are shown in Table 1. Data from both groups are comparable with respect to estimated amount of blood loss, blood transfusion, type of PD, concomitant procedures, and the rate of biliary infection. However, the median operative time was significantly longer in group II than in group I (p < 0.001).
Postoperative outcomes of group I and group II patients are shown in Table 2. Of the 208 patients, 6 (2.9 %) died within 90 days after PD. No significant difference was observed in the mortality rate between the two groups. Similarly, no significant difference was seen between the two groups in regard to the underlying disease or the 30-day readmission rate. However, the overall median postoperative length of hospital stay was significantly shorter in group I than in group II (p < 0.001). Similarly, the median blood glucose level was significantly lower in group I than in group II patients (p < 0.001). Ninety-one patients (43.8 %) developed one or more complications other than DGE. The incidence of postoperative complications other than DGE was significantly lower in group I than in group II (p = 0.03; Tables 2 and 3).
Delayed Gastric Emptying
Six patients who died in the immediate postoperative period were excluded from the analysis because the cause of death was not related to DGE. Overall, 74/202 patients (36.7 %) developed DGE according to the ISGPS criteria (Table 4). The majority of patients had grade A (44/202; 21.8 %); 21 patients (10.4 %) had grade B, and 9 patients (4.5 %) had grade C DGE. The incidence of DGE was significantly lower in group I than in group II patients (p < 0.001). A total of 9 patients in group I (10.2 %) developed DGE, whereas 65 patients (57.0 %) in group II developed DGE. Significantly fewer patients in group I developed grade A, B, and C DGE than did patients in group II. In fact, none of the patients in group I had grade C DGE, whereas 9 patients (7.9 %) in group II did.
Compared to group II patients, group I patients had significantly shorter times to removal of the NGT and to starting a solid diet after surgery. However, no significant difference was observed between groups in the reinsertion rate of the NGT or in the 30-day readmission rate as a result of DGE. On the other hand, significantly more patients in group I than in group II received prophylactic intravenous erythromycin as a prokinetic agent. To determine the influence of erythromycin on the occurrence of DGE, we performed a subset analysis between patients with or without DGE. Although more patients with DGE received intravenous erythromycin than did patients without DGE, the difference was not statistically different (p = 0.69; Table 5).
In a separate analysis, other postoperative complications were excluded that may have affected the length of NGT placement and the patients’ tolerance of solid food, such as prolonged intubation, abdominal sepsis, and prolonged NPO for POPF. According to the ISGPS criteria, 47 patients (23.3 %) developed primary DGE. The rate of primary DGE was significantly lower in group I than in group II patients (8.0 vs. 35.1 %, respectively; p < 0.001). Furthermore, more patients in group II than in group I developed clinically relevant DGE (i.e., grades B and C). One patient in group I developed grade B DGE, whereas in group II, 6 patients developed grade B DGE and 4 patients developed grade C DGE (Table 4).
Univariate analysis of factors that may result in DGE revealed that older age, preoperative comorbidities, ASA grade 4, standard orthotopic technique, operative time, perioperative serum glucose level, and rate of complications including POPF were significant factors that influence the incidence of DGE. Variables with a p value <0.25 in the univariate analysis were included in the logistic regression model for the multivariate analysis. The multivariate analysis revealed that age, standard orthotopic technique, and postoperative rate of complications including POPF are independent risk factors for DGE (Table 6). The highest odds ratio was observed for the orthotopic standard technique (odds ratio = 8.5).
Discussion
We conducted a prospective cohort pilot study to evaluate the efficacy of preserving the gastric antrum with proximal Roux-en-y GJA in reducing the incidence of DGE after PD. In a group of 202 patients who underwent elective PD, we found that the rate of DGE and the length of hospital stay related to DGE were significantly lower in group I patients who underwent PD with the new technique than in group II patients who underwent PD with the standard orthotopic technique. In addition, more group II patients developed clinically relevant DGE (i.e., grades B and C), whereas only 2 patients (2.3 %) in group I developed grade B DGE, and no patients developed grade C DGE. Both patients in group I with grade B DGE developed intra-abdominal abscesses that contributed to generalized ileus and DGE.
The rates of overall and clinically relevant DGE in group II patients (57.0 and 24.6 %, respectively) were comparable to those observed in other studies.1–19,33,42,43 However, in patients treated with our new approach, the rates of overall and clinically relevant DGE were significantly reduced in comparison (10.2 and 2.3 %, respectively; p < 0.001). This could be interpreted as a result of the decreased complication rate seen in group I compared to group II patients, which corresponds to the decreased rate of POPF seen after June 2007, as shown previously.41 However, this improvement in the incidence of DGE also pertained to the rate of primary DGE when excluding postoperative complications other than DGE that influenced the length of NGT placement and the patients’ tolerance of solid food. Our findings corroborate those of a prospective, randomized, controlled study that reported a significant reduction in the incidence of overall and clinically relevant DGE in patients who underwent pylorus-resection PD with preservation of more than 95 % of the stomach when compared with patients who underwent pylorus-preserving PD (4.5 vs. 17.2 %, and 3 vs. 7.8 %, respectively).33 However, more patients in that study developed grade B and C DGE than in our study, as all of those patients underwent standard reconstruction of the GJA by using the antecolic approach.
We also found that the length of hospital stay as a result of DGE was longer in group II than in group I. Although an inverse relationship between length of hospital stay and readmission rate has been proposed,44,45 we observed no significant difference between groups in the 30-day readmission rate.
In various studies, several risk factors for DGE have been identified in univariate and multivariate analyses.43,46–49 In the present study, the results of our univariate analysis corroborated the findings of these studies. We found that the median operative time was longer in group II than in group I, despite an additional anastomosis that was performed in group I patients. The reason for this is not clear, given that the procedures differ only in the reconstruction technique, and all procedures were performed by three senior surgeons with more than 35 years of combined experience in hepatobiliary and pancreatic surgery. Although the length of the procedure was a predictor of DGE in univariate analysis, this was not confirmed in multivariate analysis. Additionally, we found that perioperative blood sugar was better controlled in group I than in group II. This may be attributed to a higher incidence of complications in group II than in group I. Although perioperative blood sugar level was a predictor for DGE in our univariate analysis, this was not confirmed in multivariate analysis. Our multivariate regression analysis showed that older age, severe postoperative complications including clinically relevant POPF, and standard orthotopic technique are independent risk factors for DGE. However, among the risk factors identified, the highest odds ratio was observed in the patients who underwent the standard technique.
Although self-limiting and non-fatal, the development of clinically relevant DGE leads to significant deviation from the normal clinical pathway and contributes significantly to the deterioration of the patient’s quality of life in the immediate postoperative period. Whereas primary DGE is caused by disruption of the neurohumoral pathway, several studies have shown that intra-abdominal complications and angulation and torsion of the gastrojejunostomy/duodenojejunostomy anastomosis are a possible cause of secondary DGE (54–59). In 1978, PpPD was developed by Traverso and Longmire37 to increase gastric volume and reduce complications related to gastric stasis and dumping syndrome. However, DGE still occurs in 30 to 50 % of patients who undergo PpPD.17,35 The mechanism for DGE after PpPD has been suggested to be multifactorial, including vascular and neural injury to the anteropyloric muscle,31,32 angulation of the duodenojejunostomy,50 and gastric atony after removal of the duodenum with diminished circulating motilin hormone.29
Despite numerous reports of case control and randomized controlled studies examining the antecolic vs. retrocolic route to the reconstruction of the gastrojejunal/duodenojejunal anastomosis, there is no consensus regarding which is the procedure of choice after PD.10,16,34,51–53 In all of these studies, regardless of the type of reconstruction (Billroth I or Billroth II), a lower incidence of DGE was observed in procedures that allowed for the straight passage of the gastric content under gravity into the jejunum. Although the use of Roux limbs after PD has been previously studied, our technique is unique in that we used the proximal 35–40 cm of the jejunum brought through the transverse mesocolon as an isolated Roux limb. This improved gastric emptying by providing a straight route for the gastric content to pass into the jejunum under gravity, avoiding the angulation or torsion of the GJA that has been previously reported in Billroth I retrocolic reconstruction.53
As stated above, motilin and its receptors play a significant role in regulating phase III of the MMC at the end of the postprandial period. Several studies have shown that resection of the duodenum after PpPD reduces the cyclic surge in plasma motilin levels, creating slow recovery of phase III with low amplitude in the efferent limb and slow propagation of the MMC downstream of the small intestine.38,54 Therefore, preserving the gastric antrum and using the proximal limb of the jejunum, which has a higher concentration of motilin receptors than does the distal limb, to reconstruct the GJA maximizes the utilization of motilin receptors in response to the transit of stomach content. This may, in part, compensate for the loss of duodenal secretions.
Erythromycin, a macrolide antibiotic, and derivatives of erythromycin have been shown to induce gastric phase III of the MMC in humans and dogs.55,56 Acting as a motilin agonist, it binds to motilin receptors. During the last two decades, the effects of erythromycin on gastrointestinal motility in gastrectomized patients have been studied extensively. A prospective, randomized, placebo-controlled, double-blinded study showed that erythromycin significantly improved gastric emptying in patients after PD.19 In the present study, we did not observe a significant effect of erythromycin on the incidence of DGE because more patients with DGE received erythromycin than did patients without DGE. However, the difference was not statistically significant (p = 0.69).
The drawbacks of this technique are the additional anastomosis required to establish continuity of the two loops of jejunum, which may negatively affect intestinal motility, and the difficulty of approaching the HJA endoscopically, if warranted. However, in our group I patients, we did not encounter any complications related to an additional jejunal anastomosis or the need for endoscopic examination of the HJA. In addition, a major limitation of this study is that it is a prospective cohort pilot study with potential type I error. To validate the results of this pilot study, we plan to conduct a randomized, controlled study.
In conclusion, we have demonstrated that the preservation of the gastric antrum with proximal Roux-en-y GJA after PD reduces the incidence of overall and clinically significant DGE, as well as the ensuing length of hospital stay. Notably, this effect was also observed in the subset of patients with primary DGE. Although this new approach dramatically reduced the incidence of DGE, it did not eliminate DGE completely, most likely because of the complexity of the procedure and the multiplicity of factors that are involved.
References
Balcom JH, Rattner DW, Warshaw AL, Chang Y, Fernandez-del Castillo C: Ten-year experience with 733 pancreatic resections: changing indications, older patients, and decreasing length of hospitalization. Arch Surg 2001;136:391–398.
Bassi C, Falconi M, Molinari E, Salvia R, Butturini G, Sartori N, Mantovani W, Pederzoli P: Reconstruction by pancreaticojejunostomy versus pancreaticogastrostomy following pancreatectomy: results of a comparative study. Ann Surg 2005;242:767–771, discussion 771–763.
Buchler MW, Wagner M, Schmied BM, Uhl W, Friess H, Z’Graggen K: Changes in morbidity after pancreatic resection: toward the end of completion pancreatectomy. Arch Surg 2003;138:1310–1314; discussion 1315.
Fabre JM, Burgel JS, Navarro F, Boccarat G, Lemoine C, Domergue J: Delayed gastric emptying after pancreaticoduodenectomy and pancreaticogastrostomy. Eur J Surg 1999;165:560–565.
Goei TH, van Berge Henegouwen MI, Slooff MJ, van Gulik TM, Gouma DJ, Eddes EH: Pylorus-preserving pancreatoduodenectomy: influence of a Billroth I versus a Billroth II type of reconstruction on gastric emptying. Dig Surg 2001;18:376–380.
Hashimoto Y, Traverso LW: Incidence of pancreatic anastomotic failure and delayed gastric emptying after pancreatoduodenectomy in 507 consecutive patients: use of a web-based calculator to improve homogeneity of definition. Surgery 2010;147:503–515.
Horstmann O, Markus PM, Ghadimi MB, Becker H: Pylorus preservation has no impact on delayed gastric emptying after pancreatic head resection. Pancreas 2004;28:69–74.
Jimenez RE, Fernandez-del Castillo C, Rattner DW, Chang Y, Warshaw AL: Outcome of pancreaticoduodenectomy with pylorus preservation or with antrectomy in the treatment of chronic pancreatitis. Ann Surg 2000;231:293–300.
Kollmar O, Sperling J, Moussavian MR, Kubulus D, Richter S, Schilling MK: Delayed gastric emptying after pancreaticoduodenectomy: influence of the orthotopic technique of reconstruction and intestinal motilin receptor expression. J Gastrointest Surg 2011;15:1158–1167.
Murakami Y, Uemura K, Sudo T, Hayashidani Y, Hashimoto Y, Nakagawa N, Ohge H, Sueda T: An antecolic Roux-en Y type reconstruction decreased delayed gastric emptying after pylorus-preserving pancreatoduodenectomy. J Gastrointest Surg 2008;12:1081–1086.
Niedergethmann M, Shang E, Farag Soliman M, Saar J, Berisha S, Willeke F, Post S: Early and enduring nutritional and functional results of pylorus preservation vs classic Whipple procedure for pancreatic cancer. Langenbecks Arch Surg 2006;391:195–202.
Nikfarjam M, Kimchi ET, Gusani NJ, Shah SM, Sehmbey M, Shereef S, Staveley-O’Carroll KF: A reduction in delayed gastric emptying by classic pancreaticoduodenectomy with an antecolic gastrojejunal anastomosis and a retrogastric omental patch. J Gastrointest Surg 2009;13:1674–1682.
Park JS, Hwang HK, Kim JK, Cho SI, Yoon DS, Lee WJ, Chi HS: Clinical validation and risk factors for delayed gastric emptying based on the International Study Group of Pancreatic Surgery (ISGPS) Classification. Surgery 2009;146:882–887.
Patel AG, Toyama MT, Kusske AM, Alexander P, Ashley SW, Reber HA: Pylorus-preserving Whipple resection for pancreatic cancer. Is it any better? Arch Surg 1995;130:838–842; discussion 842–833.
Reid-Lombardo KM, Farnell MB, Crippa S, Barnett M, Maupin G, Bassi C, Traverso LW, Pancreatic Anastomotic Leak Study G: Pancreatic anastomotic leakage after pancreaticoduodenectomy in 1,507 patients: a report from the Pancreatic Anastomotic Leak Study Group. J Gastrointest Surg 2007;11:1451–1458; discussion 1459
Tani M, Terasawa H, Kawai M, Ina S, Hirono S, Uchiyama K, Yamaue H: Improvement of delayed gastric emptying in pylorus-preserving pancreaticoduodenectomy: results of a prospective, randomized, controlled trial. Ann Surg 2006;243:316–320.
Tran KT, Smeenk HG, van Eijck CH, Kazemier G, Hop WC, Greve JW, Terpstra OT, Zijlstra JA, Klinkert P, Jeekel H: Pylorus preserving pancreaticoduodenectomy versus standard Whipple procedure: a prospective, randomized, multicenter analysis of 170 patients with pancreatic and periampullary tumors. Ann Surg 2004;240:738–745.
van Berge Henegouwen MI, van Gulik TM, DeWit LT, Allema JH, Rauws EA, Obertop H, Gouma DJ: Delayed gastric emptying after standard pancreaticoduodenectomy versus pylorus-preserving pancreaticoduodenectomy: an analysis of 200 consecutive patients. J Am Coll Surg 1997;185:373–379.
Yeo CJ, Barry MK, Sauter PK, Sostre S, Lillemoe KD, Pitt HA, Cameron JL: Erythromycin accelerates gastric emptying after pancreaticoduodenectomy. A prospective, randomized, placebo-controlled trial. Ann Surg 1993;218:229–237; discussion 237–228.
Ehrlein HJ, Schemann M. Gastrointestinal Motility. Technische Universitat Munchen, Munich, Germany. 2005. http://humanbiology.wzw.tum.de/motvid01/tutorial.pdf. Accessed August 6 2015.
Hansen MB: Neurohumoral control of gastrointestinal motility. Physiol Res 2003;52:1–30.
Itoh Z, Aizawa I, Takeuchi S, Takayanagi R: Diurnal changes in gastric motor activity in conscious dogs. Am J Dig Dis 1977;22:117–124.
Poitras S, Brosseau L: Evidence-informed management of chronic low back pain with transcutaneous electrical nerve stimulation, interferential current, electrical muscle stimulation, ultrasound, and thermotherapy. Spine J 2008;8:226–233.
Miller P, Roy A, St-Pierre S, Dagenais M, Lapointe R, Poitras P: Motilin receptors in the human antrum. Am J Physiol Gastrointest Liver Physiol 2000;278:G18-23.
Mochiki E, Asao T, Kuwano H: Gastrointestinal motility after digestive surgery. Surg Today 2007;37:1023–1032.
Tanaka M, Sarr MG: Role of the duodenum in the control of canine gastrointestinal motility. Gastroenterology 1988;94:622–629.
Tanaka M, Sarr MG: Effects of exogenous motilin and morphine on interdigestive gastrointestinal motor activity after total duodenectomy in dogs. Surgery 1988;104:317–325.
McLeod RS, Taylor BR, O’Connor BI, Greenberg GR, Jeejeebhoy KN, Royall D, Langer B: Quality of life, nutritional status, and gastrointestinal hormone profile following the Whipple procedure. Am J Surg 1995;169:179–185.
Naritomi G, Tanaka M, Matsunaga H, Yokohata K, Ogawa Y, Chijiiwa K, Yamaguchi K: Pancreatic head resection with and without preservation of the duodenum: different postoperative gastric motility. Surgery 1996;120:831–837.
Peeters T, Matthijs G, Depoortere I, Cachet T, Hoogmartens J, Vantrappen G: Erythromycin is a motilin receptor agonist. Am J Physiol 1989;257:G470-474
Fischer CP, Hong JC: Method of pyloric reconstruction and impact upon delayed gastric emptying and hospital stay after pylorus-preserving pancreaticoduodenectomy. J Gastrointest Surg 2006;10:215–219.
Hayashibe A, Kameyama M, Shinbo M, Makimoto S: The surgical procedure and clinical results of subtotal stomach preserving pancreaticoduodenectomy (SSPPD) in comparison with pylorus preserving pancreaticoduodenectomy (PPPD). J Surg Oncol 2007;95:106–109.
Kawai M, Tani M, Hirono S, Miyazawa M, Shimizu A, Uchiyama K, Yamaue H: Pylorus ring resection reduces delayed gastric emptying in patients undergoing pancreatoduodenectomy: a prospective, randomized, controlled trial of pylorus-resecting versus pylorus-preserving pancreatoduodenectomy. Ann Surg 2011;253:495–501.
Kurahara H, Shinchi H, Maemura K, Mataki Y, Iino S, Sakoda M, Ueno S, Takao S, Natsugoe S: Delayed gastric emptying after pancreatoduodenectomy. J Surg Res 2011;171:e187-192.
Ogata Y, Hishinuma S: The impact of pylorus-preserving pancreatoduodenectomy on surgical treatment for cancer of the pancreatic head. J Hepatobiliary Pancreat Surg 2002;9:223–232.
Ohtsuka T, Tanaka M, Miyazaki K: Gastrointestinal function and quality of life after pylorus-preserving pancreatoduodenectomy. J Hepatobiliary Pancreat Surg 2006;13:218–224.
Traverso LW, Longmire WP, Jr.: Preservation of the pylorus in pancreaticoduodenectomy. Surg Gynecol Obstet 1978;146:959–962.
Pastorino G, Ermili F, Zappatore F, Castagnola M, Fazio S, Ciferri E: Multiparametric evaluation of functional outcome after pylorus-preserving duodenopancreatectomy. Hepatogastroenterology 1995;42:62–67.
Dindo D, Demartines N, Clavien PA: Classification of surgical complications: a new proposal with evaluation in a cohort of 6336 patients and results of a survey. Ann Surg 2004;240:205–213.
Bassi C, Dervenis C, Butturini G, Fingerhut A, Yeo C, Izbicki J, Neoptolemos J, Sarr M, Traverso W, Buchler M, International Study Group on Pancreatic Fistula D: Postoperative pancreatic fistula: an international study group (ISGPF) definition. Surgery 2005;138:8–13
Barakat O, Ozaki CF, Wood RP: Topically applied 2-octyl cyanoacrylate (Dermabond) for prevention of postoperative pancreatic fistula after pancreaticoduodenectomy. J Gastrointest Surg 2012;16:1499–1507.
Kunstman JW, Fonseca AL, Ciarleglio MM, Cong X, Hochberg A, Salem RR: Comprehensive analysis of variables affecting delayed gastric emptying following pancreaticoduodenectomy. J Gastrointest Surg 2012;16:1354–1361.
Welsch T, Borm M, Degrate L, Hinz U, Buchler MW, Wente MN: Evaluation of the International Study Group of Pancreatic Surgery definition of delayed gastric emptying after pancreatoduodenectomy in a high-volume centre. Br J Surg 2010;97:1043–1050
Fong ZV, Ferrone CR, Thayer SP, Wargo JA, Sahora K, Seefeld KJ, Warshaw AL, Lillemoe KD, Hutter MM, Fernandez-Del Castillo C: Understanding hospital readmissions after pancreaticoduodenectomy: can we prevent them?: a 10-year contemporary experience with 1,173 patients at the Massachusetts General Hospital. J Gastrointest Surg 2014;18:137–144; discussion 144–135
Sadot E, Brennan MF, Lee SY, Allen PJ, Gonen M, Groeger JS, Peter Kingham T, D’Angelica MI, DeMatteo RP, Jarnagin WR, Fong Y: Readmission after pancreatic resection: causes and causality pattern. Ann Surg Oncol 2014;21:4342–4350.
Lermite E, Pessaux P, Brehant O, Teyssedou C, Pelletier I, Etienne S, Arnaud JP: Risk factors of pancreatic fistula and delayed gastric emptying after pancreaticoduodenectomy with pancreaticogastrostomy. J Am Coll Surg 2007;204:588–596.
Liberski SM, Koch KL, Atnip RG, Stern RM: Ischemic gastroparesis: resolution after revascularization. Gastroenterology 1990;99:252–257.
Murakami H, Suzuki H, Nakamura T: Pancreatic fibrosis correlates with delayed gastric emptying after pylorus-preserving pancreaticoduodenectomy with pancreaticogastrostomy. Ann Surg 2002;235:240–245.
Park YC, Kim SW, Jang JY, Ahn YJ, Park YH: Factors influencing delayed gastric emptying after pylorus-preserving pancreatoduodenectomy. J Am Coll Surg 2003;196:859–865.
Itani KM, Coleman RE, Meyers WC, Akwari OE: Pylorus-preserving pancreatoduodenectomy. A clinical and physiologic appraisal. Ann Surg 1986;204:655–664.
Chijiiwa K, Imamura N, Ohuchida J, Hiyoshi M, Nagano M, Otani K, Kai M, Kondo K: Prospective randomized controlled study of gastric emptying assessed by (13)C-acetate breath test after pylorus-preserving pancreaticoduodenectomy: comparison between antecolic and vertical retrocolic duodenojejunostomy. J Hepatobiliary Pancreat Surg 2009;16:49–55.
Gangavatiker R, Pal S, Javed A, Dash NR, Sahni P, Chattopadhyay TK: Effect of antecolic or retrocolic reconstruction of the gastro/duodenojejunostomy on delayed gastric emptying after pancreaticoduodenectomy: a randomized controlled trial. J Gastrointest Surg 2011;15:843–852.
Ueno T, Takashima M, Iida M, Yoshida S, Suzuki N, Oka M: Improvement of early delayed gastric emptying in patients with Billroth I type of reconstruction after pylorus preserving pancreatoduodenectomy. J Hepatobiliary Pancreat Surg 2009;16:300–304.
Tanaka M, Sarr MG: Total duodenectomy: effect on canine gastrointestinal motility. J Surg Res 1987;42:483–493.
Itoh Z, Nakaya M, Suzuki T, Arai H, Wakabayashi K: Erythromycin mimics exogenous motilin in gastrointestinal contractile activity in the dog. Am J Physiol 1984;247:G688-694.
Tomomasa T, Kuroume T, Arai H, Wakabayashi K, Itoh Z: Erythromycin induces migrating motor complex in human gastrointestinal tract. Dig Dis Sci 1986;31:157–161.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Barakat, O., Cagigas, M.N., Bozorgui, S. et al. Proximal Roux-en-y Gastrojejunal Anastomosis with Pyloric Ring Resection Improves Gastric Emptying After Pancreaticoduodenectomy. J Gastrointest Surg 20, 914–923 (2016). https://doi.org/10.1007/s11605-016-3091-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11605-016-3091-5