Abstract
Background
Minimally-invasive pancreatoduodenectomy (MIPD) is fraught with the risk of complication-related deaths (LEOPARD-2), a significant volume-outcome relationship and a long learning curve. With rates of conversion for MIPD approaching 40%, the impact of these on overall patient outcomes, especially, when unplanned, are yet to be fully elucidated. This study aimed to compare peri-operative outcomes of (unplanned) converted MIPD against both successfully completed MIPD and upfront open PD.
Methods
A systematic review of major reference databases was undertaken. The primary outcome of interest was 30-day mortality. Newcastle–Ottawa scale was used to judge the quality of the studies. Meta-analysis was performed using pooled estimates, derived using random effects model.
Results
Six studies involving 20,267 patients were included in the review. Pooled analysis demonstrated (unplanned) converted MIPD were associated with an increased 30-day (RR 2.83, CI 1.62- 4.93, p = 0.0002, I2 = 0%) and 90-day (RR 1.81, CI 1.16- 2.82, p = 0.009, I2 = 28%) mortality and overall morbidity (RR 1.41, CI 1.09; 1.82, p = 0.0087, I2 = 82%) compared to successfully completed MIPD. Patients undergoing (unplanned) converted MIPD experienced significantly higher 30-day mortality (RR 3.97, CI 2.07; 7.65, p < 0.0001, I2 = 0%), pancreatic fistula (RR 1.65, CI 1.22- 2.23, p = 0.001, I2 = 0%) and re-exploration rates (RR 1.96, CI 1.17- 3.28, p = 0.01, I2 = 37%) compared upfront open PD.
Conclusions
Patient outcomes are significantly compromised following unplanned intraoperative conversions of MIPD when compared to successfully completed MIPD and upfront open PD. These findings stress the need for objective evidence-based guidelines for patient selection for MIPD.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The adoption of MIPD into the pancreatic surgical armamentarium has been cautious owing to an appreciation of the technical challenges, high morbidity, pronounced volume-outcome relationship and long learning curves [1,2,3]. The initial randomized controlled data supporting feasibility of MIPD were from high-volume centres [4, 5] with considerable experience in minimally-invasive surgery. The largest study (MITG-P-CPAM) [6] has shown a marginal, though statistically significant, benefit in terms of post-operative length of hospitalization (15 vs. 16 days). In general, studies comparing MIPD to open PD [7, 8] demonstrate longer operative duration for MIPD with a reduced intraoperative blood loss and comparable post-operative morbidity and mortality. The Dutch multi-centre LEOPARD-2 trial [9] was the first ‘real world’ data to emerge in MIPD. The trial was prematurely terminated owing to increased complication-related 90-day mortality in the MIPD arm (10% vs. 2%) on interim analysis. It paved the way for introspection around the role of MIPD and the need for a systematic approach to the training of surgeons, as well as the uptake of MIPD in a controlled environment to obviate the risk of inadvertent harm to patients.
Not all PDs are equal [10]! MIPDs are fraught with an additional layer of complexity when compared to open PD, namely, the risk of conversion. The rates of this event have been reported to approach 40% [11]. Despite a previous nationwide training programme in LPD [12], the conversion rate during the LEOPARD-2 trial was 20% [9]. Experience from minimally-invasive colorectal [13] and liver [14] resections suggest that an unplanned intraoperative conversion not only nullifies the benefits afforded by minimally-invasive surgery, but may also worsen surgical outcomes. The impact of unplanned intraoperative conversions during MIPD on overall patient outcomes is yet to be fully elucidated [15]. This study aimed to compare peri-operative outcomes of (unplanned) converted MIPD versus successfully completed MIPD and upfront open PD.
Study methodology
Search strategy
Major databases (Medline, Google Scholar and Cochrane Library) were comprehensively searched to identify all relevant studies published between January 2000 and December 2022 using the MeSH keywords provided in Supplementary table 1.
The review was registered with PROSPERO (CRD42022355044) and performed in strict adherence to the PRISMA 2020 guidelines [16] (Fig. 1).
Inclusion Criteria
Studies fulfilling the following PICOS criteria were deemed eligible for inclusion in the systematic review:
-
P (Population): Patients undergoing MIPD (LPD or RPD)
-
I (Intervention of interest): Intra-operative Conversion ((unplanned) converted MIPD). Conversion was defined as any resection starting with a laparoscopic or robotic approach, but requiring either laparotomy or hand assistance for reasons other than trocar placement or specimen extraction
-
C (Comparator):
-
Comparator I: successfully completed MIPD
-
Comparator II: upfront open PD
-
-
O (Outcomes):reported only by Beane et
-
S (Study design): Observational, comparative studies
Exclusion criteria
-
Studies without a comparative analysis
-
Hybrid PD
-
Outcomes of interest not reported
-
Studies including extended resections (extended PD and/or extended total pancreatectomy)
-
Studies on palliative treatments
-
Inability to extract relevant data from published results
-
Non-English language studies
Data extraction and quality assessment
Two authors (MK and MMW) independently extracted relevant data from the screened full-text articles according to a standardized Cochrane data extraction sheet [21], which included the following: Name of the first author, year of publication, sample size, baseline demographic characteristics (including age, sex, BMI), ASA grade, intra-operative characteristics including type of MIPD- laparoscopic or robotic or hybrid, operative duration, blood loss, transfusion requirements and markers of oncologic adequacy including R0 resection rates and lymph nodal harvest, post-operative outcomes such as CR-POPF, DGE, PPH, overall and major (≥ CD 3) complications, medical complications including cardiac (myocardial infarction, cardiac arrest), pulmonary (re-intubation rates, need for ventilator support > 48 h, pneumonia) and AKI, UTI, VTE including DVT and PE, sepsis, SSI, need for post-operative PCD, LoS, readmissions, 30-day mortality and costs. The authors (MK and MMW) independently judged the quality of the studies using the NOS [22]. Any disagreement was resolved through mutual discussion, and the accuracy of the extracted data was adjudicated further by the senior author (SGB).
Data synthesis and analysis
The meta-analysis was run through ‘meta’ package in R software, version 4.2.3 (R Core Team, 2023) [23]. Outcomes expressed as median and inter-quartile range were converted to mean and standard deviation for pooled analysis [24]. The pooled effect size of converted versus completed and converted versus open on outcome was estimated using a random-effects model to account for both within-study and between-study variation and provides a more conservative estimate of the overall effect size. RR and associated 95% confidence intervals were calculated for dichotomous data by Mantel–Haenszel models, while SMD and associated 95% confidence intervals were calculated for continuous data using inverse-variance methods by restricted maximum-likelihood estimation process. Statistical heterogeneity among the included studies was assessed using I2, with an I2 of 0–30, 30–60, 50–70, and > 75% representing low, moderate, substantial, and considerable heterogeneity, respectively. The two-sided test was performed for all analyses, 95% confidence interval reported, and level of significance was set at 0.05. Publication bias was assessed using funnel plots and Egger’s test.
Results
Baseline demographics
Six retrospective cohort studies (four from the United States [25,26,27,28], one from Korea [29] and one multi-national European study [30]) including a total of 20,267 patients, published between 2017 and 2022 were suitable for inclusion (Table 1). While 4 studies [25,26,27,28] were registry-based, Lof et al.[30] included medium (10–19 MIPD per year) and high (> 0 MIPD per year) volume centres in their study, and Connie et al. [29] conducted a single-centre study. The latter [29] included only LPD cases, whilst the other studies [25,26,27,28, 30] included both LPD and RPD. Four studies compared all 3 cohorts, namely, (unplanned) converted MIPD, successfully completed MIPD and upfront open PD [25, 27,28,29]. The remaining 2 studies [26, 30] compared only successfully completed MIPD to (unplanned) converted MIPD. Beane et al. [25], Hester et al. [26] and Lof et al. [30] performed propensity matched analysis between successfully completed versus (unplanned) converted MIPD, whereas Stiles et al.[27] performed a propensity matched analysis between (unplanned) converted MIPD and open PD cohort. For this review, total cohorts were selected from Beane et al. [25], Lof et al. [30], and Stiles et al. [27] with the propensity matched cohorts taken from Hester et al. [26]. Conversion rates ranged between 9.2 and 25.2%, with higher rates being noted in registry-based studies. There were no differences in age or BMI between groups. While Villano et al. [28] included patients with malignancy alone, the percentage of patients undergoing PD for malignancy ranged from 55–92% in other studies. There was no significant difference between the groups in terms of the use of neoadjuvant chemotherapy. (Unplanned) converted MIPD were associated with significantly longer operative duration compared to successfully completed MIPD [27] and upfront open PD [27, 29]. Conversion was associated with a increased median intraoperative blood loss (500 vs. 275 ml; p = 0.005), and rate of blood transfusions (17.2 Vs. 42.2%; p < 0.01) [25, 30]. In studies that reported the outcome, conversion did not impact lymph node harvest [29], though patients who underwent an (unplanned) converted MIPD had lower rates of R0 resection compared to successfully completed MIPD and upfront open PD (71.9% vs. 77.8% vs. 77.7% p = 0.004) [28] (Table 2).
Risk of bias and quality assessment
Of the included studies, 2 studies [27, 28] received a NOS score of 9 with the remaining 4 studies [25, 26, 29, 30] scoring 8, suggesting a high quality and low risk of bias for all studies (Table 1).
Post-operative outcomes (Table 3)
(Unplanned) converted versus successfully completed MIPD
Beane et al. [25] (8.3 vs. 2.8%, p = 0.01) and Lof et al.(10 vs. 3.1%, p = 0.01) found that 30-day mortality was significantly higher in the (unplanned) converted group, though Lof et al. [30] could not establish any significant association between conversion and mortality in a multivariate logistic regression analysis adjusted for preoperative and intraoperative variables. Two other studies [26, 27] did not find a significant difference in 30-day mortality between the two groups. Pooled analysis (Table 4) showed that the (unplanned) converted MIPD group had significantly higher 30-day mortality (RR 2.83; CI 1.62; 4.93, p = 0.0002, I2 = 0%) in comparison to the successfully completed MIPD (Fig. 2; Supplementary Fig. 1a).
Lof et al. [30] noted a significantly higher 90-day mortality in the converted group (13 vs. 4.9%, p = 0.012). On pooled analysis, the (unplanned) converted MIPD group also had significantly higher 90-day mortality (RR 1.81; CI 1.16; 2.82, p = 0.009, I2 = 28%) compared to the successfully completed MIPD (Fig. 2; Supplementary Fig. 1b).
In comparison to successfully completed MIPD, (unplanned) converted PD had a significantly higher overall morbidity in studies by Stiles et al. (73.3 vs. 38.6%, p < 0.001) and Hester et al. (74.7 vs. 48.2%, p < 0.01). While Hester et al. (67.5 vs. 37.3%, p < 0.01) also reported significantly higher rates of major (≥ CD3) complications in the (unplanned) converted cohort, there was no difference in the study by Lof et al. (32 vs. 27.7%; p = 0.43). Of the 4 studies [25] [26, 27, 30] that compared CR-POPF rates between (unplanned) converted and successfully completed MIPD, significantly higher rates of CR-POPF in the (unplanned) converted group was reported only by Beane et al. [25] (20.8 vs. 12.1%, p = 0.02). While no study reported any significant difference in the DGE rates [25] [26, 27, 30] between the 2 groups, Hester et al. [26] found higher rates of PPH in the (unplanned) converted group (43.4 vs. 13.3% p < 0.01). Significantly longer hospitalisation was reported by 4 studies [25,26,27,28] in the (unplanned) converted group. Beane et al. [25] reported higher re-exploration rates (10.4 vs. 7.7%, p = 0.03) in patients who underwent an (unplanned) conversion, but there was no difference in the other 3 studies [26, 27, 30]. On the contrary, Beane et al. [25] found significantly higher readmission rates in patients who underwent a successfully completed MIPD (24.2 vs. 14.6%, p < 0.01), while there was no difference in the other 4 studies [26,27,28, 30]. Pooled analysis revealed significantly higher overall morbidity (RR 1.41, CI 1.09; 1.82, p = 0.0087, I2 = 0.0087) in the (unplanned) conversion group (Fig. 2; Supplementary Fig. 1c), while there was no significant difference in CR-POPF, DGE, re-exploration, re-admission or LoS (Table 4) (Supplementary Fig. 1d–h).
Significantly higher rates of respiratory complications (pneumonia, need for re-intubation and > 48 h of ventilator dependence) were noted in the (unplanned) conversion group, while there were no significant differences in renal complications or thromboembolic events [25]. Patients in the (unplanned) conversion group also experienced higher incidence of sepsis including SSIs [25, 26] (Supplementary Table 2).
(Unplanned) converted MIPD versus upfront open PD
Of the 3 studies [25, 27, 29] comparing 30-day mortality between (unplanned) converted and upfront open PD, only Beane et al. [25] reported a significantly higher mortality in the former (8.3 vs. 2.1%. p = 0.01). Meta-analysis revealed a significantly higher 30-day mortality in the (unplanned) converted group (RR 3.97, CI 2.07; 7.65, p < 0.0001, I2 = 0%) (Supplementary Fig. 2a) (Table 4). In the 2 studies [28, 29] comparing 90-day mortality between (unplanned) converted MIPD and upfront open PD, Connie et al. [29] had zero event rates, precluding a pooled analysis.
Stiles et al. [27] found no difference in overall complications (73.3 vs. 61.6%, p = 0.104), and 30-day mortality (4.7 vs. 1.2%, p = 0.368) in the (unplanned) conversion compared to the upfront open PD group. Only Beane et al. [25] noted a significant increase in CR-POPF in the (unplanned) converted group (20.8 vs. 11.4%, p = 0.02) compared to the upfront open PD group. All 3 studies [25, 27, 29] found no difference in rates of DGE. Connie et al. [29] reported a significantly higher rate of PPH (12.1 vs. 0.85%, p = 0.008), as well as re-exploration rates (p = 0.01) in the (unplanned) conversion group. While Stiles et al. [27] found a significantly longer LoS in the upfront open group, two other studies reported longer LoS in the (unplanned) conversion group [25, 28]. Pooled analysis revealed significantly higher rates of CR-POPF (RR 1.65, CI 1.22; 2.23, p = 0.0012, I2 = 0%) (Supplementary Fig. 2b) and re-exploration (RR 1.96, CI 1.17; 3.28, p = 0.011, I2 = 37%) (Supplementary Fig. 2d), while there was no difference in DGE and re-admission rates and LoS (Supplementary Fig. 2c, e and f) (Table 4). Connie et al. [29] reported significantly higher costs per patient in the (unplanned) conversion group in comparison to upfront open PD [$21,886.4 ± 10,594.4 vs. $17,168.9 ± 4,973.1; p = 0.018). Assessment using funnel plots and Egger’s test did not reveal significant publication bias in any of the outcomes except LoS (Supplementary Figs. 3a–h and 4a–f).
Predictors of conversion
Male sex [26,27,28,29,30], advanced age [11, 26,27,28,29], ASA grade III-IV [29, 30], smoking [27] and patients who reported recent weight loss [27] had a higher likelihood of unplanned conversion. Hard pancreatic texture was found to be associated with (unplanned) conversion in 2 studies [27, 29]. Another factor found to be more prevalent in patients undergoing conversions was the presence of wider pancreatic ducts [29]. Tumours > 4 cm [30], pancreato-biliary primary [30], and those requiring vascular [27] [26, 30] and/or multi-visceral [26, 30] resection were more likely to necessitate (unplanned) intraoperative conversion. (Unplanned) conversions were also significantly more common following LPD compared to RPD [26,27,28, 30]. Medium volume centres (10–19 MIPD annually) had a higher (unplanned) conversion rate compared to high volume (> 20 MIPD annually) (15.2 vs. 4.1%, p < 0.001) [30]. Only two studies [29, 30] reported indications for intra-operative conversion (Table 5).
Discussion
These data demonstrate that (unplanned) converted MIPD were associated with an increased 30- and 90-day mortality and overall morbidity compared to successfully completed MIPD. Patients undergoing (unplanned) converted MIPD experienced significantly higher 30-day mortality, CR-POPF and re-exploration rates compared upfront open PD.
Observational, case-matched studies on MIPD [31] [32] [33] demonstrate longer operative times, but less operative blood loss and shorter hospitalization in LPD with complication rates and oncological outcomes comparable to OPD. However, registry-based studies [34, 35] have advised caution owing to increased mortality rates after LPD, especially in low-volume centres. The four RCTs [4,5,6, 9] published to date comparing LPD vs. OPD have been unable to demonstrate a clear indication of post-operative morbidity and mortality, as they were likely underpowered to detect these differences. The conversion rates in these trials ranged from 3 to 25%. Unfortunately, since converted patients were predominantly analysed in the laparoscopic group on an “intention-to-treat” basis, the true implications of an intra-operative conversion were not readily evident. The meta-analysis by Zhang et al. [36] comparing LPD vs. open PD highlighted the advantages of LPD in terms of lesser intra-operative blood loss, higher R0 resection rates and lymph node yield, lower perioperative overall morbidity, and shorter length of hospitalization. No difference in survival was noted. In keeping with the IDEAL framework for surgical innovation, all novel interventions should preferably be evaluated against the current standard in a randomized controlled trial (RCT) [37]. And so, an updated meta-analysis of RCTs comparing LPD vs. open PD confirmed a significantly lower blood loss and surgical site infection rate in the LPD cohort, while the approaches were similar with respect to other outcomes [38]. The benefits of MIPD in terms of improvements in optics, surgical instrumentation, and increased access to training [12, 39] have led to an increased interest amongst surgeons to attempt MIPD.
This study presents the most updated appraisal of the literature on the impact of unplanned intra-operative conversions in MIPD acknowledging that they constitute an inherent problem in the learning curve of minimally-invasive surgery. Interestingly, there were no significant differences in the rates of pancreas-specific complications (CR-POPF, DGE), re-explorations rates, or readmissions rates. Though less frequent in comparison to LPD, unplanned conversions in RPD had more significant consequences, which may be attributed to the longer duration in RPD to actually convert to an open procedure with consequently greater blood loss. It could also reflect a problem of selection bias wherein only the most difficult procedures were converted in RPD, whereas LPD procedures were converted more easily [40]. The significantly higher 30-day mortality, CR-POPF and re-exploration rates in the unplanned conversion MIPD cohort compared to the upfront open PD cohort is also intriguing bearing in mind that the data in the present study is from retrospective series, wherein patients for MIPD would have been following a strict selection policy.
Though broadly defined into three phases [41], that is, competency, proficiency, and mastery, there exists little standardization in literature on what constitutes an established definition of a rigorous learning curve required to perform a surgery as complex as MIPD. Criticism of the literature on learning curve studies point out that they are derived from CUSUM analyses [42] based on intra-operative parameters such as operative duration and/ or intra-operative blood loss rather than postoperative outcomes such as complication rates or LoS. Additionally, there exists a significant correlation between study sample sizes and number of procedures needed to surpass the learning curve, questioning the meaningfulness and applicability of these results [43]. It is paramount that future studies investigating the subject take into account not only surgeon (previous surgical [44] and simulation [45] experience, procedure-specific training and clinical fellowships [46]) and patient (BMI [47], comorbidities and tumour factors [10]) characteristics, but institutional expertise as well, which includes annual procedural volumes and team familiarity [48].
Patient selection appears to be of paramount importance in MIPD, given the risks associated with unplanned conversions. The current review highlights patient (elderly, male, smokers, ASA III/ IV, recent history of weight loss), pancreatic gland, and tumour (> 4 cm, pancreato-biliary tumours) characteristics associated with higher risk of intra-operative conversion, that need to be factored in while selecting patients for MIPD. The Miami guidelines state that trainees should have passed the learning curve for open PD (> 60) before undertaking training in MIPD. Centres should be performing at least 50 PD annually in addition to minimum annual volume of 20 MIPDs [1]. This may be operationalized by devising strict national and international surgical society guidelines. Further, utilization of risk prediction scores like Difficulty scoring system (DSS)[49] or PD-ROBOSCORE [50] will likely aid better patient selection for MIPD.
The study is not without limitations. The definition of conversion varied between centres/ studies. Categorization of conversion into elective and emergency in future studies may facilitate rational comparison of outcomes. Secondly, studies might have had surgeons at different stages of learning curve, and a uniform definition of learning curve might enable assessment of the impact of surgeon experience and centre volume on the risk of conversion. Finally, we combined LPD and RPD together due to non-availability of stratified data, though it is obvious that both the approaches differ not only in terms of impact of conversion, but risk factors as well.
As surgical innovations become more complex and the burden of age and comorbidities in the surgical patient population continues to increase, understanding the benefits and risks associated with surgical interventions becomes ever more important. We need to move beyond the traditional endpoints of mortality and resource use towards more pertinent measures of morbidity, patient-reported outcomes, and functional status. At the present time, the implementation of MIPD must be guided by an appreciation of surgeon training and (also institutional) capability and optimum patient selection, as unplanned conversions are fraught with the attendant risk of morbidity and mortality.
Abbreviations
- AKI:
-
Acute kidney injury
- ASA:
-
American Society of Anaesthesiology
- BMI:
-
Body mass index
- CD:
-
Clavien-Dindo
- CR-POPF:
-
Clinically-relevant post-operative pancreatic fistula
- DGE:
-
Delayed gastric emptying
- DVT:
-
Deep vein thrombosis
- LPD:
-
Laparoscopic pancreatoduodenectomy
- MeSH:
-
Medical Education Subject Headings
- MIPD:
-
Minimally-invasive pancreatoduodenectomy
- NOS:
-
Newcastle–Ottawa scale
- PCD:
-
Percutaneous drainage
- PD:
-
Pancreatoduodenectomy
- PE:
-
Pulmonary embolism
- PRISMA:
-
Preferred Reporting Items for Systematic Reviews and Meta-analyses
- PPAP:
-
Post-pancreatectomy acute pancreatitis
- PPH:
-
Post-pancreatectomy haemorrhage
- RPD:
-
Robotic pancreatoduodenectomy
- RR:
-
Risk ratio
- SMD:
-
Standardised mean differences
- SSI:
-
Surgical site infections
- UTI:
-
Urinary tract infection
- VTE:
-
Venous thromboembolism
References
Asbun HJ, Moekotte AL, Vissers FL et al (2020) The miami international evidence-based guidelines on minimally invasive pancreas resection. Ann Surg 271:1–14
Nagakawa Y, Nakata K, Nishino H et al (2022) International expert consensus on precision anatomy for minimally invasive pancreatoduodenectomy: PAM-HBP surgery project. J Hepatobiliary Pancreat Sci 29:124–135
Muller PC, Kuemmerli C, Cizmic A et al (2022) Learning curves in open, laparoscopic, and robotic pancreatic surgery. a systematic Review and proposal of a standardization. Ann Surg Open. 3(1):e111
Palanivelu C, Senthilnathan P, Sabnis SC et al (2017) Randomized clinical trial of laparoscopic versus open pancreatoduodenectomy for periampullary tumours. Br J Surg 104:1443–1450
Poves I, Burdio F, Morato O et al (2018) Comparison of perioperative outcomes between laparoscopic and open approach for pancreatoduodenectomy: the padulap randomized controlled trial. Ann Surg 268:731–739
Wang M, Li D, Chen R et al (2021) Laparoscopic versus open pancreatoduodenectomy for pancreatic or periampullary tumours: a multicentre, open-label, randomised controlled trial. Lancet Gastroenterol Hepatol 6:438–447
Pedziwiatr M, Malczak P, Pisarska M et al (2017) Minimally invasive versus open pancreatoduodenectomy-systematic review and meta-analysis. Langenbecks Arch Surg 402:841–851
Nickel F, Haney CM, Kowalewski KF et al (2020) Laparoscopic versus open pancreaticoduodenectomy: a systematic review and meta-analysis of randomized controlled trials. Ann Surg 271:54–66
van Hilst J, de Rooij T, Bosscha K et al (2019) Laparoscopic versus open pancreatoduodenectomy for pancreatic or periampullary tumours (LEOPARD-2): a multicentre, patient-blinded, randomised controlled phase 2/3 trial. Lancet Gastroenterol Hepatol 4:199–207
Mihaljevic AL, Hackert T, Loos M et al (2021) Not all Whipple procedures are equal: proposal for a classification of pancreatoduodenectomies. Surgery 169:1456–1462
Boggi U, Amorese G, Vistoli F et al (2015) Laparoscopic pancreaticoduodenectomy: a systematic literature review. Surg Endosc 29:9–23
de Rooij T, van Hilst J, Topal B et al (2019) Outcomes of a multicenter training program in laparoscopic pancreatoduodenectomy (LAELAPS-2). Ann Surg 269:344–350
Allaix ME, Furnee EJ, Mistrangelo M et al (2016) Conversion of laparoscopic colorectal resection for cancer: What is the impact on short-term outcomes and survival? World J Gastroenterol 22:8304–8313
Nguyen KT, Gamblin TC, Geller DA (2009) World review of laparoscopic liver resection-2,804 patients. Ann Surg 250:831–841
Palacio J, Sanchez D, Samuels S, et al (2023) Impact of conversion at time of minimally invasive pancreaticoduodenectomy on perioperative and long-term outcomes: review of the national cancer database. Ann Hepatobiliary Pancreat Surg. https://doi.org/10.14701/ahbps.22-101
Page MJ, McKenzie JE, Bossuyt PM et al (2021) The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. Int J Surg 88:105906
Bassi C, Marchegiani G, Dervenis C et al (2017) The 2016 update of the International Study Group (ISGPS) definition and grading of postoperative pancreatic fistula: 11 years after. Surgery 161:584–591
Wente MN, Bassi C, Dervenis C et al (2007) Delayed gastric emptying (DGE) after pancreatic surgery: a suggested definition by the international study group of pancreatic surgery (ISGPS). Surgery 142:761–768
Wente MN, Veit JA, Bassi C et al (2007) Postpancreatectomy hemorrhage (PPH): an International study group of pancreatic surgery (ISGPS) definition. Surgery 142:20–25
Dindo D, Demartines N, Clavien PA (2004) Classification of surgical complications: a new proposal with evaluation in a cohort of 6336 patients and results of a survey. Ann Surg 240:205–213
Higgins JPT, Green S (2011) Cochrane handbook for systematic reviews of interventions version 5.1.0 [updated march 2011]. the cochrane collaboration, 2011.
Wells G, Shea B, O’Connell D, et al (2013) The Newcastle-Ottawa scale (NOS) for assessing the quality of nonrandomised studies in meta-analyses. Ottawa Hospital Research Institute. https://www.ohri.ca/. Accessed 11 July 2023
R Core Team (2023) R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria
Hozo SP, Djulbegovic B, Hozo I (2005) Estimating the mean and variance from the median, range, and the size of a sample. BMC Med Res Methodol 5:13
Beane JD, Pitt HA, Dolejs SC et al (2018) (2017) Assessing the impact of conversion on outcomes of minimally invasive distal pancreatectomy and pancreatoduodenectomy. HPB (Oxford) 20(4):356–363
Hester CA, Nassour I, Christie A et al (2020) Predictors and outcomes of converted minimally invasive pancreaticoduodenectomy: a propensity score matched analysis. Surg Endosc 34:544–550
Stiles ZE, Dickson PV, Deneve JL et al (2018) The impact of unplanned conversion to an open procedure during minimally invasive pancreatectomy. J Surg Res 227:168–177
Villano AM, Ruth K, Castellanos J et al (2023) Discrepancies in survival after conversion to open in minimally invasive pancreatoduodenectomy. Am J Surg 225:728–734
Connie LCK, Hong SS, Kang I et al (2021) Adverse Impact of intraoperative conversion on the postoperative course following laparoscopic pancreaticoduodenectomy. Yonsei Med J 62:836–842
Lof S, Vissers FL, Klompmaker S et al (2021) Risk of conversion to open surgery during robotic and laparoscopic pancreatoduodenectomy and effect on outcomes: international propensity score-matched comparison study. Br J Surg 108:80–87
Asbun HJ, Stauffer JA (2012) Laparoscopic vs. open pancreaticoduodenectomy: overall outcomes and severity of complications using the accordion severity grading system. J Am Coll Surg 215:810–819
Song KB, Kim SC, Hwang DW et al (2015) Matched case-control analysis comparing laparoscopic and open pylorus-preserving pancreaticoduodenectomy in patients with periampullary tumors. Ann Surg 262:146–155
Tee MC, Croome KP, Shubert CR et al (2015) Laparoscopic pancreatoduodenectomy does not completely mitigate increased perioperative risks in elderly patients. HPB (Oxford) 17:909–918
Sharpe SM, Talamonti MS, Wang CE et al (2015) Early national experience with laparoscopic pancreaticoduodenectomy for ductal adenocarcinoma: a comparison of laparoscopic pancreaticoduodenectomy and open pancreaticoduodenectomy from the national cancer data base. J Am Coll Surg 221:175–184
Nussbaum DP, Adam MA, Youngwirth LM et al (2016) Minimally invasive pancreaticoduodenectomy does not improve use or time to initiation of adjuvant chemotherapy for patients with pancreatic adenocarcinoma. Ann Surg Oncol 23:1026–1033
Zhang H, Lan X, Peng B et al (2019) Is total laparoscopic pancreaticoduodenectomy superior to open procedure? a meta-analysis. World J Gastroenterol 25:5711–5731
Hirst A, Philippou Y, Blazeby J et al (2019) No surgical innovation without evaluation: evolution and further development of the ideal framework and recommendations. Ann Surg 269:211–220
Sattari SA, Sattari AR, Makary MA et al (2022) laparoscopic versus open pancreatoduodenectomy in patients with periampullary tumors: a systematic review and meta-analysis. Ann Surg 277(5):742–755
Zwart MJW, Nota CLM, de Rooij T et al (2022) Outcomes of a multicenter training program in robotic pancreatoduodenectomy (LAELAPS-3). Ann Surg 276:e886–e895
Magge D, Zenati M, Lutfi W et al (2018) Robotic pancreatoduodenectomy at an experienced institution is not associated with an increased risk of post-pancreatic hemorrhage. HPB (Oxford) 20:448–455
Wehrtmann FS, de la Garza JR, Kowalewski KF et al (2020) Learning curves of laparoscopic roux-en-y gastric bypass and sleeve gastrectomy in bariatric surgery: a systematic review and introduction of a standardization. Obes Surg 30:640–656
Chang WR, McLean IP (2006) CUSUM: a tool for early feedback about performance? BMC Med Res Methodol 6:8
Muller PC, Breuer E, Nickel F et al (2022) Robotic distal pancreatectomy, a novel standard of care benchmark values for surgical outcomes from 16 international expert centers. Ann Surg 1:10–1097
Nagakawa Y, Nakamura Y, Honda G et al (2018) Learning curve and surgical factors influencing the surgical outcomes during the initial experience with laparoscopic pancreaticoduodenectomy. J Hepatobiliary Pancreat Sci 25:498–507
Mark Knab L, Zenati MS, Khodakov A et al (2018) Evolution of a novel robotic training curriculum in a complex general surgical oncology fellowship. Ann Surg Oncol 25:3445–3452
Kennedy GT, McMillan MT, Sprys MH et al (2016) The influence of fellowship training on the practice of pancreatoduodenectomy. HPB (Oxford) 18:965–978
Zou SY, Wang WS, Zhan Q et al (2020) Higher body mass index deteriorates postoperative outcomes of pancreaticoduodenectomy. Hepatobiliary Pancreat Dis Int 19:163–168
Parker SH, Lei X, Fitzgibbons S et al (2020) The impact of surgical team familiarity on length of procedure and length of stay: inconsistent relationships across procedures, team members, and sites. World J Surg 44:3658–3667
Peng F, He R, Wang H et al (2023) Development of a difficulty scoring system for laparoscopic pancreatoduodenectomy in the initial stage of the learning curve: a retrospective cohort study. Int J Surg 109:660–669
Napoli N, Cacace C, Kauffman EF et al (2023) The PD-ROBOSCORE: a difficulty score for robotic pancreatoduodenectomy. Surgery 173(6):1438–1446
Acknowledgements
The authors thank Mr. Brahmanndam Mannem for help with the artwork
Funding
Open Access funding enabled and organized by CAUL and its Member Institutions.
Author information
Authors and Affiliations
Contributions
MK contributed to Conceptualization of the manuscript, design of the study, interpretation of data, drafting of the manuscript and final approval. MMW contributed to Interpretation of data, drafting of the manuscript and final approval. SU contributed to Statistical analysis, interpretation of data, review, and final approval. SGB contributed to Conceptualization of the manuscript, interpretation of data, critical review and final approval.
Corresponding author
Ethics declarations
Conflict of interest
Drs. Monish Karunakaran, Matthew Marshall-Webb, Shahid Ullah and Savio Barreto have no conflicts of interest or financial ties to disclose.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Karunakaran, M., Marshall-Webb, M., Ullah, S. et al. Impact of Unplanned Intra-Operative Conversions on Outcomes in Minimally Invasive Pancreatoduodenectomy. World J Surg 47, 2507–2518 (2023). https://doi.org/10.1007/s00268-023-07114-1
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00268-023-07114-1