Introduction
            Endoscopic ultrasound (EUS)‐guided fine‐needle aspiration (FNA) was first described
               in 1992 and remains a safe, well‐established, and first‐line diagnostic tool for the
               evaluation of solid pancreatic lesions [1]. With regard to diagnosing solid pancreatic lesions, its sensitivity and specificity
               has been reported to be 86.8 % and 95.8 %, respectively [2]. The most common solid pancreatic lesions are pancreatic adenocarcinoma (PAC) followed
               by neuroendocrine tumor (NET) and solid pseudopapillary tumor (SPT) [3]. PAC is the seventh leading cause of global cancer deaths in industrialized countries
               and the third most common in the United States. PAC remains one of the most lethal
               malignancies, with a dismal prognosis and mortality/incidence ratio of 94 % [4]
               [5]. Therefore, establishing early and accurate diagnosis remains paramount. 
            EUS-guided pancreatic sampling can be performed by obtaining fine-needle aspiration
               (EUS-FNA) as well as core fine-needle biopsy samples (EUS-FNB). Some of the limitations
               of EUS-FNA include risks of inadequate sampling and false-negative results for malignancy
               in up to 20 % to 40 % of cases [6]
               [7]. EUS-FNB needles, on the other hand, allow sampling of a larger amount of tissue
               and better preservation of cell architecture than an aspirate. Several studies have
               shown comparable diagnostic accuracy of EUS-FNA and EUS-FNB in solid pancreatic lesions,
               with the exception of fewer needle passes needed to obtain an adequate sample using
               the EUS-FNB technique [8]
               [9]
               [10]
               [11]. Recently Sweeney et al also showed comparable diagnostic yield of EUS-FNA, FNB,
               and combined FNA and FNB in solid pancreatic lesions [12].
            To overcome the limitations of EUS-FNA, ROSE has gained popularity across health centers,
               especially in the United States. This technique involves evaluation of direct smears
               obtained at the point of care in the endoscopy suite by an in-house cytopathologist
               [13]. Studies have suggested a 3.5 % increase in adequacy rates [14] and 8 % increase in sensitivity [15] for EUS-FNA of solid pancreatic lesions with the addition of this technique. Other
               factors that influence the diagnostic yield of EUS-guided sampling include operator
               experience or expertise, tumor location as well as size and characteristics of the
               lesion [16].
            An alternative to ROSE is LBC in which FNA samples are collected in a liquid medium.
               This technique makes samples less vulnerable to contamination or artifacts and allows
               for optimal cell preservation as there is immediate fixation and storage of collected
               samples at room temperature. In addition, no special technical training or skills
               are required for collecting the material in the fixative solution, which can solve
               the problem of sample assessment in the absence of ROSE [17]. The LBC technique is further divided into filtration-based (ThinPrep®, CellPrep®) and precipitation-based (SurePath™) [18].
            Studies have reported higher accuracy of LBC over CS cytology in diagnosis of cervical,
               gallbladder, and biliary cancers; however, data regarding its applicability in pancreatic
               lesions are limited [19]
               [20]. We evaluated the diagnostic accuracy of filtration-based and precipitation-based
               LBC compared to CS cytology in pancreatic lesions using meta-analysis. 
         Methods
            Search strategy
            
            The literature was searched by a medical librarian for publications regarding the
               concepts of liquid-based or smear-based cytology for EUS-guided fine-needle aspiration
               of pancreatic lesions. The search strategies were created using a combination of keywords
               including “SurePath”, “ThinPrep”, “conventional Papanicolaou smear”, “endoscopic ultrasonography-guided
               fine-needle aspiration”, “liquid-based cytology”, “pancreatic lesion” and standardized
               index terms. Searches were performed during March 2020 in ClinicalTrials.gov, Ovid EBM Reviews, Ovid Embase (1974 +), Ovid Medline (1946 + including epub ahead
               of print, in-process & other non-indexed citations), Scopus (1970 +) and Web of Science
               (1975 +). Results were limited to English language. The full search strategy is available
               in Supplementary Appendix A. The MOOSE checklist was followed and is provided as Supplementary Appendix B 
               [21]
               [22]. Reference lists of evaluated studies were examined to identify other studies of
               interest.
            
            Study selection
            
            We included studies that evaluated the diagnostic efficacy of conventional smear-based
               cytology with LBC in EUS-guided FNA sampling of pancreatic lesions. Studies were included
               irrespective of inpatient/ outpatient setting, study sample size, follow-up time,
               and geography as long as they provided the appropriate data needed for the analysis.
            
            Our exclusion criteria were studies performed in the pediatric population (age < 18
               years) and studies not published in English language. In cases of multiple publications
               from a single research group reporting on the same patient, same cohort and/or overlapping
               cohorts, data from the most recent and/or most appropriate comprehensive report were
               retained. Authors did not need to be contacted for clarification of possible study-cohort
               overlap, as all included studies were published as full manuscripts. The retained
               studies were decided by two authors (BPM, SC) based on the publication timing (most
               recent) and/or the sample size of the study (largest). In situations where a consensus
               could not be reached, overlapping studies [23]
               [24] were included in the final analysis and any potential effects were assessed by sensitivity
               analysis of the pooled outcomes by leaving out one study at a time. Studies reporting
               outcomes of LBC were also reviewed separately by another author (SM) with expertise
               in pathological sciences prior to inclusion in our final analysis,
            
            Data abstraction and quality assessment
            
            Data on study-related outcomes from the individual studies were abstracted independently
               onto a standardized form by at least three authors (BPM, SRK, AS). Authors SC, ARS,
               ASD, NB cross-verified the collected data for possible errors and two authors (SRK,
               SC) did the quality scoring independently. The Newcastle-Ottawa scale for cohort studies
               was used to assess the quality of studies [25]. This quality score consisted of eight questions, the details of which are provided
               in Supplementary Table 1.
               
            
            Outcomes assessed
            
            Two outcomes were assessed: (1) pooled odds of CS cytology compared with LBC techniques
               in diagnosing benign, suspicious and malignant pancreatic lesions with analysis of
               outcomes of CS cytology with both precipitation-based and filtration-based methods
               of LBC; and (2) pooled diagnostic performance in terms of accuracy, sensitivity, specificity,
               PPV and NPV of CS and LB cytology.
            
            Statistical analysis
            
            We used meta-analysis techniques to calculate the pooled estimates in each case following
               the methods suggested by DerSimonian and Laird using the random-effects model [26]. When the incidence of an outcome was zero in a study, a continuity correction of
               0.5 was added to the number of incident cases before statistical analysis. [27]. We assessed heterogeneity between study-specific estimates by using Cochran Q statistical
               test for heterogeneity, 95 % confidence interval (CI), which deals with the dispersion
               of the effects, and the I2 statistics [27]
               [28]
               [29]. In this, values < 30 %, 30 % to 60 %, 61 % to 75 %, and > 75 % were suggestive
               of low, moderate, substantial, and considerable heterogeneity, respectively. We reported
               our primary outcomes as pooled odds ratio (OR) between CS cytology and LBC techniques
               where OR denotes the proportional probability of diagnosing a malignant and/or benign
               and/or a suspicious lesion with one technique as compared to the other. 
            
            Publication bias was ascertained, qualitatively, by visual inspection of funnel plot
               and quantitatively, by the Egger test [28]. When publication bias was present, further statistics using the fail-Safe N test
               and Duval and Tweedie’s ‘Trim and Fill’ test was used to ascertain the impact of the
               bias [30]. Three levels of impact were reported based on the concordance between the reported
               results and the actual estimate if there were no bias. The impact was reported as
               minimal if both versions were estimated to be same, modest if effect size changed
               substantially but the final finding would still remain the same, and severe if basic
               final conclusion of the analysis is threatened by the bias [31]. P < 0.05 was used “a-priori” to define significance between the groups compared. 
            
            All analyses were performed using Comprehensive Meta-Analysis (CMA) software, version
               3 (BioStat, Englewood, New Jersey, United States). 
            Results
            Search results and population characteristics
            
            From an initial pool of 756 studies, 454 records were screened and 48 full-length
               articles were assessed. A total of nine studies (including 1308 patients) were included
               in the final analysis [18]
               [32]
               [33]
               [34]
               [35]
               [36]
               [37]
               [38]
               [39]. None of the included studies used ROSE. Four studies originated in Korea, two in
               China, and one each from the Netherlands, the United States, and Japan. Three studies
               used the precipitation-based technique of LBC [32]
               [33]
               [34] whereas six used the filtration-based technique (five studies used ThinPrep® and one used CellPrep®
               [18]). The schematic diagram demonstrating our study selection is shown in Supplementary Fig. 1. 
            
            Baseline population characteristics were comparable between the CS and LBC cohorts.
               The mean and/or median age ranged from 54.9 to 74 years. The majority of the final
               diagnosis were reported as pancreatic ductal adenocarcinoma (PDAC) in 544 cases. Further
               details along with the population characteristics are listed in [Table 1a, b].
            
            
               
                  
                     Table 1a
                     
                     Study Details and Population Characteristics
                     
                  
                     
                     
                        
                        | Author | Design | ROSE | LBC method | Total (N) | Age | M/F | Needle 19G/22G/25G | N passes 3/4 | Size (cm) | 
                     
                     
                        
                        | Y/N | CS | LBC | CS | LBC | CS | LBC | CS | LBC | CS | LBC | 
                     
                  
                     
                     
                        
                        | Chun, 2020 | Randomized, prospective single center, April 2018 to March 2019, Korea. | N | Precipitation (SurePath) | 170 | 64.5 (10.8) | 65.3 (10.5) | 47/38 | 48/37 | 32/53 | 19/66 | 77/7 | 69/12 | 3.1 (1.2) | 3.3 (1.1) | 
                     
                     
                        
                        | Zhou, 2020 | Retrospective, single center, January 2015 to January 2019, China. | N | Precipitation (SurePath) | 514 | 60 (50–67) | 323/191 | 0/35/15 | 0/109/12 | 3 (2–3) | 5 < 2 cm, 59 2–4 cm , 57 > 4 cm | 2 < 2 cm, 27 2–4 cm, 21 > 4 cm | 
                     
                     
                        
                        | Hashimoto, 2017 | Retrospective, Single center, Dec 2005 to August 2014. Japan | N | Precipitation (SurePath) | 265 | 65 (35–93) | 66 (33–85) | 63/49 | 84/69 | 1/104/7 | 8/127/18 | 3.4 (1–6) | 2.9 (1–6) | 3.1 (0.1–7.8) | 3 (0.8–7.6) | 
                     
                     
                        
                        | De Luna, 2004 | Prospective, single center, August 2000 and February 2002, USA | N | Filtration (ThinPrep) | 67 | 64 (39–87) | 45/22 | – | – | – | – | – | – | 
                     
                     
                        
                        | Lee, 2016 | Retrospective, Single center, July 2010 to June 2015, Korea. | N | Filtration (ThinPrep-Group 1) | 36 | 67 (53–80) | 20/16 | 22G 36 | – | – | 3.9 (1.4–7.2)  | 
                     
                     
                        
                        | N | Filtration (ThinPrep-Group 2) | 12 | 74 (39–84) | 4/8 | 22G 12 | – | – | 
                     
                     
                        
                        | Qin, 2014 | Prospective, Single center, January 2011 to January 2014, China. | N | Filtration (ThinPrep) | 72 | 54.6 (24–70) | 58/14 | 22G 72 | – | – | 0.8 × 0.9–9.6 × 9.8  | 
                     
                     
                        
                        | Lee, 2011 | Prospective, Single center, July and December 2009, Korea. | N | Filtration (ThinPrep) | 58 | 59 (11.0) | 33/25 | 0/34/24 | 0/34/24 | 3.8 (2–8) | 46 > 2 cm, 12 < 2 cm | 
                     
                     
                        
                        | Van Riet, 2020 | Prospective, Multicenter, April 2016 and September 2017, Netherlands. | N | Filtration (ThinPrep) | 71 | – | – | – | – | 1/27/23 | 3 (2–3) | 3.1 ± 1.37 | 
                     
                     
                        
                        | Yeon, 2018 | Prospective, Single Center, Korea. | N | Filtration (CellPrep) | 43 | 65.5 ± 12.5 | 29/14 | 22G 43 | – | – | 3.7 ± 2.2 | 
                     
               
             
            
            
            
               
                  
                     Table 1b
                     
                     Study Details, Final Diagnosis and Adverse Events
                     
                  
                     
                     
                        
                        | Author | Location (H Head, U Uncinate, B Body, N Neck, T Tail) | Adverse Events | Final diagnosis (malignant/benign) | Follow Up [Months] | Diagnosis | 
                     
                     
                        
                        | CS | LBC | CS | LBC | CS | LBC | CS | LBC | 
                     
                  
                     
                     
                        
                        | Chun, 2020 | 30H, 12U, 26B, 17 T | 29H, 12U, 17B, 27 T | 4 (Pain 2,bleed 2, f0, perf0) | 9 (pain 2, bleed 3, fever3, perf1) | 82/85 (malig); 3/85 (benign) | 83/85 (malig); 2/85 (benign) | 6 m | PDAC 80, MCN w/invasive CA 1, mets in LN 1 | PDAC 78, IPMN w/invasive CA 3, NET 2 | 
                     
                     
                        
                        | Zhou, 2020 | 186H, 22U, 85B, 79 T | NR | NR | 57/385 (malig); 135/385 (susp); 72/89 (benign) | 157/385 (malig); 105/385 (susp); 78/89 (benign) | 6 m | AIP 1, Pseudocyst 6, PDAC 3 | AIP 1, Pseudocyst 6, PDAC4, AC 1 | 
                     
                     
                        
                        | Hashimoto, 2017 | 64H, 34B, 14 T | 76H, 54B, 23 T | NR | NR | 92/112 (malig); 20/112 (benign) | 136/153 (malig); 17/153 (benign) | NR | PDAC 85, NET 1, Metastatic 3, Carcinoma 1, SPN 1, Lymphoma 1, AIP 6, Inflamm 11, benign
                              tumor 3 | PDAC 122, NET 10,Metastatic 2, Carcinoma 1, SPN 1, Inflamm 6, AIP 7, Benign 4 | 
                     
                     
                        
                        | De Luna, 2004 | – | – | – | – | 34/67 (malig); 7/64 (atypical/susp) | 22/51 (malig); 12/51 (atypical/susp) | 13 m (8–26 m) | 44 PDAC, 2 MCN, 1 islet cell tumor, 19 inflammatory, 1 microcystic adenoma | 
                     
                     
                        
                        | Lee, 2016 | 5H, 16B, 15 T | – | – | 25/36 (malig); 9/36 (susp); 0/36 (benign) | 15/36 (malig); 11/36 (susp); 4/36 (benign) | 12 m | PDAC 48 | 
                     
                     
                        
                        | 5H, 5B, 2 T | – | – | 9/12 (malig); 1/12 (susp); 2/12 (benign) | 7/12 (malig); 2/12 (susp); 2/12 (benign) | 
                     
                     
                        
                        | Qin, 2014 | 50H, 22B/T | – | – | 42/60 (malig); 12/12 (benign) | 44/60 (malig); 12/12 (benign) | 12 m (3–16) | AdenoCA 41, NET 1,Panc TB 10, CP 2 | AdenoCA 42, NET 2, Panc TB 10, CP 2 | 
                     
                     
                        
                        | Lee, 2011 | 13H, 10U, 9N, 22B, 4 T | None | 30/58 (malig); 11/58 (susp); 9/58 (benign) | 11/58 (malig); 22/58 (susp); 5/58 (benign) | NR | Panc CA 36, Malig IPMN 3, Cholangio 2, Lymphoma 1, AoV CA 1, Mets 1, SCA 3, Simple
                              cyst 3, Desmoid/GIST/Inflamm/NET/Adipose T/Granuloma 1 each | 
                     
                     
                        
                        | Van Riet, 2020 | 34H, 6U, 4N, 14C, 13 T | None | 47/71 (malignant) | 30/42 (malignant) | 12 m | Benign 4, Malig 64, Atypical (NET, Pancreatitis) 3 | 
                     
                     
                        
                        | Yeon, 2018 | 18H, 6U, 7B, 12 T | – | – | 24/48 (malig); 20/48 (benign) (48 specimen) | 17/48 (malig); 20/48 (benign) (48 specimen) | 6 m  | NR | 
                     
               
             
            
            
            Characteristics and quality of included studies
            
            Six studies were prospective in design, [18]
               [23]
               [32]
               [35]
               [39]
               [40] and the remaining were retrospective. The detailed study quality evaluation is presented
               in Supplementary Table 1. Based on the New-Castle Ottawa scoring system, seven studies were considered to
               be of high quality and two studies were considered to be of medium quality. There
               were no low-quality studies. 
            
            Definition of cytological diagnosis
            
            Cytologic diagnoses in the techniques were made according to the Papanicolaou Society
               of Cytopathology (PSC) guidelines and classified into three categories: (1) benign,
               defined as the presence of sufficient cellularity for making diagnoses of benign tumors;
               (2) suspicious for malignancy, meaning there were some typical features of a specific
               malignant neoplasm, but quantity was insufficient; and (3) malignant, a group of tumors
               that clearly show malignant cytologic features.
            
            Meta-analysis outcomes
            
            1. Pooled odds of CS cytology compared with LBC in  diagnosing benign, suspicious
               and malignant lesions: 
            
            
               
               - 
                  
                  CS cytology performed comparably to LBC in diagnosing benign and suspicious pancreatic
                     lesions [OR = 1.1 (0.7–1.75); P = 0.7, 1.23 (0.96–1.59); P = 0.1] when combining the data from both the filtration and precipitation-based methods
                     for LBC. 
- 
                  
                  CS cytology performed significantly better than filtration-based LBC technique in
                     diagnosing suspicious, and malignant pancreatic lesions [OR = 1.69 (1.02–2.79); P
                      = 0.04, OR = 0.47 (0.27–0.8); P = 0.006]. For benign lesions, outcomes of the two techniques were comparable. 
- 
                  
                  Precipitation-based LBC performed significantly better than CS cytology in diagnosing
                     malignant pancreatic lesions [OR = 0.39 (0.19–0.8); P = 0.01], but this effect was not seen with respect to benign lesions. 
Pooled rates of performance in terms of final diagnosis (malignant, suspicious or
               benign) of CS cytology and LBC techniques and pooled odds are summarized in [Table 2] and [Fig. 1], [Fig. 2], [Fig. 3], [Fig. 4], [Fig. 5] and [Fig. 6]
               .
               
            
            
               
                  
                     Table 2
                     
                     Pooled performance of CS and LBC techniques.
                     
                  
                     
                     
                        
                        |  | Malignant | Benign | Suspicious | 
                     
                  
                     
                     
                        
                        | Pooled odds ratio (95 % confidence interval) | 
                     
                     
                        
                        | Conventional smear vs Liquid based cytology (LBC) | NA | OR = 1.1 (0.7–1.75)P  = 0.7
 I2 = 2; 8 studies
 | OR = 1.23 (0.96–1.59)P  = 0.1
 I2 = 76; 5 studies
 | 
                     
                     
                        
                        | Conventional smear vs Precipitation-LBC (SurePath) | OR = 0.39 (0.19–0.8)P  = 0.01
 I2 = 60; 3 studies
 | OR = 1.1 (0.6–2.1)P = 0.7
 I2 = 48; 3 studies
 | -NA- | 
                     
                     
                        
                        | Conventional smear vs Filtration-LBC(ThinPrep, CellPrep)
 | OR = 1.69 (1.02–2.79)P  = 0.04
 I2 = 56; 7 studies
 | OR = 1.1 (0.54–2.17)P = 0.8
 I2 = 0; 5 studies
 | OR = 0.47 (0.27–0.8)P  = 0.006
 I2 = 0; 4 studies
 | 
                     
                     
                        
                        | Pooled proportions (95 % confidence interval) | 
                     
                     
                        
                        | Conventional smear | 64.9 % (43.4–81.7)I2 = 96; 10 studies
 | 26.4 % (8.2–58.8)I2 = 94; 8 studies
 | 22.8 % (10.4–42.7)I2 = 93; 5 studies
 | 
                     
                     
                        
                        | Liquid-based cytology subtypes | 
                     
                     
                        
                        | Precipitation-LBC (SurePath) | 84.1 % (50.9–96.4)I2 = 98; 3 studies
 | 23.2 % (3.3–72.5)I2 = 98; 3 studies
 | NA | 
                     
                     
                        
                        | Filtration-LBC (ThinPrep) | 48.6 % (24.2–73.7)I2 = 84; 7 studies
 | 29.1 % (6.7–70.3)I2 = 85; 5 studies
 | 27.5 % (11.9–51.5)I2 = 18; 4 studies
 | 
                     
               
               
               CS convetional smear; LBC, liquid-based cytology.
                
            
            
            
             Fig. 1 OR malignant.
                  Fig. 1 OR malignant.
            
            
            
             Fig. 2 OR benign.
                  Fig. 2 OR benign.
            
            
            
             Fig. 3 OR suspicious.
                  Fig. 3 OR suspicious.
            
            
            
             Fig. 4 PR malignant.
                  Fig. 4 PR malignant.
            
            
            
             Fig. 5 PR benign.
                  Fig. 5 PR benign.
            
            
            
             Fig. 6 PR suspicious.
                  Fig. 6 PR suspicious.
            
            
            
            2. Pooled diagnostic performance of CS, Precipitation-based and Filtration-based LBC
               techniques 
            
            Precipitation-based LBC had higher pooled accuracy (85.2 %) and sensitivity (83.6 %)
               compared to CS (79.7 % and 79.2 %, respectively) and filtration-based LBC (77.3 %
               and 68.3 %, respectively). Specificity and PPV were comparable in all three techniques.
               NPV was found to be higher with filtration-based LBC technique (50.9 %) as compared
               with CS (46.2 %) and precipitation-based LBC techniques (35.4 %). Details are summarized
               in [Table 3] and Supplementary Fig. 1 to 5
               
            
            
               
                  
                     Table 3
                     
                     Pooled accuracy/sensitivity/specificity/PPV/NPV of techniques.
                     
                  
                     
                     
                        
                        |  | Accuracy | Sensitivity | Specificity | PPV | NPV | 
                     
                  
                     
                     
                        
                        | CS | 79.7 % (72.2–85.6)I2  = 86;
 8 studies
 | 79.2 % (70.7–85.7)I2  = 89;
 8 studies
 | 99.4 % (98.4–99.8)I2  = 0;
 7 studies
 | 99.5 % (98.5–99.8)I2  = 0;
 6 studies
 | 46.2 % (27.2–66.4)I2  = 96;
 6 studies
 | 
                     
                     
                        
                        | Liquid based cytology sub-types | 
                     
                     
                        
                        | Precipitation-LBC (SurePath) | 85.2 % (74.4–91.9)I2  = 76;
 3 studies
 | 83.6 % (70.7–91.5)I2  = 85;
 3 studies
 | 99.5 % (97.6–99.9)I2  = 0;
 3 studies
 | 99.5 % (97.6–99.9)I2  = 0;
 3 studies
 | 35.4 % (14.5–63.9)I2  = 91;
 3 studies
 | 
                     
                     
                        
                        | Filtration-LBC (ThinPrep) | 77.3 % (67.1–85)I2  = 49;
 5 studies
 | 68.3 % (55.3–79)I2  = 64;
 5 studies
 | 99.5 % (97.6–99.9)I2  = 0;
 4 studies
 | 99.5 % (97.6–99.9)I2  = 0;
 3 studies
 | 50.9 % (24.4–76.9)I2  = 92
 3 studies
 | 
                     
               
               
               CS, conventional smear; LBC, liquid-based cytology; PPV, positive predictive value;
                  NPV, negative predictive value.
                
            
            
            
            Validation of meta-analysis results
            
            Sensitivity analysis
            
            To assess whether any one study had a dominant effect on the meta-analysis, we excluded
               one study at a time and analyzed its effect on the main summary estimate. In the pooled
               OR analysis, we noted a significant change to the pooled rates for CS vs LBC by precipitation,
               when the studies by Lee et al 2011 and Yeon et al 2018 were removed (pooled OR = 1.4,
               P = 0.1 and pooled OR = 1.7, P = 0.1; respectively). No changes to the final pooled rates were noted in the analysis
               of benign and/or suspicious lesions. In the analysis of proportions, we did not notice
               any changes to the pooled rates when any one study was removed at a time in the diagnosis
               of any of the lesions.
            
            Heterogeneity
            
            We assessed dispersion of the calculated rates using the CI and I2 percentage values. The CI gives an idea of the range of the dispersion and I2 tell us what proportion of the dispersion is true vs chance [29]. Overall, a considerable to substantial degree of heterogeneity was noted in the
               analysis. Based on our analysis, the types of LBC method (precipitation, filtration),
               brand of LBC medium (SurePath™, ThinPrep®, CellPrep®) and final diagnosis of the lesion (benign, suspicious, or malignant) seemed to explain
               the observed heterogeneity to some extent. Other possible variables that might have
               contributed to the heterogeneity, which were not amenable to analysis, were the number
               of needle passes performed, FNA needle gauge used (19G, 22G, 25G), location of pancreatic
               lesion (head, uncinate, body, tail) and study design (retrospective, prospective).
               Overall, considerable heterogeneity was noted in the analysis.
            
            Publication bias
            
            Publication bias was not evaluated as the number of studies in our analysis was less
               than 10. 
            Discussion
            We found that EUS-guided FNA using conventional smear (CS) cytology was superior to
               filtration-based LBC for diagnosing malignant as well as suspicious pancreatic lesions.
               On the other hand, precipitation-based LBC was superior to CS cytology, in particular,
               for diagnosing malignant pancreatic lesions. We found no significant difference in
               the diagnostic odds of the three techniques in terms of diagnosing benign pancreatic
               lesions. 
            In terms of overall diagnostic performance, EUS-guided fine-needle aspiration using
               precipitation-based liquid cytology technique had higher accuracy and sensitivity
               compared to CS and filtration-based liquid cytology techniques (85.2 % and 83.6 %,
               respectively).
            EUS-guided FNA is a safe, cost-effective and widely accepted method for evaluating
               and sampling solid pancreatic lesions [41]. For decades, the CS technique has been used and has demonstrated a diagnostic sensitivity
               for pancreatic malignancy as high as 96 % [42]
               [43]. CS involves the FNA sample being smeared directly onto a glass slide and then either
               air-dried for Diff-quick staining or wet-fixed with an ethanol-based fixative for
               Papanicolaou staining, although other stains can be employed. 
            There are some important differences between CS preparations, filtration-based LBC,
               and precipitation-based LBC that deserve a mention. CS preparations have the advantage
               of the pathologist knowing that the cellular material on the slide represents a single
               pass (meaning that increased cellularity has more meaning and can better support an
               abnormality). On the other hand, when LBC is used, often several passes are put into
               the same vial, and therefore, cellularity becomes less informative. CS also better
               preserves extracellular material that may be present in a lesion (eg, hyalinization
               that occurs in SPT). In addition, it is generally understood that CS allows better
               evaluation of cytomorphologic architecture; for example, loss of cohesion in carcinoma
               cells is often more evident on a CS. Finally, it is helpful to have the option for
               different staining methods (Diff-Quik™) and Papanicolaou stains with CS. 
            The major advantage of CS is the needed availability of a ROSE where a cytopathologist
               is present during the procedure. The rationale for using ROSE in EUS-FNA tissue acquisition
               is that it allows real-time evaluation of sample adequacy and diagnostic yield. Additionally,
               on-site cytopathologists can determine whether additional sampling is required for
               further diagnosis or if specimen triage is necessary for additional studies (eg, immunohistochemistry
               or flow cytometry) [44]
               [45]. Despite its proven advantage [46]
               [47], ROSE is not readily available in all healthcare centers across the world. According
               to a study on practice patterns in EUS-FNA published in 2016, ROSE was available in
               only 48 % of European and 55 % of Asian centers, but in almost all centers (98 %)
               in the United States. The obstacles to expanding ROSE include limited cytopathologist
               staffing, cost-effective performance, and longer procedural duration [48].
            LBC was first introduced in 1991 and has been used extensively in the analysis of
               fine-needle aspirations of the thyroid [49]
               [50]
               [51] and cervical cytology [52]
               [53]
               [54]. Although tissue architecture and the determination of cellularity can be made more
               difficult on LBC as compared to CS, LBC does allow for a reduction in artifacts related
               to sample drying and elimination of blood contamination by lysing red blood cells
               thereby resulting in a cleaner background. In addition, because the cellular elements
               are within a circle in the center of the slide, it can be less time-consuming for
               the cytopathologist compared with CS where the samples are irregularly distributed
               over multiple glass slides [18]
               [55].
            Filtration-based and precipitation-based are two types of LBC methods. They have some
               similarities and few subtle differences. In general, the filtration method has flatter
               cell layer distribution, which is considered its main advantage over the precipitation
               method as cells can be easier to visualize over a larger diameter area. The filtration
               method does suffer from the filter itself getting clogged by interfering material
               (such as blood or mucus) that increases the number of unsatisfactory results as compared
               to the precipitation method. The nuclear features of malignancy or benignity should
               be similarly evident in both LBC preparations. Both methods have the advantage of
               being a single slide for evaluation, compared to CS which usually has multiple slides
               per case [56]. Differences between the preparation types outlined in [Table 4].
            
               
                  
                     Table 4
                     
                     Advantages and disadvantages of CS and LBC techniques.
                     
                  
                     
                     
                        
                        |  | 
                              Conventional Smear (CS)
                               | 
                              LBC (Filtration)
                               | 
                              LBC (Precipitation)
                               | 
                     
                  
                     
                     
                        
                        | 
                              Advantages
                               | Better gauge of cellularity | No ROSE needed | No ROSE needed | 
                     
                     
                        
                        | Preserved extracellular material | Single slide | Single slide | 
                     
                     
                        
                        | Preserved cytologic architecture | Flatter cell distribution | Improved satisfactory rate | 
                     
                     
                        
                        | Stain options | 
                     
                     
                        
                        | 
                              Disadvantages
                               | Requires ROSE | Increased unsatisfactory rate | More cell crowding/overlap | 
                     
                     
                        
                        | More slides to evaluate | Loss of cellularity gauge, extracellular material, cytologic architecture, and stain
                              options | Loss of cellularity gauge, extracellular material, cytologic architecture, and stain
                              options | 
                     
               
               
               CS, conventional smear; LBC, liquid-based cytology; ROSE, rapid on-site evaluation.
                
            
            
            The strengths of this review are as follows: systematic literature search with well-defined
               inclusion criteria, careful exclusion of redundant studies, inclusion of good quality
               studies with detailed extraction of data and rigorous evaluation of study quality.
               Our study included only those studies in which a comparative analysis between CS and
               LBC was performed in pancreatic lesions. We excluded studies in which either only
               one technique was evaluated [57]
               [58] or non-pancreatic lesions were evaluated [59]
               [60] There are limitations to this study as well, most of which are inherent in any meta-analysis.
               We were unable to evaluate the effect of lesion location, size, number of passes,
               needle size, or operator experience on our results. We included studies that were
               retrospective in nature contributing to selection bias and our analysis has the limitation
               of non-causal comparison with significant heterogeneity. While a majority of the lesions
               diagnosed in our study were pancreatic adenocarcinomas, we were unable to evaluate
               the efficacy of either cytology techniques for other malignant and benign pancreatic
               etiologies given their underrepresentation in included studies. In one of the included
               studies, atypical and suspicious lesions were grouped together [35]. Finally, our analysis included only three studies that used the precipitation-based
               LBC technique, which may have influenced our results.
         Conclusion
            Our study is the first in the literature to evaluate the diagnostic performance of
               conventional smear in the absence of ROSE with LBC in EUS-guided FNA sampling of solid
               pancreatic lesions. We found that CS and LBC techniques have comparable efficacy in
               terms of characterizing pancreatic lesions as either malignant, suspicious or benign.
               However, given the differences in preparation methods of LBC, comparative analysis
               with CS is inaccurate. Hence, we decided to compare CS with both LBC techniques and
               found that precipitation-based LBC (SurePath) outperforms CS cytology without ROSE
               for diagnosing malignant pancreatic lesions. However, CS cytology outperforms the
               filtration-based LBC (ThinPrep, CellPrep) technique in diagnosing both malignant and
               suspicious pancreatic lesions. In conclusion, in the absence of ROSE, precipitation-based
               LBC should be preferred over CS technique in EUS-guided sampling of pancreatic lesions.
               Finally, regardless of the cytologic preparation method, EUS-FNA cytology continues
               to remain a useful and accurate diagnostic tool for pancreatic lesions.