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World J Gastroenterol. Jun 14, 2008; 14(22): 3461-3463
Published online Jun 14, 2008. doi: 10.3748/wjg.14.3461
Heterogeneity of colorectal adenomas, the serrated adenoma, and implications for screening and surveillance
Hugh James Freeman, Department of Medicine (Gastroen-terology), University of British Columbia, Vancouver V6T 1W5, Canada
Author contribution: Freeman HJ contributed all to this paper.
Correspondence to: Dr. Hugh James Freeman, MD, FRCPC, FACP, Department of Medicine (Gastroenterology), University of British Columbia Hospital, 2211 Wesbrook Mall, Vancouver V6T 1W5, Canada. hugfree@shaw.ca
Telephone: +1-604-8227216
Fax: +1-604-8227236
Received: March 17, 2008
Revised: May 7, 2008
Accepted: May 14, 2008
Published online: June 14, 2008

Abstract

Current algorithms for screening and surveillance for colon cancer are valuable, but may be limited by the underlying nature of the targeted neoplastic lesions. Although part of the success of adenoma removal relates to interruption of so-called “adenoma-carcinoma sequence”, an alternate serrated pathway to colon cancer may pose difficulties with the ultimate results achieved by traditional colonoscopic methods. The endpoint carcinoma in this unique pathway may be derived from a dysplastic serrated adenoma. These tend to be located primarily in the right colon, especially in females, and are frequently associated with co-existent colon cancer. Unfortunately, however, there are few, if any, other identifiable risk factors, including age or family history of colon polyps or colon cancer. Moreover, this alternate serrated pathway may itself also be quite biologically heterogeneous as reflected in sessile serrated adenomas (SSA) with virtually exclusive molecular signatures defined by the presence of either BRAF or KRAS mutations. Screening algorithms in the future may need to be modified and individualized, depending on new information that likely will emerge on the natural history of these biologically heterogeneous lesions that differs from traditional adenomatous polyps.

Key Words: Colorectal adenomas, Serrated polyps, Polyp heterogeneity, Colonoscopy screening, Colorectal cancer



INTRODUCTION

Clinician endoscopists have witnessed an evolution in the application of the colonoscope. Initially, it was used primarily as an investigative modality to explore patient symptoms (abdominal pain, diarrhea, bleeding). Later, it also became widely applied as a therapeutic tool, particularly for removal of colorectal neoplasms. Now, colonoscopy has increasingly been used to screen for colon polyps and cancer in those with few or no symptoms demanding peace of mind. As a result, various agencies have developed (and promoted) guidelines for use that might aid in this endeavour, largely based on various risk factors, including familial colon polyps and cancers. For some, these are described as “evidence-based” with the goal of being “cost-effective” for an increasingly scarce service resource. These guidelines have also been based, at least in part, on the “Vogelstein” hypothesis that colon cancer results from a multistage and sequential series of mutational events that proceed from a benign adenomatous proliferation of altered epithelial cells to an increasingly larger and more complex invasive neoplastic (and even metastatic) lesion or lesions, the so-called “polyp-cancer sequence”[1]. Reasonably, interruption of this sequence could be accomplished by an intervening polypectomy and reduce the individual’s risk for colon cancer. Recent information emphasizing the heterogeneous nature of these precursor colon epithelial polyps has suggested that this perspective may be an oversimplification of a more difficult problem.

TRADITIONAL ADENOMAS AND SCREENING

Although different degrees of altered cytological differentiation and atypia have often been described for individual polyps, recognition that colon polyp heterogeneity might have some prognostic clinical significance has traditionally been limited to discerning the degree of villous architectural change in the resected polyp (as opposed to tubular change), estimating polyp size (or more precisely, dimension) along with the number of colon polyps (albeit macroscopically visible). Any one (or more) of these has been considered by some to warrant alteration in the general guideline leading to shortened intervals of screening and/or surveillance, particularly if there were multiple polyps of large size that were histologically complex, primarily with villous architecture. Other factors may have also been entered into the equation in the mind of the practicing clinician including a background of chronic inflammatory bowel disease, certain ethnic or racial backgrounds, and, likely, individual financial means to facilitate performance of the actual screening procedure.

ALTERNATE SERRATED PATHWAY

More recently, there has also been increased recognition that the serrated polyp (including the hyperplastic polyp (HP) with its serrated morphological features) may be more than a simple clinically innocuous bystander in the process of cancer development[23].

These polyps appear quite distinct from traditional adenomatous polyps and may also exhibit morphological and molecular heterogeneity. Recent evidence suggests that some subtypes may pose a substantive potential risk for eventual malignant transformation. As such, it appears that this serrated pathway may represent an alternate road to development of colon cancer with potentially important implications for the “guideline approach” to screening and surveillance for colonic neoplastic lesions.

Some of the difficulty in this area relates to the pathological terminology along with evolution in methods of classification of serrated lesions that reflects the so-called “saw-tooth” architectural appearance of this polyp group[4]. Moreover, distinction between different forms of serrated polyps and interobserver agreement among expert pathologists may be limited[5]. It appears that HPs are the most common type and these have been further sub-divided into microvesicular, goblet-cell rich and mucin-poor types. Other kinds of serrated polyps include sessile serrated adenomas (SSA), traditional serrated adenomas (TSA) and mixed polyps containing components of sessile serrated and tubular adenomas. Significant differences in the expression of specific genetic and molecular markers have also been shown between SSA and TSA[6]. While HPs seem to remain small and localized to the distal colorectum, other serrated polyps may progress to cancer through an apparently unique pathway. An early recognized form of this entity, initially labeled “hyperplastic polyposis” or “serrated adenomatous polyposis”, consisted of larger sessile polyps developing mainly in the right colon. These were associated with synchronous colon cancer in over 50%[78]. For TSA, dysplasia or intramucosal carcinoma were also noted in almost 50%[9]. Of note, about 10% of all colon polyps may be SSA type and about 15% have multiple lesions, based on detection with magnification chromoendoscopy[10]. Most were located in the right colon, particularly in females, however, there was no correlation with age or personal or family history of colon polyps or colon cancer[10]. Other characteristics of SSA are listed in Tables 1 and 2.

Table 1 Comparison of SSA and TSA to TA-TVA-VA polyps.
SSATSATA-TVA-VA
LocationRight colonThroughout, 60% leftThroughout, 60% left
ShapeFlatPedunculatedPedunculated
CytodysplasiaMinimalPresentPresent
GrowthBottom-upBottom-upTop-down
SerrationPresentPresentAbsent
Basal cryptDilation presentDilation absentDilation may be present
Horizontal cryptsPresentAbsentMay be present
Branched cryptsPresentAbsentMay be present
Basal serrationPresentAbsentAbsent
Nuclear shapeRound or ovalTall columnarTall columnar
CytoplasmEosinophilicEosinophilicBasophilic
Table 2 Comparison of SSA polyps and HP polyps.
SSAHP
LocationRight colonRectosigmoid
ShapeFlatPedunculated or flat
Size> 5 mm< 5 mm
Cytologic dysplasiaMinimalAbsent
Basal crypt dilationYesNo
Horizontal cryptsYesNo
Branched cryptsYesNo
Basal crypt serrationYesNo
Nuclear shapeRound to ovalFlat or low columnar
Cytoplasmic eosinophiliaProminentNot prominent
MOLECULAR HETEROGENEITY OF SSA TYPE POLYPS

The molecular heterogeneity of lesions in this alternate serrated pathway has been nicely reviewed elsewhere by O’Brien[3]. The carcinomas that occur demonstrate microsatellite instability (MSI-high) due to hMLH1 inactivation and consequent DNA mismatch repair (MMR). In addition, heterogeneity is evident in that some carcinomas are also microsatellite stable (MSS or MSI-low). The pathway is believed to originate in a HP, or precursor aberrant crypt focus, and progresses through an intermediate disordered type of HP that eventually becomes dysplastic (dysplastic serrated polyp), and ultimately to a serrated adenocarcinoma[3]. Definition of the phenomenon of epigenetic mutagenesis by CpG-island methylation and its key role in sporadic MSI colorectal carcinomas have been stated to be at the molecular genetic core of this newly defined serrated pathway[3]. CpG island methylation phenotype (CIMP) refers to nonrandom methylation of gene promoter regions that concordantly affects multiple susceptible suppressor, mutator, and other genes that have roles in carcinogenesis[12]. Epigenetic gene silencing of cancer-related genes has been shown in precursor polyps and endpoint carcinomas in the serrated polyp pathway[3]. This mechanism differs from the mutagenic process of the traditional “adenoma-carcinoma sequence”, where adenomas progress to carcinoma by deletions and homozygous loss of suppressor genes due to APC mutation-induced chromosomal instability[1]. Another interesting observation has been the discovery of an oncogene BRAF mutation in these neoplasms[10]. A specific activating mutation (V600E) of this phosphokinase appears to be present in most CIMP-high and MSI colon cancers, serrated polyps, including hyperplastic aberrant crypt foci, and dysplastic serrated adenomas. Although the BRAF serrated pathway is predominant (up to 80% of SSA), a second is associated with KRAS mutations. It contrasts with the BRAF pathway in that most of these are distal rather than proximal lesions with lower levels of CpG-island methylation and MSS or MSI-L rather than MSI endpoint carcinomas[3].

FUTURE SCREENING FOR COLON POLYPS

The high proportion of SSA is noteworthy as these are not exactly rare and most disconcerting is that routine colonoscopy may not be adequate for their detection[213].

Moreover, there does not appear to be a definite profile of high risk for this SSA type that might actually lead to initiation of the screening process, particularly family history[2]. Thus, current screening algorithms may not be adequate for detection. Moreover, hyperplastic/serrated polyposis has also been observed in patients with chronic inflammatory bowel disease[14]. A prudent approach has been suggested to include complete resection and surveillance examinations as often as the intervals defined for the more traditional adenomatous polyps but this approach is not necessarily reflective of the natural biological history of these lesions. A prudent colonoscopist will also emphasize prior to embarking on a screening procedure with the patient that small lesions may be not be readily detectable. While still the gold standard for polyp detection, colonoscopic procedures have a definitive “miss rate” so that it can come close to, but does not appear able to reach perfection. Recent comparative and prospective studies using pan-colonic narrow-band imaging suggest that its use for surveillance of even small adenomas may be superior to conventional colonoscopy and equivalent to chromoendoscopy[1518]. More widespread application of these evolving technologies in the future may also impact on the detection of serrated adenomas and current screening and surveillance guidelines.

Footnotes

Peer reviewers: Vincent W Yang, Professor and Director, 201 Whitehead Research Building, 615 Michael Street, Atlanta, GA 30322, United States; Alessandro Fichera, MD, FACS, FASCRS, Assistant Professor, Department of Surgery -University of Chicago, 5841 S. Maryland Ave, MC 5031, Chicago IL 60637, United States

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