Hubbry Logo
search
logo
Gross processing avatar
Gross processing
Gross processing
current hub
1549705

Gross processing

logo
Community Hub0 Subscribers
Read side by side
Gross processing
View on Wikipedia
from Wikipedia
Gross examination of a kidney (right of image) with a renal oncocytoma (left of image).

Gross processing, "grossing" or "gross pathology" is the process by which pathology specimens undergo examination with the bare eye to obtain diagnostic information, as well as cutting and tissue sampling in order to prepare material for subsequent microscopic examination.[1]

Responsibility

[edit]

Gross examination of surgical specimens is typically performed by a pathologist, or by a pathologists' assistant working within a pathology practice. Individuals trained in these fields are often able to gather diagnostically critical information in this stage of processing, including the stage and margin status of surgically removed tumors.[1]

Steps

[edit]
Items used for submitting specimens: (Biopsy) wrap, (biopsy) sponge, (tissue processing) cassette and (biopsy) bag.

The initial step in any examination of a clinical specimen is confirmation of the identity of the patient and the anatomical site from which the specimen was obtained. Sufficient clinical data should be communicated by the clinical team to the pathology team in order to guide the appropriate diagnostic examination and interpretation of the specimen - if such information is not provided, it must be obtained by the examiner prior to processing the specimen.

There are usually two end products of the gross processing of a surgical specimen. The first is the gross description, a document which serves as the written record of the examiner's findings, and is included in the final pathology report. The second product is a set of tissue blocks, typically postage stamp-sized portions of tissue sealed in plastic cassettes, which will be processed into slides for microscopic examination. Since only a minority of the tissue from a large specimen can reasonably be subject to microscopic examination, the success of the final histological diagnosis is highly dependent on the skill of the professional performing the gross examination. The gross examiner may sample portions of the specimen for other types of ancillary tests as diagnostically indicated; these include microbiological culture, flow cytometry, cytogenetics, or electron microscopy.

Perpendicular versus en face sections

[edit]
Perpendicular and en face sections

Two major types of sections in gross processing are perpendicular and en face sections:

  • Perpendicular sections allow for measurement of the distance between a lesion and the surgical margin.
  • En face means that the section is tangential to the region of interest (such as a lesion) of a specimen. It does not in itself specify whether subsequent microtomy of the slice should be performed on the peripheral or proximal surface of the slice (the peripheral surface of an en face section is closer to being the true margin, whereas the proximal surface generally displays more area and therefore generally has greater sensitivity in showing pathology, also compared to perpendicular sections).
  • A shaved section is a superficial en face slice that contains the entire surface of the segment.

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Gross processing

View on Grokipedia
from Grokipedia
Gross processing, commonly referred to as grossing or gross examination, is the foundational stage in surgical pathology involving the macroscopic inspection, description, measurement, and dissection of tissue specimens received from surgical procedures or biopsies to identify abnormalities and select representative sections for subsequent microscopic histological analysis.[1] This process ensures that diagnostic information is captured at the visible level before fixation and embedding, guiding pathologists in correlating gross findings with cellular details to support accurate disease diagnosis and staging.[2] In clinical practice, gross processing plays a critical role in pathology workflows by facilitating the triage of specimens, preventing loss of small biopsies through techniques like cassette placement or lens paper use, and enabling special studies such as sentinel lymph node evaluation for cancer staging.[2] Accurate gross descriptions—including details on size, color, consistency, and orientation—are essential for documenting normal and abnormal features, with errors in specimen identification accounting for a significant portion of medicolegal claims in pathology.[2] Tissues are typically fixed in 10% neutral buffered formalin at a volume ten times that of the specimen to preserve morphology, and inking may be applied to margins for assessing surgical resection completeness in malignancies.[3] The historical evolution of gross processing traces back to ancient observational practices but advanced significantly in the 19th century with Rudolf Virchow's emphasis on correlating macroscopic and microscopic pathology, followed by the introduction of formalin fixation in the early 20th century and standardized guidelines from organizations like the College of American Pathologists in the mid-20th century.[1] Today, it is performed by pathologists or trained assistants in dedicated gross rooms equipped with digital imaging, barcoding, and voice recognition systems to enhance efficiency and documentation accuracy.[1] Emerging trends include artificial intelligence for automated measurements and 3D imaging integration, promising to streamline workflows and improve telepathology capabilities in the future.[1]

Overview

Definition and Purpose

Gross processing, also known as grossing or gross pathology, refers to the macroscopic examination, description, dissection, and sampling of surgical or biopsy specimens prior to microscopic analysis. This initial step involves the naked-eye inspection of tissues to identify visible abnormalities, measure dimensions, and select representative sections for histological processing.[4][5] It serves as the foundational phase in anatomic pathology, enabling pathologists to document key features such as lesion size, location, and gross morphology without reliance on magnification.[6] The primary purposes of gross processing are to gather essential diagnostic information on specimen characteristics, ensure representative sampling for subsequent histology, evaluate tumor margins and staging, and contribute data to the comprehensive pathology report. By systematically assessing tissues, it facilitates accurate pathologic diagnosis, guides therapeutic decisions, and supports compliance with staging protocols, such as those from the American Joint Committee on Cancer.[5] This process also aids in selecting portions for ancillary studies, like molecular testing, while minimizing errors in tissue submission.[2] In up to 90% of cases, gross examination alone can yield a definitive diagnosis or a targeted differential, underscoring its role in efficient patient care.[4] Historically, gross processing evolved from rudimentary autopsy practices in the 19th century, where clinico-pathologic correlations relied on visible morphologic findings to link gross observations with clinical outcomes.[7] Early advancements included the introduction of frozen section techniques in the late 19th and early 20th centuries, such as William Henry Welch's 1891 procedure at Johns Hopkins and Louis B. Wilson's 1905 refinements at the Mayo Clinic, which integrated gross assessment with rapid intraoperative diagnosis.[7] By the mid-20th century, following the establishment of organizations like the College of American Pathologists in 1946, gross processing transitioned to standardized protocols in modern surgical pathology laboratories, emphasizing systematic handling, documentation, and quality assurance.[1] Distinct from microscopic processing, which involves cellular-level analysis via stained slides, gross processing focuses on overt structural features to inform the overall pathology workflow—from specimen receipt and fixation to slide preparation and final reporting. It bridges clinical surgery and detailed histologic evaluation, ensuring that only pertinent tissues proceed to resource-intensive microscopic review.[5][8]

Importance in Pathology

Gross processing plays a pivotal role in pathology by facilitating the initial macroscopic evaluation of tissue specimens, which is essential for detecting abnormalities such as tumors, infections, or processing artifacts that might otherwise compromise diagnostic accuracy. This step allows pathologists to identify gross features like lesion size, shape, and margins, providing critical preliminary insights that guide subsequent microscopic and molecular analyses. In oncology, gross examination directly contributes to cancer staging under the TNM system, where tumor dimensions (T), nodal involvement (N), and evidence of metastasis (M) are often first assessed macroscopically to inform prognosis and treatment planning. For instance, accurate gross measurement of tumor size in fixed specimens helps establish the T category, which may be refined histologically but relies on initial gross impressions for staging reliability.[9][10] Beyond diagnosis, proper gross processing enhances laboratory efficiency by minimizing sampling errors and optimizing tissue allocation for ancillary studies, such as immunohistochemistry or molecular testing, which require well-preserved and representative samples. Inadequate grossing can lead to under-sampling of key areas, contributing to pre-analytic errors that account for a majority (up to 88% in some studies) of all laboratory discrepancies in surgical pathology, as identified in comprehensive error analyses.[11] This underscores its importance in quality control protocols, where standardized grossing procedures, as recommended by the College of American Pathologists (CAP), ensure consistent tissue handling and reduce the risk of diagnostic delays or misinterpretations. By preserving tissue integrity, gross processing also supports the integration of advanced tests, enabling personalized medicine approaches without depleting limited specimen material.[12] From a legal and reporting perspective, the gross description forms a foundational component of the official pathology report, serving as medico-legal documentation that records specimen characteristics for clinical decision-making and potential litigation. Incomplete or erroneous gross examinations can result in malpractice risks, such as failing to document margins or foreign bodies, which may lead to challenges in proving adherence to standards of care. CAP guidelines emphasize thorough gross documentation to mitigate these issues, ensuring traceability and defensibility in legal contexts.[13][14] In broader clinical practice, gross processing accelerates turnaround times, particularly for intraoperative frozen sections, where rapid gross preparation enables results within 20 minutes in 90% of cases, per CAP benchmarks, influencing real-time surgical decisions like margin status or re-excision needs. This efficiency is vital in high-stakes settings, such as tumor resections, where delays could affect patient outcomes, and highlights grossing's role in streamlining workflows to support timely, evidence-based care.[15][16]

Personnel and Responsibilities

Pathologists' Roles

Pathologists serve as the primary overseers of gross processing in anatomic pathology, ensuring the accuracy and diagnostic utility of specimen examinations. They are responsible for supervising all macroscopic tissue examinations, including gross dissection and sampling, to facilitate proper histologic preparation and diagnosis. This oversight extends to performing or directly supervising the final review of gross descriptions and selected sections, particularly in complex cases where anatomical expertise is essential for determining sampling adequacy in resections or biopsies. Additionally, pathologists interpret gross findings to provide preliminary diagnoses, such as during intraoperative consultations involving frozen sections, where results must be signed by a qualified pathologist to confirm diagnostic validity.[17][17][18] Required expertise for these roles stems from specialized training in anatomic pathology, typically acquired through residency programs that emphasize hands-on gross examination of diverse surgical specimens, from biopsies to large resections. This education equips pathologists with the skills to make critical decisions on tissue sampling, ensuring representative sections are submitted for microscopic analysis while minimizing artifacts or diagnostic errors. In challenging scenarios, such as high-risk or ambiguous tissues, pathologists often directly handle the gross evaluation—for instance, assessing whether a surgical margin appears positive based on visible tumor extension to the resection edge, which informs immediate surgical decisions and long-term patient management.[18][19] Regulatory compliance is integral to pathologists' responsibilities, aligning with standards from the College of American Pathologists (CAP) accreditation and the Clinical Laboratory Improvement Amendments (CLIA) of 1988, which classify gross examinations as high-complexity testing requiring pathologist supervision. Pathologists must define in writing the permissible grossing activities and specimen types for non-pathologist personnel, evaluate their performance annually, and document any discrepancies to maintain quality assurance. They also sign off on gross reports to verify compliance with CAP protocols, such as fixation guidelines and cancer checklists, thereby ensuring the integrity of the diagnostic process across accredited laboratories.[17][13][17]

Assistants and Technicians' Roles

Pathologists' assistants (PAs) play a critical role in the gross processing workflow by performing hands-on tasks such as the initial dissection of surgical specimens, preparation of tissue sections for microscopic examination, and dictation of preliminary gross descriptions under pathologist supervision.[20] These professionals handle a significant portion of routine and complex gross examinations, including frozen sections during intraoperative consultations, which require precise tissue sampling to facilitate rapid diagnostic feedback.[21] PAs also contribute to specimen triage, photography, and ensuring proper tissue submission for further processing, thereby supporting the efficiency of high-volume pathology laboratories.[20] In contrast, grossing technicians focus on foundational aspects of specimen preparation, including routine measurements of tissue samples, application of inks to delineate margins, and assembly of cassettes for embedding and sectioning.[22] Their duties typically involve accessioning specimens, describing basic gross features of low-complexity biopsies, and maintaining the grossing area's organization, all performed under direct oversight to ensure compliance with laboratory standards.[22] Unlike PAs, technicians are generally limited to straightforward cases and do not perform advanced procedures like frozen sections or autopsies.[22] Training for PAs emphasizes advanced education through two-year NAACLS-accredited master's programs, which include coursework in anatomic pathology, surgical techniques, and laboratory management, culminating in eligibility for ASCP Board of Certification.[23] This specialized preparation enables PAs to undertake a broader scope of responsibilities compared to grossing technicians, who typically require an associate degree or equivalent per CAP guidelines and may hold certifications such as ASCP's Histotechnician (HT), though no dedicated national credential exists for grossing alone.[22] In high-volume labs, effective teamwork between PAs, technicians, and pathologists is essential, with technicians handling preparatory tasks to allow PAs to focus on more intricate dissections.[20] Due to ongoing pathologist shortages, particularly noted in studies from 2020 onward, there has been increased delegation of gross processing duties to PAs, enhancing laboratory throughput amid rising caseloads and workforce declines projected at 7% by 2035.[21] This shift has improved grossing efficiency, with productivity often measured via dissection time values (DTVs), where standardized metrics from large-scale analyses show PAs processing specimens at rates equivalent to reclassifying many types to lower complexity levels based on actual times under 420 minutes per working day.[24] Such metrics underscore the value of PAs in maintaining timely specimen handling, typically achieving 3-5 blocks per hour in routine workflows when supported by technicians.[24]

Specimen Receipt and Preparation

Initial Handling and Verification

Upon receipt in the pathology laboratory, surgical specimens are transported from the operating room either fresh or pre-placed in fixative, using rigid, leak-proof containers to prevent contamination or damage during transit; immediate delivery is prioritized, with refrigeration recommended if delays occur to preserve specimen integrity.[25][26] Logging into the laboratory information system (LIS) follows, where details such as patient identifiers, specimen type, date, time, and transporter information are entered to establish a digital record; this step integrates with chain-of-custody documentation, often via forms or logs that track each hand-off to minimize loss or mishandling.[17][26] Verification begins with confirming patient identity using at least two unique identifiers (e.g., full name and medical record number) against the accompanying requisition form, ensuring the specimen type and source (e.g., biopsy from a specific organ) match clinical details; integrity is assessed by inspecting for leaks, breakage, or contamination, with any discrepancies prompting immediate notification to surgery staff.[25][26] This process, typically performed by pathology assistants or technicians, adheres to standards that reject non-compliant submissions to avoid diagnostic errors.[27] Orientation is noted at receipt, documenting surgical markers such as proximal/distal or medial/lateral to guide subsequent examination, while containers receive unique barcode or permanent ink labels including patient ID, specimen source, collection date/time, and preservative used.[25][26] Biohazards are managed per OSHA guidelines under the Bloodborne Pathogens Standard (29 CFR 1910.1030), requiring secondary containment bags, personal protective equipment, and spill protocols to protect handlers from exposure during transport and initial unpacking.[28][26] Common issues include transport delays, which can degrade fresh specimens if not refrigerated, and mislabeling or identification mismatches, occurring at rates of approximately 0.09% (0.92 per 1000 labels) based on 2008 CAP Q-Probes benchmarking data across pathology labs; such errors are addressed through immediate reconciliation, barcode verification systems, or specimen rejection to prevent downstream analytic failures.[29][30]

Fixation and Documentation

Fixation in gross processing begins immediately upon specimen receipt to preserve tissue morphology and prevent autolysis or degradation. The primary fixative used is 10% neutral buffered formalin (NBF), which cross-links proteins to stabilize cellular structures for subsequent microscopic examination.[25] Specimens are submerged in a volume of fixative at least 15-20 times the tissue volume to ensure adequate penetration, with fixation initiated as soon as possible—ideally within minutes—for unfixed tissues to halt enzymatic activity.[25] For optimal results, a minimum of 6 hours of fixation is required, though complete fixation for 4 mm thick sections typically takes about 24 hours, and durations up to 48 hours are standard for most clinical specimens to achieve uniform preservation without over-fixation artifacts.[25] Alternatives to formalin are employed for specific studies, such as immunohistochemistry (IHC) or molecular analyses, where formalin may mask antigenic sites. Alcohol-based fixatives, including ethanol-methanol mixtures or alcohol-polyethylene glycol formulations, serve as effective substitutes by coagulating proteins without aldehyde-induced modifications, preserving morphology and enhancing antigen retrieval in special procedures.[31] These alternatives require adjusted protocols, such as shorter immersion times, to avoid tissue shrinkage. Documentation accompanies fixation to ensure traceability and compliance with quality standards. Upon receipt, details such as the date and time of arrival, fixative type and volume added, cold and warm ischemic times, and any noted discrepancies from the requisition are recorded via dictation, electronic entry, or requisition annotations.[25][32] Total fixation duration is also documented in the pathology report to support diagnostic accuracy and regulatory audits.[25] Adherence to College of American Pathologists (CAP) protocols is essential, mandating standardized fixation times—such as 6-72 hours for breast tissue to optimize hormone receptor testing—and verification of environmental conditions during processing to prevent degradation.[25] These guidelines, including CAP checklist items like ANP.22983 for breast fixation, underscore the rationale of timely fixation to maintain tissue integrity for reliable histopathological interpretation.[25] Special considerations distinguish handling of fresh versus fixed specimens. Fresh tissues, often received unfixed for intraoperative consultations like frozen sections, must be kept moist with saline-soaked gauze and transported rapidly under refrigeration if delayed, with residual material fixed post-procedure for permanent sections.[25] Fixed specimens, in contrast, are stored in rigid, leak-proof containers to protect against drying or contamination, facilitating deferred gross examination while ensuring long-term stability.[25]

Gross Examination and Description

Measurement and Visual Assessment

In gross processing, measurement techniques begin with the use of rulers or calipers to record the specimen's dimensions in three planes, typically expressed in centimeters for length, width, and depth, ensuring precise documentation of size for diagnostic correlation. Scales are employed to determine weight in grams, particularly for organs or large resections where mass provides additional context for pathological assessment. Volume estimation, when relevant, may involve displacement methods or calculated approximations from dimensional data, though it is less routinely quantified unless specified by protocol. These measurements are performed prior to any dissection to capture the specimen's native state post-fixation. Visual inspection involves a systematic evaluation of the specimen's external and cut surfaces under adequate lighting to note key morphological features. Color variations, such as tan, yellow, white, or hemorrhagic red, are described to indicate potential pathological processes like ischemia or inflammation. Texture and consistency are assessed by gentle palpation, categorizing the tissue as firm, soft, rubbery, fleshy, or friable, which helps differentiate between neoplastic, inflammatory, or degenerative changes. Surface features, including ulceration, necrosis, or focal lesions, are observed and their locations relative to anatomical landmarks recorded; for instance, tumor size is estimated visually or measured directly if discrete, aiding in staging and margin proximity evaluation without invasive sampling. Descriptive standards for gross reports adhere to structured formats like those outlined in the College of American Pathologists (CAP) cancer protocol templates, which mandate inclusion of tumor dimensions in centimeters and qualitative visual elements such as the presence or absence of gross necrosis. Synoptic reporting ensures completeness by prompting specific fields for measurements and observations, reducing variability in documentation across cases. For complex specimens, photographs with a centimeter scale bar are recommended to supplement textual descriptions, providing a visual record that enhances reproducibility and supports multidisciplinary review. Challenges in measurement and visual assessment include accounting for fixation artifacts, such as tissue shrinkage of approximately 10-20% in linear dimensions due to formalin processing, which can alter perceived size and require adjustments for accurate in vivo correlation. Ensuring reproducibility demands standardized terminology and protocols to minimize inter-observer variability, as subjective elements like consistency assessment can differ without training.

Inking and Margin Evaluation

In gross processing, inking involves applying specialized dyes to the resection surfaces of surgical specimens to demarcate and orient the margins for subsequent microscopic evaluation. Commonly used inks include India ink and acrylic-based tissue-marking dyes, with multiple colors such as black for deep margins, blue for lateral margins, green for medial, and red or yellow for superficial or anterior aspects, allowing precise identification of each surface.[33][34] The ink is typically applied using a cotton swab, brush, or toothpick immediately after excision or upon receipt in the pathology lab, followed by air-drying for 5-10 minutes to prevent smearing during fixation; this superficial penetration, often limited to 0.5-1 mm, ensures visibility without deep tissue diffusion that could obscure histological details.[33][35] Multi-color coding enhances specimen orientation by assigning distinct hues to specific anatomical surfaces, facilitating accurate correlation between gross findings and microscopic sections, particularly in complex resections like those from the breast or head and neck.[35] Over-inking must be avoided, as excessive application can lead to ink seepage into adjacent tissue or contamination of processing fluids, potentially interfering with immunohistochemical staining or causing artifactual obscuration of tumor margins under the microscope; labs standardize color protocols and use minimal volumes to mitigate this.[35][33] Margin assessment at the gross level relies on visual inspection of the inked surfaces to gauge tumor proximity to the edges, guiding decisions on additional sampling or reporting. A margin is grossly considered "close" if the tumor extends within 5 mm of the inked edge, though this threshold varies by tumor type and site—such as <1 mm for colorectal carcinoma or 1-5 mm for oral squamous cell carcinoma—prompting closer microscopic scrutiny.[36][37] In cases following neoadjuvant therapy, such as breast-conserving surgery for carcinoma, inking plays a critical role by enabling the application of the "no tumor on ink" criterion, which defines an adequate margin and has been shown to reduce re-excision rates by up to 50% compared to standard post-fixation inking.[38][39] Studies demonstrate that proper inking protocols significantly decrease margin misinterpretation; for instance, intraoperative multi-color inking has been associated with lower positive margin rates (23% vs. 46%) and reduced reoperation needs, while color discrimination analyses highlight how standardized inks minimize identification errors during pathological review.[38][40]

Dissection and Sectioning

General Dissection Techniques

General dissection techniques in surgical pathology involve a systematic process of opening, exploring, and sampling specimens to identify and select representative tissue portions for microscopic examination, ensuring accurate diagnosis while optimizing fixation and processing efficiency. This approach begins with careful incision using scalpels or knives to serially slice tissues, allowing visualization of internal structures, lesions, and margins without compromising integrity. A key principle is the adoption of standardized methods like bread-loafing, where the specimen is cut into parallel slices perpendicular to the longest axis, facilitating uniform exposure to fixative and comprehensive assessment of pathological features. For instance, in prostatectomy specimens, the prostate is serially sectioned from apex to base in 3 mm slices perpendicular to the urethral axis after inking the surfaces, enabling evaluation of tumor extent and extraprostatic extension.[41] Sampling strategies emphasize selecting portions that capture the heterogeneity of the specimen, prioritizing areas of interest such as tumors, interfaces between normal and abnormal tissue, and representative normal regions to avoid sampling bias. A common guideline is to submit at least one section per centimeter of the tumor's greatest dimension, including sections from necrotic areas, viable tumor, and adjacent non-neoplastic tissue to provide diagnostic context.[42] This minimum ensures sufficient material for histologic evaluation while balancing workload; for smaller lesions under 2 cm, entire submission may be warranted, whereas larger tumors require focused sampling of heterogeneous zones. These strategies align with protocols that promote representative analysis, reducing the risk of understaging or missing multifocal disease.[43] Specimen-specific techniques adapt these principles to tissue characteristics for optimal handling. For hollow organs like the colon, the structure is opened along the antimesenteric border to expose the mucosa, which may be inked separately to delineate luminal surfaces from serosal margins, enhancing penetration of fixative and identification of mucosal lesions.[44] In fatty tissues, such as breast mastectomy specimens, bread-loafing is employed by serially sectioning from medial to lateral in 5-10 mm intervals starting at the deep margin, allowing assessment of tumor relationships to fatty stroma despite challenges in cutting dense adipose; extended fixation times are often required due to poor fixative diffusion in fat.[45] For lymph nodes, nodes are dissected from surrounding adipose tissue, measured, and if no gross metastasis is evident, the entire node is submitted in 2-3 mm slices; any suspicious extranodal fat is included in separate cassettes to evaluate potential infiltration.[46] In high-volume laboratories, efficiency is critical, with gross dissection allocated time based on specimen complexity to maintain turnaround times without sacrificing quality. This involves prioritizing urgent specimens, using standardized protocols to streamline workflows, and conducting annual performance reviews of grossing personnel to optimize processes like serial sectioning and sampling. Such time management supports high daily caseloads while ensuring compliance with accreditation standards and minimizing delays in diagnosis.[24]

Sectioning Methods

Sectioning methods in gross processing involve preparing thin slices of tissue for embedding and microscopic examination, with the primary goal of accurately assessing surgical margins relative to lesions such as tumors. The two main techniques are perpendicular sectioning and en face (tangential) sectioning, each offering distinct advantages in evaluating margin involvement and lesion extent.[47] Perpendicular sectioning is performed by cutting slices orthogonal to the margin plane, enabling precise measurement of the distance between the lesion and the margin, often reported in millimeters for prognostic and therapeutic purposes.[48] This method is particularly useful in cases where exact quantification is required, such as small lesions where margin clearance directly impacts staging and reporting.[47] In contrast, en face sectioning involves parallel cuts to the margin surface, incorporating the entire margin into the section for comprehensive evaluation. Subtypes include shaved (superficial) sections, which capture the outermost layer of the margin, and deep sections, which target subsurface areas for broader coverage of potential involvement. This approach maximizes the sampled surface area, making it suitable for detecting multifocal or infiltrative pathology, though it does not allow direct distance measurement.[49] For instance, in breast specimens, en face sectioning can examine 12% of the surface, providing greater sensitivity for identifying residual disease compared to perpendicular methods, which sample only about 1.8% of the surface with standard 3 mm thickness.[49] Selection of the method depends on lesion characteristics, specimen size, and clinical context. Perpendicular sectioning is preferred for small lesions or when precise distance measurement is critical, such as in colorectal resections where tumor-to-margin distance informs radicality assessment. En face sectioning is favored for large surfaces like skin excisions or breast lumpectomies, where broad margin evaluation is needed; for example, in skin biopsies of basal cell carcinoma, it is indicated when the tumor is more than 2 cm from the resected ends or the specimen is extensive, allowing evaluation of irregular infiltrative patterns.[48][33] Pros of perpendicular sectioning include accurate quantification and anatomical orientation, while cons involve limited surface sampling that may miss subtle involvement. En face offers superior coverage and sensitivity but risks underestimating deep extension without distance metrics.[33] The College of American Pathologists (CAP) recommends flexibility in choosing between perpendicular and en face approaches for margin evaluation, emphasizing that sections should be taken to assess involvement by invasive carcinoma or ductal carcinoma in situ, with radial margins considered negative if tumor is greater than 1 mm from the inked surface.[48] In practice, tumor-to-margin diagrams—such as those depicting orthogonal cuts revealing a 2 mm clearance versus tangential slices showing full surface ink exposure—illustrate these differences, aiding pathologists in documentation and correlation with imaging. As of March 2025, CAP has updated cancer protocols, including those for breast biomarkers, to align with current standards, though core sectioning recommendations remain consistent with prior guidelines.[50][48][49]

Equipment and Safety

Tools and Materials

Gross processing in surgical pathology relies on a variety of basic tools essential for precise specimen handling and dissection. Scalpels with interchangeable blades, forceps for tissue manipulation, scissors for cutting, and probes for exploration form the core set, enabling accurate incision and separation without damaging delicate structures.[17][51] These instruments are typically made of stainless steel for durability and ease of cleaning. Measurement devices are critical for documenting specimen characteristics, including rulers or calipers for linear dimensions and balances for weight assessment, ensuring compliance with standardized protocols.[17] Cutting boards, such as those made from cork, plastic, or self-healing materials, provide a stable, non-slip surface to protect underlying workspaces during sectioning.[52] Key materials include plastic embedding cassettes, typically measuring approximately 37 × 28 × 5 mm (length × width × height) to allow fixative penetration while holding tissue samples securely during processing.[51][17] Inks in multi-color sets—commonly six colors like black, blue, green, red, yellow, and orange—are applied to surgical margins to distinguish orientations and facilitate microscopic correlation.[17] Fixatives, primarily 10% neutral buffered formalin stored in leak-proof containers, are used to preserve specimens at a volume ratio of 15-20:1 (fixative volume to tissue volume).[17] Sponges or absorbent pads aid in specimen orientation within cassettes, preventing movement during transport and embedding.[53] Advanced equipment enhances efficiency and documentation in gross processing. Dictation systems allow for real-time verbal recording of descriptions, reducing errors in reporting.[17] Macro photography setups, including cameras with macro lenses and standardized lighting, capture high-resolution images for records and consultations.[17] Ventilation hoods with laminar down-draft systems are installed over workstations to mitigate exposure to formalin fumes and aerosols.[51] Cost considerations often favor reusable scalpel handles paired with disposable blades, as the latter reduce cross-contamination risks while keeping per-use expenses lower than fully disposable systems in high-volume labs.[54] Maintenance protocols ensure tool integrity and prevent contamination. Instruments like scalpels and forceps undergo sterilization via autoclaving after each use, with handles designed for repeated processing to maintain sharpness and hygiene.[55] Inventory management involves regular stock checks of blades, inks, and cassettes, alongside documentation to track usage and expiration dates, aligning with laboratory accreditation standards.[17]

Safety Protocols and Best Practices

In gross processing, biohazard safety is paramount due to the handling of potentially infectious human tissues, requiring the use of personal protective equipment (PPE) such as gloves, gowns, masks, and goggles to minimize exposure to bloodborne pathogens.[56] Fume hoods must be employed during formalin fixation to control airborne concentrations, adhering to the Occupational Safety and Health Administration (OSHA) permissible exposure limit of 0.75 parts per million (ppm) as an 8-hour time-weighted average and a short-term exposure limit of 2 ppm over 15 minutes, as formaldehyde is a known carcinogen.[57] Sharps disposal protocols are essential to prevent needlestick injuries, involving the use of puncture-resistant containers that are not overfilled and replaced routinely, in line with OSHA and Centers for Disease Control and Prevention (CDC) guidelines to reduce injury risks from contaminated needles and blades.[58][59] Best practices in gross processing emphasize workflow standardization to enhance efficiency and accuracy, including two-person verification for high-risk cases such as those involving infectious agents or complex specimens to mitigate identification errors.[60] Checklists are widely recommended to reduce procedural errors, covering steps from specimen receipt to sectioning, as part of lean and Six Sigma methodologies adapted for pathology labs.[60] Quality metrics, such as turnaround time (TAT), are critical for reliability; as a quality metric, the College of American Pathologists recommends that at least 90% of routine cases achieve a TAT of two business days or less from accession to report, with biopsies specifically targeted for availability within two days to support timely clinical decisions.[61][62] Common pitfalls in gross processing include over-fixation, which can degrade tissue antigens and compromise downstream immunostaining quality by altering protein structures, and under-sampling, where insufficient tissue sections lead to missed diagnostic features and contribute to specimen-related errors.[63][11] These issues underscore the need for standardized fixation times and representative sampling protocols to ensure diagnostic integrity. Adaptations from the 2020s, particularly during the COVID-19 pandemic, have enhanced protocols for infectious specimens in gross processing, such as mandating 24-hour formalin fixation prior to examination (except for frozen sections) and frequent glove disinfection with 70% ethanol every 30 minutes to reduce viral transmission risks.[64][65] Training for gross processing staff includes annual competency assessments to verify proficiency in safety procedures and technical skills, as outlined in CAP frameworks that emphasize risk-based PPE use and procedural adherence.[66] Ergonomics training is also prioritized to prevent repetitive strain injuries in gross rooms, focusing on adjustable workstations and proper posture during prolonged dissection tasks, with programs highlighting risk identification in healthcare settings.[67][68]

References

  1. Grossing in Pathology: Past, Present and Future - Cirdan
  2. THE EFFICIENT OPERATION OF THE SURGICAL PATHOLOGY ...
  3. Gross Pathology: An In-depth Overview - ORNet
  4. Gross examination - PubMed
  5. Asking the PRIME questions for grossing: Teaching a framework for ...
  6. [PDF] Overview of Anatomic and Clinical Pathology
  7. ORIGIN AND DEVELOPMENT OF AMERICAN SURGICAL ...
  8. [PDF] Practical Guide to Specimen Handling in Surgical Pathology
  9. TNM Classification - StatPearls - NCBI Bookshelf - NIH
  10. [PDF] Principles of Cancer Staging - The American College of Surgeons
  11. Errors in Surgical Pathology Laboratory - IntechOpen
  12. Interpretive Diagnostic Error Reduction
  13. Surgical Pathology Specimens for Gross Examination Only and ...
  14. General Advice on Gross Examination - Essential Pathology
  15. Intra-Operative Frozen Section Consultation: Concepts, Applications ...
  16. An audit of frozen section consultations in a tertiary care center
  17. [PDF] Practical Guide to Specimen Handling in Surgical Pathology
  18. Anatomic Pathology Rotations - Emory School of Medicine
  19. Role of the Surgical Pathologist in the Diagnosis and Management ...
  20. Pathologists' Assistants: A Profession Comes to Maturity - PMC - NIH
  21. Bridging the Workforce Gap - The Pathologist
  22. Grossing Technician Duties and Responsibilities
  23. The Pathologist's Assistant
  24. Gross Dissection Time Values of Pathologists' Assistants ... - PubMed
  25. [PDF] Practical Guide to Specimen Handling in Surgical Pathology
  26. [PDF] Standards of Practice for Handling and Care of Surgical Specimens ...
  27. Enhancing preanalytic surgical specimen management
  28. https://www.osha.gov/laws-regs/regulations/standardnumber/1910/1910.1030
  29. Specimen Labeling Errors: A Q-Probes Analysis of 147 Clinical ...
  30. Specimen labeling errors: a Q-probes analysis of 147 clinical ...
  31. Establishment of the formalin-free surgical pathology ... - PubMed
  32. [PDF] Grossing Manual.pdf - National Cancer Institute
  33. Margins in Skin Excision Biopsies: Principles and Guidelines - PMC
  34. Grossing & features to report - Pathology Outlines
  35. Inking in Surgical Pathology: Does the Method Matter? A Procedural ...
  36. Surgical margins - Libre Pathology
  37. Definition of “Close Margin” in Oral Cancer Surgery and Association ...
  38. The effect of intraoperative specimen inking on lumpectomy re ...
  39. [PDF] Breast Cancer Breast Conservation Surgery Margins
  40. Recognition and Discrimination of Tissue-Marking Dye Color by ...
  41. Prostate: Prostatectomy | Gross Pathology Manual - UChicago Voices
  42. [PDF] Protocol for the Examination of Resection Specimens From Patients ...
  43. [PDF] General Approach to Surgical Pathology Specimens
  44. Intraoperative evaluation of surgical margins in breast cancer
  45. Mastectomy | Gross Pathology Manual
  46. Gross processing - patholines.org
  47. [PDF] CAP Cancer Protocol Colon - College of American Pathologists
  48. Imaging‐Assisted Large‐Format Breast Pathology: Program ...
  49. The gross room/surgical cut-up - Basicmedical Key
  50. Grossing and Trimming Knives, Scissors and Boards - Ted Pella
  51. Grossing Tools - Forceps, Scalpels & Scissors - Newcomer Supply
  52. A cost comparison of disposable vs reusable instruments ... - PubMed
  53. Surgical Grossing of Tissue - Avantik
  54. Biosafety for lab and pathology
  55. https://www.osha.gov/laws-regs/regulations/standardnumber/1910/1910.1048
  56. [PDF] Protecting Yourself When Handling Contaminated Sharps - OSHA
  57. Sharps Safety Program Resources | Infection Control - CDC
  58. Lean workflow / Six Sigma - Pathology Outlines
  59. Reducing turnaround time of surgical pathology reports in ... - NIH
  60. [PDF] CAP QCDR Measure Turnaround Time (TAT) - Biopsies
  61. [PDF] Best practices-Histology
  62. The Anatomic Pathology laboratory adjustments in the era of COVID ...
  63. Lessons Learned From an Anatomic Pathology Department in a ...
  64. [PDF] Competency Model for Pathologists
  65. How to Ergonomically Configure Your Grossing Station
  66. https://www.labce.com/ergonomics_for_healthcare_personnel.aspx
User Avatar
No comments yet.