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Pathology

Pathology is the branch of medical science that involves the and of through the examination of surgically removed organs, tissues, bodily fluids, and whole bodies (). It serves as the bridge between science and medicine, underpinning every aspect of patient care by providing diagnostic information essential for decisions. Derived from the Greek word pathología meaning " of ," pathology focuses on the causes (etiologies), development (), and structural and functional changes caused by . Pathology encompasses several key sub-disciplines, including anatomical pathology, which examines tissues and organs at gross and microscopic levels to identify abnormalities such as cancer; clinical pathology, which analyzes blood, urine, and other fluids for biochemical, immunologic, and molecular markers; and molecular pathology, which applies genetic and molecular techniques to detect disease-specific alterations for precision medicine. Other branches include cytopathology, focusing on individual cells for diagnoses like infections and malignancies; hematopathology, dealing with blood disorders; and microbiology, addressing infectious agents. These areas often overlap, with pathologists using advanced tools like digital imaging, AI, and genomic sequencing to enhance accuracy and speed. In clinical practice, pathologists collaborate with surgeons, oncologists, radiologists, and other physicians to guide patient management, from confirming diagnoses to predicting responses and prognoses. For instance, the vast majority of cancer diagnoses are made by pathologists, influencing therapy choices and outcomes. Historically, pathology evolved from ancient humoral theories to modern scientific approaches starting in the , integrating , , and to advance healthcare and innovation, such as vaccine development and infection control. Today, it remains indispensable, impacting nearly all aspects of while driving personalized and preventive care strategies.

Introduction

Definition and Etymology

Pathology is the branch of medical science that studies the causes, development, processes, and effects of , serving as the for understanding abnormal conditions in living organisms. This discipline systematically examines the essential nature of , including their structural and functional manifestations, to inform , treatment, and prevention strategies. Central to pathology are four key aspects: etiology, which identifies the initiating causes of ; pathogenesis, describing the step-wise mechanisms of development; morphologic changes, encompassing the structural alterations at cellular, , and organ levels; and functional consequences, which detail the resulting impairments in physiological processes. These elements provide a comprehensive framework for analyzing how normal biological functions deviate into pathological states. For instance, branches such as apply these aspects to examination, while focuses on laboratory-based assessments. The term "pathology" originates from the Ancient Greek words pathos (πάθος), meaning "" or "disease," and logos (λόγος), meaning "study" or "discourse," thus denoting the scientific study of disease and its effects. This etymology reflects the discipline's historical emphasis on investigating the origins and impacts of in the body. At its core, pathology conceptualizes disease as a disruption of —the of physiological processes that maintains health—leading to adaptive or maladaptive responses in tissues and organs.

Scope and Importance

Pathology encompasses the and of through the of tissues, cells, and bodily fluids, enabling the of diseases based on their morphological, molecular, and functional characteristics. This discipline involves histopathological examination of tissue specimens to identify abnormalities such as tumors or inflammatory conditions, cytological of cellular samples for early detection of malignancies, and evaluation of fluids like blood or for biochemical and microbiological insights. Such methods support disease using standardized criteria that integrate cellular and molecular data, facilitating precise categorization for clinical management. Beyond core diagnostics, pathology contributes to by revealing patterns and through population-level and fluid analyses, while advancing via molecular testing that predicts individual responses to therapies, such as targeted cancer treatments. In healthcare, pathology informs approximately 70% of clinical decisions, providing essential data for applications like , which determines intensity, and identification, which guides . These contributions are bolstered by pathology's low rates, with studies reporting clinically significant diagnostic typically under 1%, which help minimize overall misdiagnosis risks compared to broader rates of 5-15%. In , pathology plays a pivotal role during crises, as evidenced by its contributions to responses through histopathological analysis of lung tissues to characterize viral damage and inform diagnostic criteria, alongside supporting development by elucidating pathogenesis via studies. This integrative approach not only enhances outbreak surveillance but also accelerates therapeutic innovations by linking microscopic findings to epidemiological trends.

History

Early Developments

The origins of pathology trace back to ancient civilizations, where early physicians began associating clinical symptoms with internal organ dysfunction through observation and rudimentary examinations. In around 2600 BCE, , revered as a and , is traditionally credited with foundational medical insights, including the , which systematically links external injuries to internal anatomical disruptions, such as head trauma affecting brain function and spinal injuries causing paralysis. This text, dating to approximately 1600 BCE but drawing on earlier knowledge, represents one of the earliest attempts at empirical pathology by describing diagnoses based on observable signs rather than solely magical interventions. In , (c. 460–370 BCE) advanced this observational approach by rejecting supernatural explanations for diseases in favor of natural etiologies, emphasizing environmental factors, diet, and bodily imbalances as causes of illness. In his treatise , he argued that conditions like arose from natural processes, such as affecting the , marking a shift toward rational pathology grounded in and symptom correlation. This Hippocratic method laid the groundwork for clinical reasoning without , focusing on holistic patient to understand progression. During the medieval period, Islamic scholars built upon these foundations, integrating Greek knowledge with systematic descriptions of pathological changes. (Ibn Sina, 980–1037 CE) in his detailed tissue alterations in various diseases, classifying pathologies by humoral imbalances and organ-specific changes, such as and suppuration, which influenced for centuries. In Europe, post-mortem examinations emerged in 14th-century , particularly at the around 1270 CE, where dissections of human cadavers allowed direct correlation of gross anatomical findings with disease states, often for legal and pedagogical purposes. A pivotal transition occurred in the Renaissance with Andreas Vesalius (1514–1564), whose 1543 work De Humani Corporis Fabrica revolutionized through precise illustrations and dissections, providing a reliable basis for correlating normal structure with pathological deviations. This emphasis on accurate anatomical knowledge bridged early observational pathology to later cellular theories, such as Rudolf Virchow's 19th-century contributions.

Modern Era

The modern era of pathology, spanning the 19th and early 20th centuries, marked a profound shift from empirical observations to a scientifically grounded discipline, emphasizing cellular and microbial mechanisms of disease. This period saw the establishment of pathology as a foundational medical , driven by key theoretical advancements and the institutionalization of pathological practices. A pivotal contribution was Rudolf Virchow's development of cellular pathology, articulated in his 1858 publication Die Cellularpathologie in ihrer Begründung auf physiologische und pathologische Gewebelehre. Virchow posited the principle "omnis cellula e cellula" (every cell arises from a preexisting ), fundamentally redirecting pathological inquiry from humoral imbalances to cellular abnormalities as the basis of disease. This framework, building on earlier advances, emphasized that diseases manifest through disruptions in cellular structure and function, laying the groundwork for . Parallel to cellular theory, the revolutionized pathology by identifying microorganisms as causal agents. In the 1860s, Pasteur's experiments on and demonstrated that specific microbes could invade the body and induce illness, disproving and establishing a microbial for infectious diseases. Building on this, formalized the link between microbes and pathology in 1876 through his eponymous postulates, which required isolating a from a diseased , culturing it, reproducing the disease in a healthy , and re-isolating the same —criteria that enabled the rise of as a subfield of pathology. Institutional developments further solidified pathology's scientific maturation. The establishment of dedicated pathology departments, such as the one at in 1889 under William Henry Welch, integrated pathological research with and clinical practice, fostering systematic studies and laboratory diagnostics. Concurrently, advancements in staining techniques, notably the hematoxylin-eosin (H&E) method refined by in the 1880s, allowed for clearer visualization of cellular details in tissues, becoming a standard tool for histopathological examination. These innovations, rooted in early practices, transformed pathology into a rigorous, evidence-based field essential to modern .

Recent Advances

In the 21st century, has revolutionized diagnostic workflows through advancements in whole-slide imaging (WSI), which digitizes entire glass slides into high-resolution images for analysis on digital platforms. The U.S. (FDA) first approved WSI systems for primary diagnostic use in 2017 with the clearance of the IntelliSite Pathology Solution, marking a shift from traditional to computational review. By 2025, expansions in WSI included high-volume like Roche's VENTANA DP 600, enabling efficient processing of large slide volumes for routine clinical diagnostics. These developments facilitate remote consultations and collaboration among pathologists, improving access in underserved areas and integrating seamlessly with telepathology systems. Building on WSI, regulatory approvals in 2025 have accelerated the adoption of AI-assisted companion diagnostics in , enhancing precision in cancer subtyping and treatment selection. For instance, received FDA Breakthrough Device Designation on April 29, 2025, for the VENTANA TROP2 (EPR20043) RxDx Device, an AI-driven companion diagnostic for non-small cell (NSCLC) that combines immunohistochemical assays with to identify TROP2 expression levels more accurately than manual methods, aiding selection of patients for TROP2-targeted therapies such as datopotamab deruxtecan. These approvals underscore AI's role in standardizing interpretations and reducing inter-observer variability in oncologic pathology. Artificial intelligence integration, particularly through foundation models, has further transformed histopathology by enabling automated pattern recognition and predictive analytics. The Virchow foundation model, released in 2024 by Paige.AI, represents a landmark with its 632 million parameters pretrained on over 1.5 million whole-slide images across diverse tissues, achieving state-of-the-art performance in pan-cancer detection comparable to clinical-grade tools. This model excels in identifying subtle histopathological features, such as tumor microenvironments, and supports downstream tasks like predicting tumor aggressiveness in and cancers, thereby aiding prognostic stratification. In practice, AI tools like Virchow accelerate diagnostic workflows by automating slide triage and region-of-interest highlighting, reducing turnaround times for pathology reports and alleviating pathologist workload in high-volume settings. Further advancements include the August 2025 FDA clearance expansion for PathAI's AISight Dx to support VENTANA DP 200 and DP 600 scanners, enhancing AI applications in primary diagnosis. Advances in precision medicine have leveraged multi-omics approaches to integrate genomic, proteomic, and other data layers, providing deeper insights into disease mechanisms and personalized therapies. A key example is the 2024 consensus recommendations from the Association for Molecular Pathology and American College of Medical Genetics on DPYD genotyping, which guides dosing of fluoropyrimidine chemotherapies to predict and mitigate severe toxicity risks based on dihydropyrimidine dehydrogenase enzyme variants. This genotyping, often performed via targeted next-generation sequencing (NGS), exemplifies how pharmacogenomic profiling refines treatment in oncology by correlating genetic markers with adverse drug reactions. Complementing this, NGS-based detection of antimicrobial resistance (AMR) markers has advanced rapidly, with 2024 studies demonstrating high-accuracy prediction of bacterial susceptibility using whole-genome sequencing, enabling tailored antibiotic stewardship in infectious disease pathology. These multi-omics strategies, rooted in molecular pathology foundations, enhance diagnostic specificity and support evidence-based interventions across clinical scenarios. In November 2025, Labcorp announced a collaboration with Roche to advance digital pathology capabilities, further integrating AI and WSI into clinical workflows.

Branches of Pathology

General Pathology

General pathology examines the basic mechanisms of processes that apply universally across tissues and organs, emphasizing cellular responses to injurious stimuli and the progression from to . It provides the foundational understanding of how cells and tissues react to stress, forming the basis for all specialized branches of pathology. This field integrates concepts from to systemic consequences, highlighting the dynamic interplay between protective responses and pathological outcomes. Diseases are broadly classified by duration and severity into acute and chronic forms, with acute diseases characterized by rapid onset, short duration (hours to days), and often self-limiting or treatable progression, whereas diseases involve prolonged persistence (months to years) and potential for ongoing remodeling. Cell injury is further delineated as reversible or irreversible; reversible injury, such as cellular swelling or fatty change, allows full recovery if the injurious agent is removed early, but irreversible injury, marked by mitochondrial dysfunction and membrane rupture, leads inexorably to . A central in injury response is , a stereotypic protective orchestrated by , leukocyte emigration, and release; acute inflammation predominates with influx for rapid clearance, while features and accumulation, promoting and repair or destruction. Pathogenesis unfolds in sequential stages starting with etiology—the inciting factors, including genetic predispositions (e.g., mutations) or environmental insults (e.g., toxins or infections)—which trigger cellular adaptations to maintain under stress. Common adaptations include , an increase in cell size due to enhanced protein synthesis in response to workload demands, and , a reduction in cell size and organ mass from disuse, , or nutrient deprivation, both serving as reversible coping strategies. When adaptive capacity is exceeded, cells progress to injury and , distinguished by —an uncontrolled, inflammatory process involving enzymatic digestion, membrane disruption, and leakage of cellular contents—or , a programmed, energy-dependent death pathway activated by intrinsic (mitochondrial) or extrinsic (death receptor) signals, featuring protease activation that cleaves key substrates for orderly dismantling without eliciting . , first morphologically defined in seminal work, ensures tissue by eliminating damaged or superfluous cells through shrinkage, condensation, and formation of apoptotic bodies for non-inflammatory . Systemic effects of unchecked local processes can escalate to life-threatening conditions, including , a circulatory failure with hypoperfusion leading to and organ ischemia; , defined as life-threatening from a dysregulated host response to infection, often involving endothelial damage and microvascular ; and multi-organ dysfunction (MODS), where sequential failure of vital systems (e.g., lungs, kidneys, liver) arises from amplified inflammatory cascades. A key driver in severe sepsis is the , an excessive release of proinflammatory mediators like TNF-α and IL-6, which promotes endothelial activation, , and widespread tissue injury, potentially culminating in refractory and high mortality. These general principles underpin the anatomical manifestations observed in diseased tissues across the body.

Anatomical Pathology

Anatomical pathology is a branch of pathology that involves the of organs, s, and whole bodies to diagnose through gross and microscopic of structural changes. It focuses on the morphological effects of processes, such as alterations in architecture and cellular features, to identify abnormalities like , degeneration, or neoplasia. This discipline plays a crucial role in clinical decision-making by providing definitive diagnoses from surgical specimens, biopsies, and autopsies, guiding treatments ranging from surgical interventions to targeted therapies. Key techniques in anatomical pathology include biopsy, autopsy, and frozen sections, which enable the evaluation of tissue samples at various scales. A involves the removal and microscopic examination of small tissue samples to detect pathological changes, often using with hematoxylin and eosin (H&E) staining as the standard method to visualize cellular details. H&E staining highlights nuclear structures with hematoxylin (blue-purple) and cytoplasmic components with (pink), allowing pathologists to identify cellular —such as irregular nuclear size, shape, and patterns—and signs of , where malignant cells breach membranes and infiltrate surrounding tissues. provide comprehensive post-mortem assessment of systems to determine causes of and study disease progression, while frozen sections offer rapid intraoperative by flash-freezing tissue, slicing it thinly with a , and staining for immediate microscopic review, typically within 15-20 minutes. Subspecialties within anatomical pathology integrate these techniques for targeted applications. Cytopathology examines individual cells from fluid or tissue scrapings, exemplified by the Pap smear test developed in the 1920s by George Papanicolaou, which screens for by detecting atypical squamous cells in vaginal smears, significantly reducing mortality through early identification of precancerous lesions. Surgical pathology assesses resected tissues during operations, including intraoperative margin evaluation via frozen sections to confirm clear tumor boundaries and avoid re-excision, as seen in procedures where positive margins prompt immediate extension of resection. Dermatopathology specializes in skin lesions, analyzing patterns like nested melanocytes in , where irregular, variably sized nests of atypical cells at the dermoepidermal junction distinguish malignant lesions from benign nevi through disrupted epidermal architecture. In its diagnostic role, employs and to assess severity and extent, aiding and therapy planning. Grading evaluates microscopic features like and mitotic activity to classify tumors from well-differentiated (low grade) to poorly differentiated (high grade), while uses the TNM system—where T describes size and depth, N indicates regional involvement, and M denotes distant —to map anatomical spread. Distinguishing benign from malignant tumors relies on criteria such as architectural disruption; benign lesions maintain organized, encapsulated structures with uniform cells, whereas malignant ones show , desmoplastic reactions, and loss of boundaries, often confirmed through H&E-stained sections revealing pleomorphism and .

Clinical Pathology

Clinical pathology, also known as laboratory medicine, encompasses the laboratory-based examination of body fluids, tissues, and other specimens to evaluate biochemical, hematological, and microbiological parameters for disease diagnosis, , and . This discipline focuses on functional and quantitative assessments rather than morphological analysis, providing critical data for clinical decision-making in areas such as infection control, metabolic disorders, and hematologic conditions. Key to its role is the integration of automated analyzers and standardized testing protocols to ensure rapid, accurate results that guide therapeutic interventions. Core divisions within include and . involves the measurement of biochemical markers in blood and other fluids, such as assays for function evaluation; for instance, (ALT) and aspartate aminotransferase (AST) levels are routinely assessed to detect , with elevations indicating hepatocellular damage. , on the other hand, examines blood cell populations and abnormalities through tests like the (CBC) and advanced techniques such as , which uses (CD) markers to subtype leukemias by identifying specific antigen expressions on malignant cells. Microbiology is integrated into for identification and antimicrobial guidance, primarily through and sensitivity testing, which isolates from specimens like or and determines their susceptibility to antibiotics. studies complement these efforts by evaluating hemostatic function; (PT) and the international normalized ratio (INR) are standard tests for assessing clotting disorders, monitoring anticoagulant therapy, and preventing thrombotic complications. Applications of clinical pathology extend to therapy monitoring and supportive care, such as serial measurements to confirm and track , where elevated levels signal damage and inform risk stratification. In , ABO and blood typing ensures compatibility, preventing hemolytic reactions during blood product administration by matching donor and recipient antigens. These analyses often correlate briefly with results to confirm diagnoses in complex cases.

Molecular Pathology

Molecular pathology examines the genetic and molecular alterations underlying disease processes, providing insights into at the DNA, RNA, and protein levels to inform , , and . This subdiscipline integrates advanced genomic techniques to detect , gene amplifications, and other aberrations that drive and other pathologies, enabling precision medicine approaches. By focusing on molecular drivers rather than gross morphological changes, it complements traditional pathology methods and has become essential in and beyond. Fundamental techniques in molecular pathology include polymerase chain reaction (PCR), fluorescent in situ hybridization (FISH), and next-generation sequencing (NGS). PCR, first described in 1985 for amplifying specific DNA sequences such as those associated with sickle cell anemia, allows sensitive detection of genetic variants in pathological samples. FISH visualizes chromosomal abnormalities, such as HER2 gene amplification in , where it identifies increased HER2 copy numbers relative to chromosome 17 centromeres, guiding targeted therapies like . NGS panels enable comprehensive profiling of somatic mutations, exemplified by KRAS alterations in approximately 40% of colorectal cancers, which predict resistance to anti-EGFR therapies and inform treatment decisions. Applications of extend to companion diagnostics and , optimizing therapeutic outcomes while minimizing adverse effects. For instance, detection of the T790M mutation via or NGS serves as a companion diagnostic for in non-small cell patients progressing on first-line inhibitors, with FDA-approved tests confirming eligibility for this third-generation . In , variants in the DPYD gene, which encodes dihydropyrimidine , are assessed to adjust 5-fluorouracil (5-FU) dosing; carriers of deficient alleles (e.g., DPYD*2A) face up to 10-fold higher risk of severe toxicity, prompting dose reductions of 25-50% to prevent life-threatening reactions like and . Emerging innovations include liquid biopsies leveraging (ctDNA) for non-invasive disease monitoring and early detection. These assays analyze ctDNA in to track tumor evolution, treatment response, and without tissue sampling. In 2024, advances in multi-cancer early detection tests using ctDNA and profiling achieved sensitivities exceeding 90% for specific cancers, such as 97.4% for pancreatic ductal and 95% for , with specificities around 92-94%, enhancing prospects for population-level screening.

Specialized Fields

Oral and Maxillofacial Pathology

Oral and maxillofacial pathology is a specialized branch of pathology that focuses on the and of diseases affecting the , jaws, and associated structures, emphasizing their unique epithelial, odontogenic, and salivary origins. This field integrates histopathological analysis with clinical to address conditions arising from tissues such as mucosa, teeth, and salivary glands, which are distinct from broader anatomical pathologies due to their developmental ties to ectodermal and mesodermal elements. Pathologists in this domain examine lesions that can range from benign cysts to malignant neoplasms, often requiring multidisciplinary collaboration with oral surgeons and dentists for accurate management. Among the most prevalent conditions in oral and maxillofacial pathology is oral squamous cell carcinoma (OSCC), which accounts for over 90% of all oral malignancies. Risk factors for OSCC include tobacco use, betel quid chewing, and alcohol consumption, with tobacco exposure linked to approximately 80% of cases through carcinogenic mechanisms like DNA adduct formation. Another significant category involves odontogenic cysts and tumors, such as ameloblastoma, a benign but locally aggressive neoplasm originating from odontogenic epithelium; it frequently harbors BRAF V600E mutations in up to 80% of cases, driving uncontrolled cell proliferation via the MAPK pathway. Salivary gland pathologies, including pleomorphic adenoma—the most common benign tumor of salivary glands—also feature prominently, characterized by mixed epithelial and myoepithelial proliferation often in the parotid or minor oral glands. Diagnostic approaches in oral and maxillofacial pathology rely heavily on incisional or excisional of mucosal lesions to obtain for histopathological evaluation, supplemented by radiographic such as panoramic X-rays or cone-beam computed (CBCT) to assess jaw involvement in cysts or tumors. For salivary gland lesions like , may precede surgical excision, with microscopy revealing chondromyxoid stroma and ductal elements. These methods ensure precise classification, distinguishing odontogenic origins from reactive or inflammatory processes. The clinical uniqueness of oral and maxillofacial pathology lies in its close integration with dentistry, where routine oral examinations by dental professionals enable early detection of lesions, potentially reducing oral cancer mortality by up to 34% in high-risk populations through visual screening programs. This collaborative framework enhances outcomes by facilitating prompt biopsies and interventions, underscoring the field's role in preventive oral health.

Forensic Pathology

Forensic pathology is a subspecialty of pathology that applies medical expertise to legal investigations, primarily determining the cause and manner of death in cases involving suspicious, unnatural, or sudden circumstances. Forensic pathologists perform medicolegal autopsies under legal authority, such as from a coroner or medical examiner, to gather evidence for criminal justice, public health, and civil proceedings. This field distinguishes itself by integrating pathological findings with scene investigation, witness statements, and toxicology to establish facts like identity, time of death, and contributing factors, often in homicides, suicides, accidents, or undetermined cases. Medicolegal autopsies involve systematic external and internal examinations to document injuries and diseases. The external exam includes inspection of clothing, body surfaces, and orifices for , followed by incisions (e.g., Y-shaped or coronal) to access internal structures; this may reveal patterns like defensive wounds or ligature marks. Internal examination employs techniques such as the Virchow method for organ removal and , allowing detailed analysis of vital organs for hemorrhage, fractures, or pathology. screens are integral, collecting samples from blood, urine, vitreous humor, and viscera to detect drugs, alcohol, poisons, or environmental toxins, which can clarify intent or in deaths like overdoses or impaired driving incidents. The is classified into five categories based on circumstances: natural (due to disease or aging, e.g., ); accident (unintentional or without harm intent, e.g., falls or drug errors); (deliberate with >50% evidentiary certainty, e.g., self-inflicted wounds); (death from another's volitional act causing or fear, e.g., assaults, including some actions); and undetermined (when evidence does not favor one category, e.g., ambiguous overdoses). This classification guides legal outcomes and requires preponderance of evidence from , history, and ancillary tests. Key applications include analyzing gunshot wounds to reconstruct events, where pathologists examine entry versus sites—entry wounds show rings and inward beveling, while exits exhibit outward eversion—and trace trajectories through wound alignment, organ damage, and projectile recovery for ballistic matching. Histological examination of skin margins can further distinguish entry from by revealing collagen fiber disruption patterns or deposition, aiding in distance and direction determinations. In cases, diagnostic patterns such as petechiae (pinpoint hemorrhages in conjunctivae, face, or viscera due to venous ) indicate mechanisms like strangulation or compression, while diatom tests detect microscopic in or lungs to confirm by matching environmental samples, though results must exclude . Challenges in forensic pathology arise from post-mortem changes that complicate interpretations, particularly in estimating time since death or assessing injuries. , the stiffening of muscles from ATP depletion, begins 1-2 hours post-mortem in , peaks at 12 hours, and resolves after 24-36 hours, influenced by and activity. , the gravitational settling of blood causing reddish-purple discoloration in dependent areas, appears in patches within 1-3 hours and fixes after 6-12 hours, preventing redistribution if the body is moved; these changes must be differentiated from antemortem lividity or to avoid misclassifying .

Neuropathology

Neuropathology is a specialized branch of dedicated to the study of diseases affecting the and , encompassing neurodegenerative, neoplastic, infectious, and prion-related disorders through histological examination of neural tissues. It focuses on unique pathological processes in the and , such as protein aggregations, glial proliferations, and inflammatory responses, often requiring postmortem analysis or intraoperative biopsies to diagnose conditions that manifest with cognitive, motor, or sensory deficits. Distinct from broader , neuropathology emphasizes the intricate cytoarchitecture of neural tissues and the role of the blood-brain barrier in disease progression. Among major neurodegenerative disorders, Alzheimer's disease exemplifies neuropathological hallmarks including extracellular amyloid-beta plaques and intracellular neurofibrillary tangles composed of hyperphosphorylated tau protein, which correlate with neuronal loss and synaptic dysfunction primarily in the hippocampus and cortex. These features are quantified using the ABC scoring system, where amyloid plaques (A), tau tangles (B), and Braak staging (C) guide diagnosis, with plaques often preceding cognitive symptoms by decades. In gliomas, a common neoplastic process, isocitrate dehydrogenase (IDH) mutations, particularly IDH1 R132H, are pivotal for grading and prognosis; IDH-mutant astrocytomas, graded as WHO grade 2-4, generally have better outcomes compared to IDH-wildtype counterparts, influencing therapeutic decisions like chemotherapy responsiveness. Prion diseases, such as Creutzfeldt-Jakob disease, feature spongiform changes characterized by vacuolation of the neuropil, astrocytic gliosis, and neuronal loss without significant inflammation, often accompanied by amyloid plaques in variant forms. Diagnostic techniques in neuropathology include brain biopsies for intraoperative assessment, where frozen sections reveal neoplastic infiltrates or inflammatory patterns, supplemented by immunohistochemistry using markers like glial fibrillary acidic protein (GFAP) to identify astrocytomas, as GFAP positivity highlights fibrillary processes in neoplastic astrocytes. Cerebrospinal fluid (CSF) analysis detects neuroinflammation through elevated biomarkers such as neopterin or cytokines, indicating microglial activation in conditions like encephalitis, providing a non-invasive correlate to tissue pathology. Molecular markers, such as IDH mutations, are integrated via sequencing to refine glioma classification, aligning with broader molecular pathology approaches. Recent updates, including the 2021 WHO classification with 2024 refinements, emphasize molecular profiling for precise glioma subtyping. A distinctive feature of neuropathology involves the blood-brain barrier's role in infections, where () encephalitis exploits barrier disruption to cause necrotizing , leading to and leukocyte infiltration in the temporal lobes. Autopsies in such cases reveal laminar necrosis, marked by selective cortical neuronal death with relative preservation of deeper layers, often with hemorrhagic components and , underscoring the barrier's vulnerability in viral entry and disease severity.

Education and Practice

Training Pathways

The path to becoming a pathologist begins with , where students complete a , typically in a science-related field, fulfilling pre-medical prerequisites such as one year each of with , with , with , physics with laboratory, mathematics (calculus or statistics), and English composition. These requirements prepare students for admission to , where competition is high, with average GPAs around 3.7 and MCAT scores of 511 for accepted applicants. Following undergraduate studies, aspiring pathologists enroll in a four-year (MD) or (DO) program, which combines foundational sciences in the first two years with clinical rotations in the latter two, including dedicated exposure to pathology through courses on general principles and elective rotations in anatomic or . This curriculum ensures a broad understanding of processes, with pathology rotations emphasizing , , and laboratory diagnostics to build early diagnostic skills. In the United States, postgraduate training occurs through Accreditation Council for Graduate Medical Education (ACGME)-accredited residency programs, which for combined anatomic pathology/clinical pathology (AP/CP) last 48 months, requiring a minimum of 18 months dedicated to AP (covering surgical pathology, autopsy, cytopathology, and forensics) and 18 months to CP (including laboratory management, transfusion medicine, microbiology, and hematopathology), with the remaining 12 months for electives or research. Separate tracks exist for AP-only or CP-only residencies, each spanning 36 months with at least 24 months of core training in the respective area. Residents gain progressive responsibility, starting with supervised case reviews and advancing to independent sign-outs, often handling hundreds of specimens annually to meet ACGME milestones in diagnostic accuracy and procedure performance, such as at least 30 autopsies. Subspecialty training follows residency via ACGME-accredited fellowships, typically lasting 1-2 years, allowing pathologists to focus on areas like molecular genetic pathology (1 year), (1 year), or (2 years). These fellowships emphasize advanced hands-on experience, such as molecular testing protocols or specialized biopsies, preparing trainees for niche roles in academic or clinical settings. Globally, pathways vary, with the relying on ACGME oversight for standardized residency structures. In , the Union Européenne des Médecins Spécialistes (UEMS) Section of Pathology promotes harmonization through guidelines recommending a 5-year specialist , comprising 36-48 months of basic in general pathology (including , molecular techniques, and multidisciplinary ) followed by 12-24 months in areas of interest, with an emphasis on practical exposure to high case volumes, including biopsies and autopsies, to ensure competency. This framework, supported by the European Society of Pathology (), facilitates cross-border recognition while adapting to national systems, such as 5-6 years total in many EU countries.

Accreditation and Certification

In the United States, primary certification in pathology is administered by the American Board of Pathology (ABPath) following completion of accredited residency training, which serves as a prerequisite for eligibility. Candidates must pass a comprehensive written examination and, for anatomic pathology components, a practical examination involving case interpretations. Subspecialty certifications, such as in cytopathology, require additional fellowship training and passing dedicated board examinations; for instance, the first-time pass rate for the cytopathology subspecialty exam averaged 87.7% from 2007 to 2021. Overall, subspecialty exam pass rates across ABPath disciplines have averaged around 89% over the past 15 years. Certification maintenance occurs through the ABPath Continuing Certification (CC) program, a mandatory lifelong process structured in 10-year cycles with triennial reporting milestones. Key components include lifelong learning via continuing medical education (CME), requiring at least 70 credits every two years, of which 80% (56 credits) must be AMA PRA Category 1; cognitive expertise assessed through online longitudinal tools like ABPath CertLink; and practice performance assessments evaluating real-world competency. Professional standing is upheld by maintaining an unrestricted medical license and hospital privileges, with peer attestations confirming ethical practice. Internationally, and vary by region but emphasize rigorous examinations to ensure competency. In the , the Royal College of Pathologists (RCPath) oversees the Fellowship of the Royal College of Pathologists (FRCPath) qualification, comprising Part 1 written exams in basic sciences and Part 2 exams including written papers and practical orals tailored to 23 pathology specialties. The FRCPath signifies readiness for consultant-level practice and is required for entry onto the General Medical Council's specialist register. Globally, the (WHO) promotes standardized laboratory systems to accredit pathology services, particularly in low-resource settings where disparities in training and infrastructure limit access to reliable diagnostics. WHO guidelines outline essential requirements for laboratory organization, staffing, equipment, and , aiming to harmonize practices and improve equity in pathology services worldwide.

Intersections with Other Disciplines

Overlap with Diagnostic Medicine

Pathology plays a pivotal role in multidisciplinary teams, particularly through tumor boards, where pathologists collaborate with radiologists, , and surgeons to integrate diagnostic findings for optimal patient management. These conferences combine pathology reports detailing tissue histology and molecular characteristics with radiological imaging to guide treatment decisions, such as in cases of suspected malignancies. For instance, MRI-guided biopsies exemplify this synergy, where radiological imaging localizes suspicious lesions, enabling precise tissue sampling for pathological confirmation of diagnoses like . Such integrated approaches in tumor boards have been shown to streamline workflows and enhance decision-making in complex cases. In precision oncology, pathology's overlap with diagnostic medicine manifests through integrated diagnostics, which fuse pathological analyses with and laboratory data to tailor therapies based on tumor profiles. Radiologists provide pre-biopsy localization using modalities like MRI or to identify targets, while pathologists deliver confirmatory , , and genomic testing to characterize the lesion's biology. This complementary dynamic ensures accurate and , as seen in and workflows where radiological findings direct biopsy sites for pathological evaluation. Additionally, point-of-care testing in clinical settings overlaps with pathology by enabling rapid hematological or biochemical assessments at the bedside, bridging immediate clinical needs with laboratory validation. Challenges in this overlap include communication gaps between disciplines, which digital reporting standards address by standardizing terminology and reducing errors in data transmission. For example, adoption of coding in pathology reports promotes consistent documentation, minimizing typographical errors, omissions, and misinterpretations that could lead to diagnostic delays. Structured electronic reporting has been associated with improved completeness and reproducibility, thereby enhancing interdisciplinary coordination in tumor boards and precision medicine initiatives. Clinical pathology laboratories serve as central hubs for these shared testing protocols, facilitating seamless integration across diagnostic modalities.

Pathology Informatics

Pathology informatics encompasses the application of to enhance pathology workflows, enabling efficient , analysis, and collaboration in diagnostic processes. It integrates computational tools to handle vast datasets from operations, improving accuracy and accessibility while supporting evidence-based decision-making in clinical settings. Laboratory information systems (LIS) form a foundational component of , facilitating the tracking of test results, specimen management, and workflow automation across anatomic and laboratories. These systems streamline data entry, reporting, and by centralizing patient testing information and enabling real-time updates to reduce manual errors. , a key advancement, involves whole-slide imaging (WSI) where glass slides are scanned into high-resolution digital formats for analysis. Recent models, such as the transformer-based for automated segmentation of portal tracts in liver biopsies, achieve high accuracy in hotspot detection, supporting precise histopathological evaluations with reported scores up to 0.92 and agreement of 0.90 in validation studies. Telepathology applications leverage for remote consultations, allowing pathologists to review cases instantaneously and reduce diagnostic turnaround times by up to 50% in resource-limited settings through hybrid static-dynamic systems. Data analytics powered by further enhances by monitoring error rates; for instance, ML models have demonstrated false negative rates as low as 0.411% in sample validation, minimizing invalid results and improving efficiency. These tools enable of equipment and outlier detection in datasets, fostering standardized practices. Looking ahead, technology is emerging to secure pathology among remote parties, ensuring tamper-proof transmission of sensitive histopathological images and reports while maintaining . Integration with electronic health records (EHRs) is advancing through HL7 FHIR standards, which provide structured profiles for pathology reports to enable seamless and reduce data silos in healthcare systems. Recent FDA approvals of algorithms in 2025 underscore practical implementations, with over 40 new collaborations accelerating adoption as of mid-2025.

Extensions to Non-Human Contexts

Veterinary Pathology

Veterinary pathology encompasses the scientific study and diagnosis of diseases in animals, spanning animals such as and cats, livestock like and , and including and marine mammals. This discipline plays a critical role in understanding disease mechanisms, supporting animal health, and assessing risks through comparative analysis across . Diagnostic techniques in veterinary pathology include necropsies for gross examination of organs, for microscopic tissue analysis, and advanced methods like to characterize cellular abnormalities, such as in canine lymphoma where it identifies B- or T-cell origins to guide and . Unique challenges in veterinary pathology arise from zoonotic diseases that bridge animal and human health, exemplified by , where reveals characteristic —eosinophilic intracytoplasmic inclusions in neurons indicative of infection. Comparative pathology further highlights differences in disease presentation across species, as seen in strains, where highly pathogenic H5N1 causes severe systemic lesions like in multiple organs in chickens, contrasting with milder outcomes in other birds and informing risks. These aspects underscore the field's emphasis on interspecies variations and preventive strategies. Professionally, veterinary pathologists often pursue board certification through the American College of Veterinary Pathologists (ACVP), which requires completion of accredited residency training followed by rigorous Phase I and II examinations in anatomic or . In food safety contexts, veterinary pathology contributes to detecting transmissible spongiform encephalopathies like (BSE), where postmortem microscopic examination of brain tissue identifies accumulation to prevent entry into the food chain. Many core techniques, such as , are adapted from to suit veterinary applications.

Plant Pathology

Plant pathology, also known as phytopathology, is the scientific study of diseases in caused by pathogens, environmental factors, and physiological disorders, with a focus on their , , and to protect agricultural and natural ecosystems. It addresses the interactions between and disease-causing agents, emphasizing prevention and control strategies that minimize economic losses in crop production. Unlike animal pathology, plant diseases often spread rapidly through spores or contaminated tools, necessitating integrated approaches like cultural practices and chemical treatments. Major plant pathogens include fungi, bacteria, and viruses, each with distinct mechanisms of infection and reproduction. Fungi, the most prevalent group, cause diseases such as rusts, where pathogens like Puccinia graminis produce urediniospores that facilitate wind-dispersed infection cycles, leading to widespread damage in cereal crops. Bacterial pathogens, such as those causing Xanthomonas wilt in bananas ( pv. musacearum), enter through wounds or natural openings, blocking vascular tissues and causing wilting. Viruses, exemplified by (TMV), form crystalline inclusions in infected plant cells, disrupting cellular functions and reducing , with transmission often occurring via mechanical means like tools. Diagnosis in plant pathology relies on a combination of traditional and modern techniques to identify pathogens accurately. is fundamental for observing fungal hyphae, which appear as thread-like structures infiltrating tissues, confirming infections like those from species. have been adapted for , requiring isolation of the from diseased tissue, of healthy , and re-isolation to establish , though challenges arise with parasites. Molecular tools, such as quantitative (qPCR), enable precise quantification of DNA in samples, detecting low-level infections early and aiding in resistance screening programs. The economic impacts of plant diseases are profound, costing the global economy approximately $220 billion annually through reduced yields and quality (FAO, 2019), with fungal pathogens being a major contributor. Management strategies increasingly incorporate genetic breeding, such as CRISPR-Cas9 editing of varieties to confer tolerance against head blight (Fusarium graminearum), which produces mycotoxins and devastates grain production. These approaches, combined with sustainable practices, help mitigate outbreaks and support . General mechanisms in plants share analogies with animal models, such as activation, but are tailored to sessile lifestyles and lack adaptive immunity.

References

  1. [1]
    What is Pathology? - McGill University
    Pathology is a branch of medical science that involves the study and diagnosis of disease through the examination of surgically removed organs, ...Missing: authoritative | Show results with:authoritative
  2. [2]
    What is pathology? - Royal College of Pathologists
    Pathology is the study of disease. It is the bridge between science and medicine. It underpins every aspect of patient care.Missing: authoritative | Show results with:authoritative
  3. [3]
    Pathology: The Clinical Description of Human Disease - PMC
    Pathology is that field of science and medicine concerned with the study of diseases, specifically their initial causes (etiologies), their step-wise ...Missing: authoritative | Show results with:authoritative
  4. [4]
    What Is Pathology? | College of American Pathologists
    Pathology is the medical discipline that provides diagnostic information to patients and clinicians. It impacts nearly all aspects of patient care.Missing: authoritative | Show results with:authoritative
  5. [5]
    [PDF] Introduction to Pathology and Diagnostic Medicine
    Etiology. Pathogenesis. Biochemical. Changes. Morphological. Changes. Functional Changes. Natural History. Page 10. Historical Paradigm of Diagnostic Pathology.
  6. [6]
    Physiology, Homeostasis - StatPearls - NCBI Bookshelf
    May 1, 2023 · Diseases such as diabetes, hypertension, and atherosclerosis, involve both the disturbance of homeostasis, as well as the presence of ...
  7. [7]
    [PDF] PubH 6355-001 Pathophysiology of Human Disease Fall 2018
    factors, structural alterations (morphologic changes) resulting from the disease, and the functional consequences of these structural changes (clinical ...
  8. [8]
    What is Pathology?
    Pathologists are clinical care providers who contribute their scientific and practice skills to the diagnosis and management of patients in a variety of ways.Missing: authoritative | Show results with:authoritative
  9. [9]
    Homeostasis: The Underappreciated and Far Too Often Ignored ...
    The disruption of homeostatic mechanisms is what leads to disease, and effective therapy must be directed toward re-establishing these homeostatic conditions, ...
  10. [10]
    Pathology: The Clinical Description of Human Disease - PMC
    Pathology refers to the specialty of medical science concerned with the cause, development, structural/functional changes, and natural history associated with ...Missing: consequences | Show results with:consequences
  11. [11]
    The role of cytology in molecular testing and personalized medicine ...
    Dec 4, 2018 · Cytology is a viable and underused medium for obtaining molecular testing in lung cancer. There are various obstacles to the widespread ...Missing: scope epidemiology
  12. [12]
    4 statistics that showcase the broad impact of laboratory medicine
    Apr 21, 2025 · 1. Test results inform 70% of medical decisions. Test results and interpretations are at the heart of nearly every patient's care journey.
  13. [13]
    Errors and Error Rates in Surgical Pathology: An Association of ...
    May 1, 2006 · The median 1.5% discrepancy rate in the present study is therefore most encouraging. The question of total errors in participants' laboratories ...Abstract · METHODS · RESULTS AND COMMENT
  14. [14]
    Errors encountered in the diagnostic pathway: A prospective single ...
    Jun 14, 2023 · A similar study in anatomic pathology identified 132 errors from 19 774 specimens, resulting in a comparable error rate of 0.7%. However, the ...
  15. [15]
    An overview of COVID-19 for diagnostic pathologists - PubMed Central
    This article aims to review understanding of clinicopathological correlation in COVID-19, as well as clarifying the role of current diagnostic techniques.
  16. [16]
    Insights into Pathology and Pathogenesis of Coronavirus Disease ...
    Jul 15, 2021 · This article outlines the pathological characteristics of COVID-19 on the respiratory and other organs, which have mainly been demonstrated by autopsies.
  17. [17]
    The Edwin Smith papyrus: a clinical reappraisal of the oldest known ...
    The Edwin Smith papyrus is a unique treatise containing the oldest known descriptions of signs and symptoms of injuries of the spinal column and spinal cord.
  18. [18]
    [PDF] surgical papyrus - Institute for the Study of Ancient Cultures
    ... Imhotep, the great architect-physician who flourished in the. Thirtieth ... pathology, physiology, anatomy, surgery, etc. It is of course needless to ...
  19. [19]
    [PDF] On the Sacred Disease: The Historical Significance of Hippocratic ...
    Apr 26, 2012 · “[The] disease called the Sacred arises from causes as the others, namely those things which enter and quit the body, such as cold, the sun, ...
  20. [20]
    A brief history of pathology: Preface to a forthcoming series ... - NIH
    One of the greatest writers of the Arab period was Avicenna (980–1037), an illustrious physician whose major work the “Canon Medicinae” was based on the ...
  21. [21]
    A glimpse into the early origins of medieval anatomy through the ...
    Medieval autopsy practice is very poorly known in Western Europe, due to a lack of both descriptive medico-surgical texts and conserved dissected human remains.
  22. [22]
    The Science of Anatomy: A historical timeline - PMC - NIH
    ... Avicenna or Abu ibn Sina (980–1037 CE) who famously wrote the Canon of Medicine and Ibn Al-Nafis (1210–1288 CE) who explained pulmonary circulation, paving ...
  23. [23]
    Rudolf Virchow (1821-1902) and Die Cellularpathologie (1858)
    Although he intended to found a science of pathological physiology based on omnis cellula e cellula, advances in microscopy facilitated and promoted, even ...
  24. [24]
    The cell theory and cellular pathology: Discovery, refinements and ...
    In 1858, Rudolf Virchow published his Cellular Pathology which included the statement that all cells come from parent cells; in 1859, Charles Darwin ...
  25. [25]
    A Theory of Germs - Science, Medicine, and Animals - NCBI - NIH
    Robert Koch made the discoveries that led Louis Pasteur to describe how small organisms called germs could invade the body and cause disease.
  26. [26]
    Robert Koch (1843–1910) | Embryo Project Encyclopedia
    Jan 15, 2025 · Koch's postulates contain four main ideas, which serve as guidelines for establishing that specific bacteria cause specific diseases. His first ...
  27. [27]
    History | Johns Hopkins Pathology
    The Department of Pathology was one of the original departments created, playing a significant role since the hospital opened in 1889. Faculty and residents ...
  28. [28]
    From silks to science: The history of hematoxylin and eosin staining
    Jan 11, 2023 · The development of hematoxylin. The origins of hematoxylin can be traced back to the logwood tree, also known as Haematoxylum campechianum.
  29. [29]
    Roche's momentum in digital pathology continues with FDA ...
    Roche announced today that its whole slide imaging system, Roche Digital Pathology Dx, has received an additional 510(k) clearance from the ...
  30. [30]
    Whole Slide Imaging (WSI) in Pathology: Emerging Trends and ...
    Whole Slide Imaging (WSI) digitizes entire glass slides into high-resolution images, enabling remote collaboration and AI integration in pathology.
  31. [31]
    Roche granted FDA Breakthrough Device Designation for first AI ...
    Roche granted FDA Breakthrough Device Designation for first AI-driven companion diagnostic for non-small cell lung cancer. April 28, 2025. The ...Missing: assisted | Show results with:assisted
  32. [32]
    Ventana TROP2 (EPR20043) RxDx Device Receives FDA ... - OncLive
    May 5, 2025 · The AI-driven companion diagnostic device Ventana TROP2 (EPR20043) RxDx has received FDA breakthrough device designation in NSCLC.
  33. [33]
    Unveiling the future: the impact of artificial intelligence in diagnostic ...
    Aug 10, 2025 · In the field of diagnostic pathology, AI not only speeds up the diagnostic process but also minimizes human error, ultimately leading to ...
  34. [34]
    A foundation model for clinical-grade computational pathology and ...
    Jul 22, 2024 · The pan-cancer detector, trained on Virchow foundation model embeddings, achieves similar performance to clinical-grade products in general ...
  35. [35]
    The Largest Foundation Model for Computational Pathology To Date
    Aug 13, 2024 · A pathology foundation model Virchow, named in honour of Dr. Rudolf Virchow, is shown to enable pan-cancer detection and improve performance of specialised ...
  36. [36]
    How AI in Pathology is Revolutionizing Disease Diagnosis
    Sep 26, 2025 · Reduce turnaround time for pathology reports. By augmenting pathologists rather than replacing them, AI ensures higher efficiency, accuracy ...
  37. [37]
    DPYD Genotyping Recommendations - PubMed - NIH
    DPYD Genotyping Recommendations: A Joint Consensus Recommendation of the Association for Molecular Pathology, American College of Medical Genetics and ...Missing: multi- omics NGS antimicrobial resistance
  38. [38]
    Keeping up with the pathogens: improved antimicrobial resistance ...
    Jun 7, 2024 · Antimicrobial resistance (AMR) is an intensifying threat that requires urgent mitigation to avoid a post-antibiotic era.Comparative Genomic Analysis · Amr Prediction Analysis · Precision And Recall Among...
  39. [39]
    Artificial Intelligence and Multi-Omics in Pharmacogenomics - NIH
    In this review, we highlighted key technological advances, discussed current limitations, and outlined future directions for translating multi-omics plus AI ...Missing: antimicrobial | Show results with:antimicrobial
  40. [40]
    Mechanisms and Morphology of Cellular Injury, Adaptation, and Death
    The causes of cellular or tissue atrophy include nutrient deprivation or loss of hormonal stimulation, decreased workload (disuse atrophy), denervation ...
  41. [41]
    Pathology, Inflammation - StatPearls - NCBI Bookshelf - NIH
    Issues of Concern. Acute or Chronic Inflammation. Acute inflammation has a rapid onset of minutes or hours, typically resolves within a few days, has classic ...
  42. [42]
    Histology, Cell Death - StatPearls - NCBI Bookshelf
    Jan 30, 2023 · In necrotic cell death, the release of caspases is coincidental to cellular injury. In apoptosis, caspase activation is purposeful and ...Missing: Robbins | Show results with:Robbins
  43. [43]
    SIRS, Sepsis and Multiorgan Failure - NCBI - NIH
    Sepsis, circulatory failure and organ dysfunction. The widespread disruptions in severe sepsis can result in profound cardio-circulatory dysfunction. This ...Epidemiology · Historical Perspective and... · Pathophysiology of Sepsis
  44. [44]
    Cytokine Storm—Definition, Causes, and Implications - PMC
    The excessive release of proinflammatory factors ultimately leads to systemic damage and even multi-organ failure. 3. Inflammation Due to Sepsis. Adaptive and ...
  45. [45]
    Anatomic Pathology - Testing.com
    Jan 27, 2021 · Anatomic (or anatomical) pathology is the branch of medicine that studies the effect of disease on the structure of body organs, both as a whole (grossly) and ...
  46. [46]
    [PDF] Overview of Anatomic and Clinical Pathology
    Aug 16, 2019 · Anatomic pathology primarily consists of tissue evaluation—from individual cells from a Pap smear, a fine needle aspiration of a mass, or ...Missing: histopathology H&E
  47. [47]
    H&E Staining Overview: A Guide to Best Practices
    Hematoxylin and Eosin stains are used in many areas of the histology laboratory, including frozen sections, fine needle aspirates, and paraffin fixed embedded ...Missing: anatomical | Show results with:anatomical
  48. [48]
    Frozen section overview - Pathology Outlines
    Jan 3, 2019 · A frozen section (cryosection) is a pathological laboratory technique used for rapid microscopic analysis / diagnosis of a specimen / disease ...Missing: anatomical | Show results with:anatomical
  49. [49]
    Surgical Pathology Reports - NCI - National Cancer Institute
    Aug 8, 2022 · To make frozen sections, the tissue sample is rapidly frozen, cut into sections using an instrument called a cryostat, stained, and examined ...
  50. [50]
    The history of the Papanicolaou smear and the odyssey of George ...
    The Papanicolaou smear, a routine screening test for cancer of the uterine cervix, was reported in 1928, and its efficacy was proved by 1941.
  51. [51]
    Frozen and on Time: Rapid Margin Assessment Helps Prevent ...
    Mar 27, 2018 · “Our frozen section pathology is used routinely for intraoperative margin analysis in all breast cancer cases, not just those that might ...
  52. [52]
    Skin melanocytic tumor - Nevoid melanoma - Pathology Outlines
    Oct 6, 2025 · Superficial aspects of a lesion resemble thin melanoma · Deeper aspects are represented by small hyperchromatic, blue tumor cells · Nest formation ...
  53. [53]
    TNM Classification - StatPearls - NCBI Bookshelf - NIH
    The TNM system helps to establish the anatomic extent of the disease, and the combination of the 3 factors can define the overall tumor stage. This method ...
  54. [54]
    Benign or Malignant? Ex Vivo Confocal Laser Scanning Microscopy ...
    Benign nevi displayed well-organized nests of uniform melanocytes, while malignant melanoma exhibited architectural disarray, cellular pleomorphism, and ...
  55. [55]
    TUMOR CELL MORPHOLOGY - Comparative Oncology - NCBI - NIH
    The basal membrane is present in benign tumors, while the invasive growth of malignant cells is characterized by fragmentation, reduplication or disappearance ...
  56. [56]
    High-Quality Diagnosis: An Essential Pathology Package - NCBI - NIH
    Clinical pathology, also called laboratory medicine, which is largely concerned with analysis of blood and other fluids and involves, for instance, clinical ...
  57. [57]
    Clinical Chemistry | College of American Pathologists
    Clinical pathology/clinical chemistry is the use of biochemical and molecular methods in the diagnosis and managing of human disease. Learn more about…
  58. [58]
    Liver Function Tests - StatPearls - NCBI Bookshelf - NIH
    The liver function tests typically include alanine transaminase (ALT) and aspartate transaminase (AST), alkaline phosphatase (ALP), gamma-glutamyl transferase ...Introduction · Etiology and Epidemiology · Pathophysiology · Clinical Significance
  59. [59]
    Flow Cytometry Blood Cell Identification - StatPearls - NCBI Bookshelf
    Sep 11, 2024 · To identify different leukocytes in peripheral blood, a backbone marker, such as leukocyte common antigen or CD45, is used to stain different ...
  60. [60]
    Bacteria Culture Test: MedlinePlus Medical Test
    Nov 19, 2024 · A bacteria culture test can determine if you have a bacterial infection and, if so, which type of bacteria is causing it.
  61. [61]
    Prothrombin Time Test and INR (PT/INR): MedlinePlus Medical Test
    May 15, 2024 · A PT/INR test helps find out if your blood is clotting normally. It also checks to see if a medicine that prevents blood clots is working the way it should.
  62. [62]
    Troponins in myocardial infarction and injury - PMC - NIH
    The measurement of cardiac troponins is used primarily to assist in the diagnosis or exclusion of myocardial injury. Serial tests in acute coronary syndrome are ...
  63. [63]
    Blood typing: MedlinePlus Medical Encyclopedia
    Mar 31, 2024 · Blood typing is a method to tell what type of blood you have. Blood typing is done so you can safely donate your blood or receive a blood transfusion.
  64. [64]
    Next-generation sequencing in cancer diagnosis and treatment - NIH
    Apr 20, 2025 · NGS enables detailed genomic profiling of tumors, identifying genetic alterations that drive cancer progression and facilitating personalized ...
  65. [65]
    HER2 Gene Amplification Testing by Fluorescent In Situ ...
    Aug 29, 2016 · Subsequently, gene amplification was assessed by FISH using either CEP17 or another gene on the same chromosome as an internal control, again ...
  66. [66]
    Tumor location matters, next generation sequencing mutation ...
    Feb 26, 2024 · Tumor location matters, next generation sequencing mutation profiling of left-sided, rectal, and right-sided colorectal tumors in 552 patients.
  67. [67]
    EGFR T790M ctDNA Testing Platforms and Their Role as ... - PubMed
    Sep 10, 2017 · Though there are several platforms for EGFR mutation detection, highly sensitive platforms for clinical applicability as companion diagnostics ...
  68. [68]
    Impact of pharmacogenomic DPYD variant guided dosing on toxicity ...
    Apr 26, 2023 · Our study demonstrates successful routine DPYD mutation testing prior to the initiation of fluoropyrimidine chemotherapy with high uptake.
  69. [69]
    Liquid biopsy in cancer: current status, challenges and future ...
    Dec 2, 2024 · Liquid biopsy has many advantages in the diagnosis and treatment of various types of cancer, including non-invasive, quickly and so on.
  70. [70]
    Forensic Autopsy - StatPearls - NCBI Bookshelf - NIH
    Sep 4, 2023 · A forensic autopsy is an examination conducted postmortem to address medicolegal objectives. A forensic autopsy is also called a medicolegal autopsy.Introduction · Issues of Concern · Other Issues
  71. [71]
    Clinical Autopsy vs Medicolegal Autopsy - PMC - PubMed Central
    Medico-legal (ML) autopsy is performed with the aim of providing answers to questions about the identity, cause of death, time of death, circumstances of death, ...
  72. [72]
    [PDF] A Guide for Manner of Death Classification
    Feb 12, 2002 · ... death should be classified as natural or non-natural. (homicide, suicide, accident). When an injury or poisoning is involved in the cause of.
  73. [73]
    [PDF] Medical Examiners' and Coroners' Handbook on Death Registration ...
    When the death was the result of an external cause, the medical examiner or coroner should specify whether it was an accident, suicide, or homicide and describe ...<|separator|>
  74. [74]
    Gunshot Wounds Forensic Pathology - StatPearls - NCBI Bookshelf
    Apr 17, 2023 · The forensic pathologist is often required to identify gunshot wounds, the direction and the distance of fire, the manner of injury - suicidal, ...Continuing Education Activity · Introduction · Causes · Biochemical and Genetic...Missing: trajectories | Show results with:trajectories
  75. [75]
    Practical Pathology of Gunshot Wounds - Allen Press
    Sep 1, 2006 · This article reviews numerous standard forensic pathology textbooks and the pertinent literature to formulate practical guidelines to assist the pathologist.
  76. [76]
    Asphyxia - Pathology Outlines
    Jul 18, 2022 · Ligature marks: marks made by any cord-like objects used for the purposes of strangulation. Different patterns and features (see Strangulation).
  77. [77]
    Postmortem Changes - StatPearls - NCBI Bookshelf
    Rigor mortis is the post mortem stiffening/ rigidity of the body. It results from a decrease in levels of adenosinetriphosphate (ATP) beyond critical levels.
  78. [78]
    Methods of Estimation of Time Since Death - StatPearls - NCBI - NIH
    The early post-mortem phase is most frequently estimated using the classical triad of post-mortem changes – rigor mortis, livor mortis, and algor mortis.Continuing Education Activity · Function · Issues of Concern · Clinical Significance
  79. [79]
    Neuropathology of Alzheimer's Disease - PMC - PubMed Central - NIH
    The neurofibrillary tangle consists of abnormal accumulations of abnormally phosphorylated tau within the perikaryal cytoplasm of certain neurons. The senile ...
  80. [80]
    The neuropathological diagnosis of Alzheimer's disease
    Aug 2, 2019 · The current criteria use an ABC scoring system that requires the presence of amyloid plaques and tau neurofibrillary tangles to describe the ...
  81. [81]
    IDH1 and IDH2 Mutations in Gliomas
    Feb 19, 2009 · To assess the enzymatic activity of wild-type and mutant IDH1 and IDH2 proteins, a human oligodendroglioma line without IDH1 or IDH2 mutations ...
  82. [82]
    Neuropathology of prion diseases - Oxford Academic
    The classical triad of spongiform change, neuronal loss, and gliosis (astro- and microglia) is the neuropathological hallmark of prion diseases. Since neuronal ...Abstract · Macroscopy of human prion... · Histopathology of human prion...
  83. [83]
    Immunohistochemical expression of glial fibrillary acidic protein and ...
    IHC is a valuable technique and the best effective combination in differentiating high-grade gliomas from metastatic tumors of CNS are GFAP and CAM5.2.
  84. [84]
    An Algorithmic Approach to the Brain Biopsy—Part I - Allen Press
    Nov 1, 2006 · E and F, GFAP immunostaining of high-grade astrocytomas illustrates that tumor cells have more blunted and irregular cell processes, or even ...
  85. [85]
    Cerebrospinal fluid neopterin as a biomarker of neuroinflammatory ...
    Oct 26, 2020 · The elevation of neopterin in cerebrospinal fluid (CSF) has been reported in several neuroinflammatory disorders.Missing: neuropathology | Show results with:neuropathology
  86. [86]
    Mechanisms of Blood-Brain Barrier Disruption in Herpes Simplex ...
    Nov 19, 2018 · Following an HSV-1 infection, changes in BBB integrity and permeability can result in increased movement of viruses, immune cells, and/or ...
  87. [87]
    Autopsy neuropathological findings in 'burnt out' herpes simplex ...
    The brains showed marked atrophy and yellow-brown discolouration predominantly involving the anterior part of both temporal lobes. Histology revealed ...
  88. [88]
    Herpes simplex encephalitis - Pathology Outlines
    Mar 8, 2024 · Bilateral, usually asymmetrical, hemorrhagic necrosis involving the temporal lobes, especially anteriorly and inferiorly, and to a greater or ...
  89. [89]
    An Overview of United States Physician Training, Certification, and ...
    Apr 12, 2013 · Clinical Pathology (CP) – also known as Laboratory Medicine - is a rewarding and yet under-recognized career option for United States (U.S.) ...
  90. [90]
    [PDF] ACGME Program Requirements for Graduate Medical Education in ...
    Didactic activities may include, but are not limited to, lectures, conferences,. Anatomic Pathology and Clinical Pathology. ©2025 Accreditation Council for ...
  91. [91]
    Requirements for Certification - American Board of Pathology
    Residents must complete at least 2 years of training in AP/CP, AP, or CP before beginning subspecialty fellowship training, except for Dermatopathology, for ...
  92. [92]
    Overview - Pathology - ACGME
    Crosswalk: Faculty Survey-Common Program Requirements (2025) · Faculty Survey Program FAQs · Crosswalk: Resident/Fellow Survey-Common Program Requirements (2025).Contact And Support · Review Committee Dates · Upcoming Events
  93. [93]
    The UEMS section/board of pathology, chapter 6: requirement for ...
    Training in so-called 'areas of interests' covers the remaining 12-24 months. Certificates of 'advanced level of competence' remain within the authority of ...
  94. [94]
    About Certification - American Board of Pathology
    ABPath certification requires a graduate program, demonstrating competencies, and a voluntary evaluation to ensure knowledge and skills.
  95. [95]
    Fellowship Board Pass Rates Rising: Analysis of Pathology ...
    Nov 7, 2022 · The overall mean pass rate for ABPath subspecialty examinations during the previous 15 years was 89% (range, 78.9%–100%), with the overall pass ...METHODS · RESULTS · DISCUSSIONMissing: ABP | Show results with:ABP
  96. [96]
    Continuing Certification - American Board of Pathology
    The CC program helps maintain board certification through reporting, ABPath CertLink questions, and annual fees. Participation is tracked through PATHway and ...
  97. [97]
    Lifelong Learning - American Board of Pathology
    If not meeting the Lifelong Learning requirement any other way, each diplomate must obtain a minimum of 70 CME credits in each two-year reporting period. Eighty ...
  98. [98]
    Professionalism and Professional Standing
    Diplomates must maintain a full license, provide peer attestations, report substance abuse/impairments, and provide medical staff privilege information.
  99. [99]
    Examinations - Royal College of Pathologists
    The College develops and delivers the FRCPath, Diploma and Certificate examinations which are offered across 23 pathology specialties.Examination News and Dates · Examination Results · Specialty · Examiners Area
  100. [100]
    Regulations, Guidelines and Policies - Royal College of Pathologists
    The FRCPath examination is an assessment of a candidate's training programme, indicating fitness to practise, whilst at the same time signalling the entry into ...
  101. [101]
    Laboratory quality management - World Health Organization (WHO)
    WHO helps Member States to strengthen laboratory quality management through the development of training materials, guidance documents and practical tools.
  102. [102]
    MRI-guided Breast Biopsy Case-based Review - RSNA Journals
    Feb 4, 2022 · MRI-guided breast biopsy is often necessary to distinguish between benign and malignant lesions depicted at MRI, and meticulous preparation ...
  103. [103]
    Optimizing the structure of interdisciplinary tumor boards for effective ...
    Apr 25, 2023 · IntroductionMulti-professional interdisciplinary tumor boards (ITB) are essential institutions to discuss all newly diagnosed, ...
  104. [104]
    Incorporating Integrated Diagnostics into Precision Oncology Care
    Jul 29, 2024 · The convergence of imaging, pathology, and laboratory testing data, augmented with information technology, is referred to as integrated ...
  105. [105]
    Point-of-Care Testing - StatPearls - NCBI Bookshelf
    May 29, 2023 · Point-of-Care Testing (POCT) is clinical laboratory testing conducted close to the site of patient care where care or treatment is provided.Missing: overlap | Show results with:overlap
  106. [106]
    [PDF] Electronic Reporting in Pathology: Requirements and Limitations
    Structured reporting enhances report quality. Standardization of cancer reporting may reduce typographic errors as well as errors of omission. In one of the ...
  107. [107]
    Integrating pathology and radiology disciplines: an emerging ...
    Sep 5, 2012 · The integrated report may lessen preparation time for multidisciplinary tumor board conferences and would be a valuable educational resource for ...
  108. [108]
    LIS fundamentals - Pathology Outlines
    Jun 13, 2023 · A laboratory information system (LIS) that harbors a result entry system capable of receiving internal and external laboratory results in various formats.
  109. [109]
    Laboratory Information Systems - PubMed
    Anatomic pathology LIS (APLIS) functions play key roles throughout the pathology workflow, and laboratories rely on LIS management reports to monitor operations ...
  110. [110]
    Laboratory Information System - an overview | ScienceDirect Topics
    The LIS is at the core of most pathology laboratory operations. Its functions include workflow management, specimen tracking, data entry and reporting, ...<|separator|>
  111. [111]
    What is Laboratory Information System (LIS) Software?
    An LIS is a software system that records, manages, updates, and stores patient testing data for clinical and anatomic pathology laboratories, including ...
  112. [112]
    An update on applications of digital pathology: primary diagnosis
    Feb 12, 2025 · Way forwarding to 2024, the FDA announced its Final Rule on laboratory-developed tests (LDTs) in April. LDTs are now considered regulated ...
  113. [113]
    Automating liver biopsy segmentation with a robust, open-source ...
    Jul 18, 2025 · This study introduces HOTSPoT, an open-source, validated transformer-based model for automated segmentation of portal tracts in H&E-stained ...
  114. [114]
    Telepathology in Low Resource African Settings - Frontiers
    This use of telepathology has significantly reduced the turnaround time (TAT) in many underdeveloped countries. This is especially true in countries with a ...<|separator|>
  115. [115]
    Machine Learning for Patient-Based Real-Time Quality Control ...
    Aug 20, 2024 · The low false negative rate of 0.411% indicated that this greater efficiency only came with a small risk of missing invalid samples. 5.Missing: analytics | Show results with:analytics
  116. [116]
    https://diagnosticpathology.biomedcentral.com/articles/10.1186/s13000-025-01610-9
  117. [117]
    Privacy-preserving pathological data sharing among remote parties
    This paper presents a novel solution that leverages blockchain technology to ensure reliability in pathological data sharing.
  118. [118]
    Design of HL7 FHIR Profiles for Pathology Reports Integrated with ...
    Jan 25, 2024 · This paper describes the development of Health Level Seven Fast Healthcare Interoperability Resource (FHIR) profiles for pathology reports integrated with ...
  119. [119]
    Meet our 2025 PI Summit Sponsors
    With expertise in whole-slide imaging, AI-assisted diagnosis, and cloud-based pathology platforms, aetherAI empowers pathologists with cutting-edge technology ...Missing: approvals | Show results with:approvals
  120. [120]
    What is Veterinary Pathology - ACVP.org
    Veterinary Pathology is the study of animal disease, often with human implications, and crucial in determining cause of animal disease and its risk to human ...<|separator|>
  121. [121]
    Veterinary Pathology – A Path Forward with New Directions and ...
    The scope of this section of Frontiers in Veterinary Science is pathology – the study of disease – at a genetic (or epigenetic), molecular, cellular, tissue ...
  122. [122]
    Flow Cytometry: Introduction to Basics - Today's Veterinary Practice
    Oct 17, 2023 · Flow cytometry is commonly used to determine cell origin (i.e., B versus T cells) in canine lymphoma, identify markers associated with lymphoma ...Flow Cytometry: Introduction... · Immunophenotyping Of... · Sample Requirements And...Missing: necropsies | Show results with:necropsies
  123. [123]
    Pathobiological investigation of naturally infected canine rabies ...
    Apr 12, 2017 · Negri bodies were not found in the negative IHC cases, however in one negative case there was histopathological evidence of granulomatous ...
  124. [124]
    Comparative pathology of chickens experimentally inoculated with ...
    Chickens inoculated with highly pathogenic (HP) virus had histologic lesions of necrosis and inflammation in cloacal bursa, thymus, spleen, heart, pancreas, ...
  125. [125]
    ACVP.org – Advancing Veterinary Pathology for more than 75 years
    Certifying Examination. Learn about ACVP's two-part examination process, leading to board certification in veterinary anatomic or clinical pathology. Learn More ...Training Program Accreditation · About ACVP · Networking · Phase II Examinations
  126. [126]
    [PDF] Food Safety Issues - Purdue Extension
    Currently, there is no test to detect the disease in the live animal. Veterinary pathologists confirm BSE by postmortem microscopic examination of brain tissue.