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Neoplasm
Other namesTumor, tumour, carcinocytes
Colectomy specimen containing a malignant neoplasm, namely an invasive example of colorectal cancer (the crater-like, reddish, irregularly shaped tumor at top-center)
SpecialtyOncology
SymptomsLump
ComplicationsCancer
CausesRadiation, environmental factor, certain infections

A neoplasm (/ˈnplæzəm, ˈnə-/)[1][2] is a type of abnormal and excessive growth of tissue. The process that occurs to form or produce a neoplasm is called neoplasia. The growth of a neoplasm is uncoordinated with that of the normal surrounding tissue, and persists in growing abnormally, even if the original trigger is removed.[3][4][5] This abnormal growth usually forms a mass, which may be called a tumour or tumor.[6]

ICD-10 classifies neoplasms into four main groups: benign neoplasms, in situ neoplasms, malignant neoplasms, and neoplasms of uncertain or unknown behavior.[7] Malignant neoplasms are also simply known as cancers and are the focus of oncology.

Prior to the abnormal growth of tissue, such as neoplasia, cells often undergo an abnormal pattern of growth, such as metaplasia or dysplasia.[8] However, metaplasia or dysplasia does not always progress to neoplasia and can occur in other conditions as well.[3] The word neoplasm is from Ancient Greek νέος- neo 'new' and πλάσμα plasma 'formation, creation'.

Types

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-plasia and -trophy
  • Abiotrophy (loss in vitality of organ or tissue)
  • Atrophy (reduced functionality of an organ, with decrease in the number or volume of cells)
  • Hypertrophy (increase in the volume of cells or tissues)
  • Hypotrophy (decrease in the volume of cells or tissues)
  • Dystrophy (any degenerative disorder resulting from improper or faulty nutrition)

A neoplasm can be benign, potentially malignant, or malignant (cancer).[9]

  • Benign tumors include uterine fibroids, osteophytes, and melanocytic nevi (skin moles). They are circumscribed and localized and do not transform into cancer.[8]
  • Potentially-malignant neoplasms include carcinoma in situ. They are localised, and do not invade and destroy but in time, may transform into cancer.
  • Malignant neoplasms are commonly called cancer. They invade and destroy the surrounding tissue, may form metastases and, if untreated or unresponsive to treatment, will generally prove fatal.
  • Secondary neoplasm refers to any of a class of cancerous tumor that is either a metastatic offshoot of a primary tumor, or an apparently unrelated tumor that increases in frequency following certain cancer treatments such as chemotherapy or radiotherapy.
  • Rarely there can be a metastatic neoplasm with no known site of the primary cancer and this is classed as a cancer of unknown primary origin.

Clonality

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Neoplastic tumors are often heterogeneous and contain more than one type of cell, but their initiation and continued growth are usually dependent on a single population of neoplastic cells. These cells are presumed to be monoclonal – that is, they are derived from the same cell,[10] and all carry the same genetic or epigenetic anomaly – evident of clonality. For lymphoid neoplasms, e.g. lymphoma and leukemia, clonality is proven by the amplification of a single rearrangement of their immunoglobulin gene (for B cell lesions) or T cell receptor gene (for T cell lesions). The demonstration of clonality is now considered to be necessary to identify a lymphoid cell proliferation as neoplastic.[11]

Neoplasm vs. tumor

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The word tumor or tumour comes from the Latin word for swelling, which is one of the cardinal signs of inflammation. The word originally referred to any form of swelling, neoplastic or not. In modern English, tumor (non-US spelling: tumour) is used as a synonym for a neoplasm (a solid or fluid-filled cystic lesion that may or may not be formed by an abnormal growth of neoplastic cells) that appears enlarged in size.[12][13] Some neoplasms do not form a tumor; these include leukemia and most forms of carcinoma in situ. Tumor is also not synonymous with cancer. While cancer is by definition malignant, a tumor can be benign, precancerous, or malignant.[citation needed]

The terms mass and nodule are often used synonymously with tumor. Generally speaking, however, the term tumor is used generically, without reference to the physical size of the lesion.[3] More specifically, the term mass is often used when the lesion has a maximal diameter of at least 20 millimeters (mm) in the greatest direction, while the term nodule is usually used when the size of the lesion is less than 20 mm in its greatest dimension (25.4 mm = 1 inch).[3]

Causes

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Neoplastic tumor of the cheek skin, here a benign neoplasm of the sweat glands called hidradenoma, which is not solid but is fluid-filled
Diagram illustrating benign neoplasms, namely fibroids of the uterus

Tumors in humans occur as a result of accumulated genetic and epigenetic alterations within single cells, which cause the cell to divide and expand uncontrollably.[14] A neoplasm can be caused by an abnormal proliferation of tissues, which can be caused by genetic mutations. Not all types of neoplasms cause a tumorous overgrowth of tissue (such as leukemia or carcinoma in situ); however, similarities between neoplasmic growths and regenerative processes, e.g., dedifferentiation and rapid cell proliferation, have been pointed out.[15]

Tumor growth has been studied using mathematics and continuum mechanics. Vascular tumors such as hemangiomas and lymphangiomas (formed from blood or lymph vessels) are thus looked at as being amalgams of a solid skeleton formed by sticky cells and an organic liquid filling the spaces in which cells can grow.[16] Under this type of model, mechanical stresses and strains can be dealt with and their influence on the growth of the tumor and the surrounding tissue and vasculature elucidated. Recent findings from experiments that use this model show that active growth of the tumor is restricted to the outer edges of the tumor and that stiffening of the underlying normal tissue inhibits tumor growth as well.[17]

Benign conditions that are not associated with an abnormal proliferation of tissue (such as sebaceous cysts) can also present as tumors, however, but have no malignant potential. Breast cysts (as occur commonly during pregnancy and at other times) are another example, as are other encapsulated glandular swellings (thyroid, adrenal gland, pancreas).[citation needed]

Encapsulated hematomas, encapsulated necrotic tissue (from an insect bite, foreign body, or other noxious mechanism), keloids (discrete overgrowths of scar tissue) and granulomas may also present as tumors.[citation needed]

Discrete localized enlargements of normal structures (ureters, blood vessels, intrahepatic or extrahepatic biliary ducts, pulmonary inclusions, or gastrointestinal duplications) due to outflow obstructions or narrowings, or abnormal connections, may also present as a tumor. Examples are arteriovenous fistulae or aneurysms (with or without thrombosis), biliary fistulae or aneurysms, sclerosing cholangitis, cysticercosis or hydatid cysts, intestinal duplications, and pulmonary inclusions as seen with cystic fibrosis. It can be dangerous to biopsy a number of types of tumor in which the leakage of their contents would potentially be catastrophic. When such types of tumors are encountered, diagnostic modalities such as ultrasound, CT scans, MRI, angiograms, and nuclear medicine scans are employed prior to (or during) biopsy or surgical exploration/excision in an attempt to avoid such severe complications.[citation needed]

Malignant neoplasms

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DNA damage

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The central role of DNA damage and epigenetic defects in DNA repair genes in malignant neoplasms

DNA damage is considered to be the primary underlying cause of malignant neoplasms known as cancers.[18] Its central role in progression to cancer is illustrated in the figure in this section, in the box near the top. (The central features of DNA damage, epigenetic alterations and deficient DNA repair in progression to cancer are shown in red.) DNA damage is very common. Naturally occurring DNA damages (mostly due to cellular metabolism and the properties of DNA in water at body temperatures) occur at a rate of more than 10,000 new damages, on average, per human cell, per day.[19] Additional DNA damages can arise from exposure to exogenous agents. Tobacco smoke causes increased exogenous DNA damage, and these DNA damages are the likely cause of lung cancer due to smoking.[20] UV light from solar radiation causes DNA damage that is important in melanoma.[21] Helicobacter pylori infection produces high levels of reactive oxygen species that damage DNA and contributes to gastric cancer.[22] Bile acids, at high levels in the colons of humans eating a high-fat diet, also cause DNA damage and contribute to colon cancer.[23] Katsurano et al. indicated that macrophages and neutrophils in an inflamed colonic epithelium are the source of reactive oxygen species causing the DNA damages that initiate colonic tumorigenesis (creation of tumors in the colon).[24][unreliable source?] Some sources of DNA damage are indicated in the boxes at the top of the figure in this section.[clarification needed]

Individuals with a germline mutation causing deficiency in any of 34 DNA repair genes (see article DNA repair-deficiency disorder) are at increased risk of cancer. Some germline mutations in DNA repair genes cause up to 100% lifetime chance of cancer (e.g., p53 mutations).[25] These germline mutations are indicated in a box at the left of the figure with an arrow indicating their contribution to DNA repair deficiency.

About 70% of malignant (cancerous) neoplasms have no hereditary component and are called "sporadic cancers".[26] Only a minority of sporadic cancers have a deficiency in DNA repair due to mutation in a DNA repair gene. However, a majority of sporadic cancers have deficiency in DNA repair due to epigenetic alterations that reduce or silence DNA repair gene expression. For example, of 113 sequential colorectal cancers, only four had a missense mutation in the DNA repair gene MGMT, while the majority had reduced MGMT expression due to methylation of the MGMT promoter region (an epigenetic alteration).[27] Five reports present evidence that between 40% and 90% of colorectal cancers have reduced MGMT expression due to methylation of the MGMT promoter region.[28][29][30][31][32]

Similarly, out of 119 cases of mismatch repair-deficient colorectal cancers that lacked DNA repair gene PMS2 expression, PMS2 was deficient in 6 due to mutations in the PMS2 gene, while in 103 cases PMS2 expression was deficient because its pairing partner MLH1 was repressed due to promoter methylation (PMS2 protein is unstable in the absence of MLH1).[33] In the other 10 cases, loss of PMS2 expression was likely due to epigenetic overexpression of the microRNA, miR-155, which down-regulates MLH1.[34]

In further examples, epigenetic defects were found at frequencies of between 13%-100% for the DNA repair genes BRCA1, WRN, FANCB, FANCF, MGMT, MLH1, MSH2, MSH4, ERCC1, XPF, NEIL1 and ATM. These epigenetic defects occurred in various cancers, including breast, ovarian, colorectal, and head and neck cancers. Two or three deficiencies in expression of ERCC1, XPF or PMS2 occur simultaneously in the majority of the 49 colon cancers evaluated by Facista et al.[35] Epigenetic alterations causing reduced expression of DNA repair genes is shown in a central box at the third level from the top of the figure in this section, and the consequent DNA repair deficiency is shown at the fourth level.

When expression of DNA repair genes is reduced, DNA damages accumulate in cells at a higher than normal level, and these excess damages cause increased frequencies of mutation or epimutation. Mutation rates strongly increase in cells defective in DNA mismatch repair[36][37] or in homologous recombinational repair (HRR).[38]

During repair of DNA double strand breaks, or repair of other DNA damages, incompletely cleared sites of repair can cause epigenetic gene silencing.[39][40] DNA repair deficiencies (level 4 in the figure) cause increased DNA damages (level 5 in the figure) which result in increased somatic mutations and epigenetic alterations (level 6 in the figure).

Field defects, normal-appearing tissue with multiple alterations (and discussed in the section below), are common precursors to development of the disordered and improperly proliferating clone of tissue in a malignant neoplasm. Such field defects (second level from bottom of figure) may have multiple mutations and epigenetic alterations.

Once a cancer is formed, it usually has genome instability. This instability is likely due to reduced DNA repair or excessive DNA damage. Because of such instability, the cancer continues to evolve and to produce sub clones. For example, a renal cancer, sampled in 9 areas, had 40 ubiquitous mutations, demonstrating tumor heterogeneity (i.e. present in all areas of the cancer), 59 mutations shared by some (but not all areas), and 29 "private" mutations only present in one of the areas of the cancer.[41]

Field defects

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Longitudinally opened freshly resected colon segment showing a cancer and four polyps, plus a schematic diagram indicating a likely field defect (a region of tissue that precedes and predisposes to the development of cancer) in this colon segment. The diagram indicates sub-clones and sub-sub-clones that were precursors to the tumors.

Various other terms have been used to describe this phenomenon, including field effect, field cancerization, and field carcinogenesis. The term field cancerization was first used in 1953 to describe an area or "field" of epithelium that has been preconditioned by (at that time) largely unknown processes so as to predispose it towards development of cancer.[42] Since then, the terms field cancerization and field defect have been used to describe pre-malignant tissue in which new cancers are likely to arise.[citation needed]

Field defects are important in progression to cancer.[43][44] However, in most cancer research, as pointed out by Rubin[45] "The vast majority of studies in cancer research has been done on well-defined tumors in vivo, or on discrete neoplastic foci in vitro. Yet there is evidence that more than 80% of the somatic mutations found in mutator phenotype human colorectal tumors occur before the onset of terminal clonal expansion.[46] Similarly, Vogelstein et al.[47] point out that more than half of somatic mutations identified in tumors occurred in a pre-neoplastic phase (in a field defect), during growth of apparently normal cells. Likewise, epigenetic alterations present in tumors may have occurred in pre-neoplastic field defects.[citation needed]

An expanded view of field effect has been termed "etiologic field effect", which encompasses not only molecular and pathologic changes in pre-neoplastic cells but also influences of exogenous environmental factors and molecular changes in the local microenvironment on neoplastic evolution from tumor initiation to patient death.[48]

In the colon, a field defect probably arises by natural selection of a mutant or epigenetically altered cell among the stem cells at the base of one of the intestinal crypts on the inside surface of the colon. A mutant or epigenetically altered stem cell may replace the other nearby stem cells by natural selection. Thus, a patch of abnormal tissue may arise. The figure in this section includes a photo of a freshly resected and lengthwise-opened segment of the colon showing a colon cancer and four polyps. Below the photo, there is a schematic diagram of how a large patch of mutant or epigenetically altered cells may have formed, shown by the large area in yellow in the diagram. Within this first large patch in the diagram (a large clone of cells), a second such mutation or epigenetic alteration may occur so that a given stem cell acquires an advantage compared to other stem cells within the patch, and this altered stem cell may expand clonally forming a secondary patch, or sub-clone, within the original patch. This is indicated in the diagram by four smaller patches of different colors within the large yellow original area. Within these new patches (sub-clones), the process may be repeated multiple times, indicated by the still smaller patches within the four secondary patches (with still different colors in the diagram) which clonally expand, until stem cells arise that generate either small polyps or else a malignant neoplasm (cancer).[citation needed]

In the photo, an apparent field defect in this segment of a colon has generated four polyps (labeled with the size of the polyps, 6mm, 5mm, and two of 3mm, and a cancer about 3 cm across in its longest dimension). These neoplasms are also indicated, in the diagram below the photo, by 4 small tan circles (polyps) and a larger red area (cancer). The cancer in the photo occurred in the cecal area of the colon, where the colon joins the small intestine (labeled) and where the appendix occurs (labeled). The fat in the photo is external to the outer wall of the colon. In the segment of colon shown here, the colon was cut open lengthwise to expose the inner surface of the colon and to display the cancer and polyps occurring within the inner epithelial lining of the colon.[citation needed]

If the general process by which sporadic colon cancers arise is the formation of a pre-neoplastic clone that spreads by natural selection, followed by formation of internal sub-clones within the initial clone, and sub-sub-clones inside those, then colon cancers generally should be associated with, and be preceded by, fields of increasing abnormality reflecting the succession of premalignant events. The most extensive region of abnormality (the outermost yellow irregular area in the diagram) would reflect the earliest event in formation of a malignant neoplasm.[citation needed]

In experimental evaluation of specific DNA repair deficiencies in cancers, many specific DNA repair deficiencies were also shown to occur in the field defects surrounding those cancers. The Table, below, gives examples for which the DNA repair deficiency in a cancer was shown to be caused by an epigenetic alteration, and the somewhat lower frequencies with which the same epigenetically caused DNA repair deficiency was found in the surrounding field defect.

Frequency of epigenetic changes in DNA repair genes in sporadic cancers and in adjacent field defects
Cancer Gene Frequency in cancer Frequency in field defect Ref.
Colorectal MGMT 46% 34% [28]
Colorectal MGMT 47% 11% [30]
Colorectal MGMT 70% 60% [49]
Colorectal MSH2 13% 5% [30]
Colorectal ERCC1 100% 40% [35]
Colorectal PMS2 88% 50% [35]
Colorectal XPF 55% 40% [35]
Head and neck MGMT 54% 38% [50]
Head and neck MLH1 33% 25% [51]
Head and neck MLH1 31% 20% [52]
Stomach MGMT 88% 78% [53]
Stomach MLH1 73% 20% [54]
Esophagus MLH1 77%-100% 23%-79% [55]

Some of the small polyps in the field defect shown in the photo of the opened colon segment may be relatively benign neoplasms. Of polyps less than 10mm in size, found during colonoscopy and followed with repeat colonoscopies for 3 years, 25% were unchanged in size, 35% regressed or shrank in size while 40% grew in size.[56]

Genome instability

[edit]

Cancers are known to exhibit genome instability or a mutator phenotype.[57] The protein-coding DNA within the nucleus is about 1.5% of the total genomic DNA.[58] Within this protein-coding DNA (called the exome), an average cancer of the breast or colon can have about 60 to 70 protein altering mutations, of which about 3 or 4 may be "driver" mutations, and the remaining ones may be "passenger" mutations.[47] However, the average number of DNA sequence mutations in the entire genome (including non-protein-coding regions) within a breast cancer tissue sample is about 20,000.[59] In an average melanoma tissue sample (where melanomas have a higher exome mutation frequency[47]) the total number of DNA sequence mutations is about 80,000.[60] This compares to the very low mutation frequency of about 70 new mutations in the entire genome between generations (parent to child) in humans.[61][62]

The high frequencies of mutations in the total nucleotide sequences within cancers suggest that often an early alteration in the field defects giving rise to a cancer (e.g. yellow area in the diagram in this section) is a deficiency in DNA repair. The large field defects surrounding colon cancers (extending to at about 10 cm on each side of a cancer) were shown by Facista et al.[35] to frequently have epigenetic defects in 2 or 3 DNA repair proteins (ERCC1, XPF or PMS2) in the entire area of the field defect. Deficiencies in DNA repair cause increased mutation rates.[36][37][38] A deficiency in DNA repair, itself, can allow DNA damages to accumulate, and error-prone translesion synthesis past some of those damages may give rise to mutations. In addition, faulty repair of these accumulated DNA damages may give rise to epimutations. These new mutations or epimutations may provide a proliferative advantage, generating a field defect. Although the mutations/epimutations in DNA repair genes do not, themselves, confer a selective advantage, they may be carried along as passengers in cells when the cells acquire additional mutations/epimutations that do provide a proliferative advantage.[citation needed]

Etymology

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The term neoplasm is a synonym of tumor. Neoplasia denotes the process of the formation of neoplasms/tumors, and the process is referred to as a neoplastic process. The word neoplastic itself comes from Greek neo 'new' and plastic 'formed, molded'.

The term tumor derives from the Latin noun tumor 'a swelling', ultimately from the verb tumēre 'to swell'. In the British Commonwealth, the spelling tumour is commonly used, whereas in the U.S. the word is usually spelled tumor.

In its medical sense, tumor has traditionally meant an abnormal swelling of the flesh. The Roman medical encyclopedist Celsus (c. 30 BC–38 AD) described the four cardinal signs of acute inflammation as tumor, dolor, calor, and rubor (swelling, pain, increased heat, and redness). (His treatise, De Medicina, was the first medical book printed in 1478 following the invention of the movable-type printing press.)

In contemporary English, the word tumor is often used as a synonym for a cystic (liquid-filled) growth or solid neoplasm (cancerous or non-cancerous),[63] with other forms of swelling often referred to as "swellings".[64]

Related terms occur commonly in the medical literature, where the nouns tumefaction and tumescence (derived from the adjective tumescent)[65] are current medical terms for non-neoplastic swelling. This type of swelling is most often caused by inflammation caused by trauma, infection, and other factors.

Tumors may be caused by conditions other than an overgrowth of neoplastic cells, however. Cysts (such as sebaceous cysts) are also referred to as tumors, even though they have no neoplastic cells. This is standard in medical-billing terminology (especially when billing for a growth whose pathology has yet to be determined).

See also

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References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Neoplasm

View on Grokipedia
from Grokipedia
A neoplasm is an abnormal mass of tissue that forms when cells grow and divide more than they should or fail to die when they should, resulting from uncontrolled cellular proliferation known as neoplasia. These growths, also referred to as tumors, can occur in any part of the body and arise from disruptions in the normal processes of cell replacement and regulation. Neoplasms are broadly classified into two main types: benign and malignant. Benign neoplasms are noncancerous, typically grow slowly, remain localized without invading surrounding tissues, and do not spread to other parts of the body; examples include lipomas (fatty tissue growths) and adenomas (glandular growths). Although generally not life-threatening, they may require treatment if they cause symptoms by pressing on nearby structures or organs. In contrast, malignant neoplasms are cancerous, exhibit rapid and uncontrolled growth, invade adjacent tissues, and can metastasize to distant sites via the bloodstream or , making them potentially lethal depending on their type, location, and stage. Malignant neoplasms, or cancers, are further subclassified based on the tissue of origin and , including carcinomas (arising from epithelial cells, accounting for about 90% of cases, such as those in , , or colon), sarcomas (from connective tissues like or muscle), leukemias (blood-forming cells in ), lymphomas (), and myelomas (plasma cells). The development of neoplasms often involves genetic mutations that impair control, though specific causes vary and include risk factors such as use, , certain infections, , and inherited predispositions. Diagnosis typically involves , biopsies, and tests, while treatment options range from surgical removal and for localized growths to and targeted therapies for advanced cases.

Overview

Definition

A neoplasm (/niːˈoʊplæzəm/) is an abnormal mass of tissue that forms when cells grow and divide more than they should or do not die when they should, resulting from neoplasia, the process of new, uncontrolled that does not serve a physiological purpose. The term derives from the words néos ('new') and plásma ('formation, creation'), reflecting its characterization as a tissue growth distinct from surrounding normal structures. Unlike physiological adaptations such as , which involves an increase in cell number in response to a stimulus and is reversible upon removal of that stimulus, or , an increase in cell size due to enhanced functional demand that also regresses when the demand ceases, neoplasms exhibit autonomous, unregulated growth that persists independently of any external trigger. This irreversible proliferation distinguishes neoplastic tissue from adaptive responses, as the growth continues even after the initiating stimulus is eliminated. The term "neoplasm" was coined in 1864 by German anatomist Karl Friedrich Burdach to describe non-inflammatory tissue masses arising from disordered cell growth, marking a shift in medical understanding toward . A hallmark of neoplastic growth is its clonality, wherein the abnormal cells originate from a single that has acquired heritable changes enabling uncontrolled expansion.

General Characteristics

Neoplasms are characterized by the of their cells, which proliferate and expand independently of normal host regulatory signals, often forming a discrete of tissue known as a tumor that can compress or infiltrate adjacent structures. This uncontrolled growth distinguishes neoplastic cells from normal tissues, as they evade typical growth constraints and exhibit metabolic independence, such as increased to support their proliferation. The resulting tumor may remain localized or expand progressively, exerting mechanical pressure on surrounding organs and tissues. At the cellular level, neoplasms typically arise from a monoclonal origin, where a single gives rise to the entire population, unifying their behavior through shared genetic alterations. Neoplastic cells display atypical morphology, including an enlarged nucleus with irregular shape, prominent nucleoli, and a high nuclear-to-cytoplasmic ratio, alongside frequent and often abnormal mitotic figures that reflect their dysregulated division. These features are hallmarks observed across various neoplasms, aiding in their microscopic identification. Neoplasms possess the potential for progression, remaining stable as benign entities or evolving toward , which introduces the capacity for and distant . While benign forms are generally non-invasive and self-limited, malignant neoplasms can disseminate via lymphatic or hematogenous routes, altering their clinical trajectory. This spectrum underscores the dynamic nature of neoplastic development. Clinically, neoplasms can produce local effects such as tissue obstruction, , or due to expansion, as seen in gastrointestinal tumors causing bowel blockage. Functional neoplasms, particularly those arising in endocrine tissues, may secrete excess hormones, leading to systemic imbalances like from adenomas or with flushing and . These impacts vary by location and type but commonly contribute to morbidity through direct compression or paraneoplastic phenomena.

Classification

Clonality

Neoplasms are characterized by their monoclonal origin, arising from a single that acquires somatic mutations, resulting in a of genetically identical daughter cells with altered proliferative capacity. This clonal expansion distinguishes neoplasms from normal tissue regeneration or reactive hyperplasias, which involve multiple cells. The concept of monoclonality underscores the neoplastic process as a Darwinian within the tumor, where the founding clone propagates and may give rise to subclones through further mutations. Clonality is demonstrated through various molecular techniques that reveal the uniform genetic makeup of neoplastic cells. In females heterozygous for X-linked markers, X-chromosome inactivation assays, such as those analyzing patterns at the human androgen receptor (HUMARA) locus, show a single active in tumor cells, indicating derivation from one . Similarly, (G6PD) isoenzyme analysis in heterozygous individuals demonstrates expression of only one enzyme variant (e.g., type A or B) in tumor tissue, as pioneered in studies of chronic myelocytic where all leukemic cells expressed a single G6PD type despite the patient's heterozygosity. In lymphoid neoplasms, particularly B-cell lymphomas, clonality is confirmed by detecting rearranged immunoglobulin genes via (PCR) or Southern blotting, revealing a dominant rearrangement pattern absent in polyclonal reactive lymphoid populations. Although most neoplasms are monoclonal, rare exceptions include polyclonal proliferations associated with certain viral infections, such as Epstein-Barr virus (EBV)-driven lymphoproliferations in immunocompromised patients, which may mimic neoplasia but lack true autonomous growth and often regress with immune reconstitution. These cases highlight that polyclonality typically signifies a reactive rather than a neoplastic one, as autonomous neoplasms require the stable genetic alterations of a founding clone. The assessment of clonality has critical diagnostic implications, enabling differentiation between neoplastic and reactive proliferations; for instance, monoclonal patterns in lymphoid tissues confirm over inflammatory conditions like reactive lymphadenitis, guiding therapeutic decisions. Polyclonal growths, by contrast, lack the neoplastic potential for invasion or , emphasizing clonality as a hallmark of the neoplastic process. Seminal studies using G6PD markers in heterozygous females have provided enduring evidence, showing that even histologically diverse tumors, such as those in the , express a single isoenzyme type, supporting their clonal origin from a single cell.

Benign Neoplasms

Benign neoplasms, also known as benign tumors, are abnormal growths composed of cells that multiply excessively but remain noncancerous and do not spread to other parts of the body. These tumors typically exhibit slow growth rates and are often encapsulated by a fibrous capsule that confines them to a specific , preventing local of surrounding tissues. As a result, they remain localized and are frequently curable through surgical excision, with low recurrence rates following complete removal. Histologically, benign neoplasms consist of well-differentiated cells that closely resemble the normal tissue from which they originate, maintaining organized and function. They display low mitotic activity, with rare and typical mitotic figures, and lack areas of due to adequate vascular supply supporting their slow expansion. This contrasts with more aggressive growths, as benign tumors expand by pushing against adjacent structures rather than infiltrating them. Common examples of benign neoplasms include lipomas, which arise from adipose (fatty) tissue and present as soft, subcutaneous masses; leiomyomas, such as uterine fibroids, originating from ; adenomas, glandular tumors like those in the or colon; and nevi, commonly known as moles, which are melanocytic proliferations on the skin. These examples illustrate the diverse tissue origins of benign growths, which can occur in nearly any . Clinically, benign neoplasms are usually and discovered incidentally during or examinations, though larger ones may exert a mass effect by compressing nearby nerves, blood vessels, or organs, leading to symptoms such as pain, obstruction, or functional impairment. For instance, a sizable uterine can cause pelvic pressure or , while a might induce headaches or neurological deficits through compression. Although generally indolent, certain benign neoplasms carry a rare risk of ; villous adenomas of the colon, for example, larger than 1 cm have a high risk of , with those >2 cm showing a 10-20% risk of containing . Benign neoplasms are far more prevalent than their malignant counterparts, often representing the majority of diagnosed tumors across various sites, such as soft tissues where benign lumps outnumber sarcomas significantly. Their frequent incidental detection underscores their commonality in the general population, with many remaining undetected throughout life.

Malignant Neoplasms

Malignant neoplasms, commonly referred to as cancers, are characterized by uncontrolled cellular proliferation that invades surrounding tissues and has the potential for , the spread of cancer cells to distant sites via lymphatic or hematogenous routes, resulting in multi-organ involvement. Unlike benign neoplasms, which remain localized, malignant tumors exhibit aggressive behavior that disrupts normal tissue architecture and function. Malignant neoplasms are graded based on the degree of , ranging from Grade 1 (well-differentiated, resembling normal cells) to Grade 4 (undifferentiated or anaplastic, showing little resemblance to the tissue of origin), which helps predict tumor behavior and guide treatment. They are staged using the TNM system, where T describes the size and extent, N indicates regional involvement, and M denotes the presence of distant , allowing for standardized assessment of disease progression from Stage 0 () to Stage IV (advanced metastatic disease). The major types of malignant neoplasms include carcinomas, which arise from epithelial tissues and account for 80-90% of all human cancers, such as adenocarcinomas of the or ; sarcomas, originating from mesenchymal tissues like or ; leukemias and lymphomas, which involve hematopoietic and lymphoid cells; and germ cell tumors, typically affecting reproductive or embryonic tissues. These categories reflect the diverse origins of malignant growths and their varying clinical presentations. Key clinical hallmarks of malignant neoplasms encompass , marked by loss of and pleomorphic nuclei; rapid and uncontrolled growth that outpaces blood supply; promotion of to sustain tumor expansion; and systemic effects like , a wasting syndrome involving severe , , and fatigue due to metabolic alterations induced by the tumor. These features contribute to the high morbidity and mortality associated with cancers, which remain the leading cause of death globally, responsible for approximately 10 million deaths annually as of 2020 data updated through 2023.

Causes

Genetic Factors

Genetic factors play a central role in the development of neoplasms through both inherited mutations and acquired somatic alterations that disrupt normal cellular regulation. Proto-oncogenes, which encode proteins involved in cell growth and division, can be activated by mutations to become oncogenes, promoting uncontrolled proliferation. For instance, point mutations in the RAS , particularly at codons 12, 13, or 61, lock the RAS protein in a constitutively active state, leading to persistent downstream signaling that drives tumorigenesis in various cancers, including pancreatic and colorectal carcinomas. Similarly, chromosomal translocations can fuse genes to create potent oncogenes, such as the BCR-ABL fusion resulting from the t(9;22) translocation in chronic myeloid leukemia, which produces a chimeric that constitutively activates signaling pathways essential for leukemic cell and expansion. Tumor suppressor genes, conversely, normally inhibit cell growth and promote or ; their inactivation contributes to neoplasm formation by removing these brakes. Alfred Knudson's , formulated based on incidence patterns, posits that both alleles of a must be inactivated for tumor development: one inherited in hereditary cases and a somatic "second hit" in the other allele, or two somatic hits in sporadic cases. This model was exemplified by mutations in the RB1 gene, where biallelic loss leads to by derepressing transcription factors and promoting uncontrolled progression. Inherited genetic syndromes arise from germline mutations in tumor suppressor genes, conferring high lifetime cancer risks. Li-Fraumeni syndrome, caused by heterozygous TP53 mutations, predisposes individuals to a broad spectrum of cancers, including sarcomas, breast cancer, brain tumors, and leukemias, with nearly a 100% lifetime cancer risk for females and about 90% cumulative risk by age 60 overall. Mutations in BRCA1 and BRCA2 genes increase the risk of hereditary breast and ovarian cancer, with BRCA1 carriers having a 55-72% lifetime breast cancer risk and 39-46% ovarian cancer risk, while BRCA2 carriers face 45-69% and 10-27% risks, respectively, due to impaired DNA double-strand break repair. Familial adenomatous polyposis results from APC gene mutations, leading to hundreds of colorectal polyps and nearly 100% risk of colorectal cancer by age 40 if untreated, as APC normally regulates Wnt signaling to prevent polyp formation. Most neoplasms arise from somatic mutations accumulated over time in non-inherited cells, following a multistep process. In , Bert Vogelstein's model describes sequential somatic alterations: early inactivation initiates formation, followed by activation for growth, and late TP53 loss enabling invasion and , illustrating how these genetic hits progressively transform normal into . Approximately 5-10% of all cancers are hereditary, stemming from , while the vast majority are sporadic, driven by somatic changes. These genetic alterations contribute to the clonal expansion characteristic of neoplasms by conferring selective growth advantages to mutated cells.

Environmental Factors

Environmental factors play a significant role in neoplasm development, encompassing a range of external exposures that can initiate or promote cellular changes leading to uncontrolled growth. These modifiable risks include chemical agents, physical stressors, infectious pathogens, choices, and occupational hazards, collectively for a substantial portion of preventable cancers worldwide. Unlike inherent genetic predispositions, environmental influences often interact with genetic factors to elevate overall risk, but their impact can be mitigated through avoidance and interventions. Chemical carcinogens, such as those in tobacco smoke, are among the most potent environmental contributors to neoplasms. Tobacco smoke contains polycyclic aromatic hydrocarbons and other toxins that damage lung tissue, with approximately 85% of lung cancer cases attributable to smoking. Asbestos fibers, another key chemical agent, are strongly linked to mesothelioma, a rare cancer of the lung lining, following prolonged inhalation in contaminated environments. Physical agents like and ultraviolet (UV) radiation also drive neoplasm formation through direct cellular disruption. Exposure to , as experienced by atomic bomb survivors in and , significantly increases risk, with studies showing a dose-dependent elevation in incidence rates peaking years after exposure. UV radiation from induces in skin DNA, contributing to the majority of cases, particularly in fair-skinned populations with high sun exposure. Infectious agents are responsible for about 13% of the global cancer burden as of 2018, highlighting the role of pathogens in oncogenesis. Human papillomavirus (HPV) infection causes nearly all cervical cancers, while hepatitis B virus (HBV) and hepatitis C virus (HCV) account for over 70% of hepatocellular carcinomas through chronic liver inflammation. Helicobacter pylori bacteria, a common gastric pathogen, is associated with approximately 90% of non-cardia gastric cancers. Lifestyle factors further amplify environmental risks, with dietary patterns, alcohol consumption, and serving as key modifiable contributors. High-fat, low-fiber diets are linked to increased incidence via altered and inflammation, while excessive alcohol intake elevates risks for esophageal and liver cancers through production and . , often driven by caloric excess, promotes endometrial and postmenopausal cancers via elevated and insulin levels. Occupational exposures represent targeted environmental hazards, particularly in industrial settings. , a solvent used in manufacturing, is a known cause of following chronic inhalation or contact. , encountered in and production, heightens risks for and cancers, with contamination also posing widespread threats in certain regions.

Pathophysiology

DNA Damage

DNA damage represents a fundamental initiator of neoplastic transformation, arising from both endogenous and exogenous sources that compromise genomic integrity. Endogenous damage includes base modifications such as oxidation and alkylation, single-strand breaks, and spontaneous hydrolysis, often generated by (ROS) during normal cellular metabolism. Exogenous insults, such as (UV) radiation or , induce bulky adducts, strand breaks, and inter- and intrastrand crosslinks that distort the DNA helix. These lesions, if unrepaired, can lead to mutations that disrupt cellular and promote oncogenesis. Cells employ specialized DNA repair pathways to counteract these threats and maintain genome stability. (BER) addresses small, non-helix-distorting lesions like oxidized or alkylated bases by excising the damaged nucleotide and replacing it via activity. (NER) targets bulky, helix-distorting adducts, such as those formed by UV-induced cyclobutane , through recognition, excision, and resynthesis; defects in NER, as seen in , confer a greater than 10,000-fold increased risk of non-melanoma skin cancers due to unchecked accumulation of photoproducts. Mismatch repair (MMR) corrects base-base mismatches and insertion/deletion loops arising during ; germline MMR defects underlie Lynch , substantially elevating lifetime risks for colorectal, endometrial, and other cancers through . Persistent DNA damage evading repair contributes to by fostering somatic mutations in key regulatory genes. Unresolved lesions during replication can cause nucleotide substitutions, including characteristic UV-induced C>T transitions at dipyrimidine sites, which are prevalent in driver mutations such as those in BRAF and NRAS. These mutations activate oncogenes or inactivate tumor suppressors like TP53, enabling uncontrolled proliferation and survival advantages. Additionally, failures in exacerbate this process; the G1/S checkpoint, mediated by /ATR signaling, halts progression to allow repair of single-strand breaks, while the G2/M checkpoint prevents in the presence of double-strand breaks, but their dysfunction permits damaged cells to divide, amplifying mutational load. Therapeutically, neoplasms' reliance on imperfect DNA repair is exploited by DNA-damaging chemotherapeutics. Agents like form intrastrand and interstrand crosslinks that stall replication forks and trigger in rapidly dividing cancer cells, achieving high efficacy in treating testicular, ovarian, and lung cancers by overwhelming repair capacity. This vulnerability underscores DNA damage as both a driver and a target in neoplastic progression.

Field Defects

Field defects, also known as , refer to multifocal regions of genetically altered cells within apparently normal tissue that predispose to the development of multiple neoplasms, often arising from shared early mutagenic events such as chronic exposure to carcinogens. This concept was first described in in the context of oral squamous cell carcinomas, where atypical epithelial changes were observed in clinically normal mucosa surrounding tumors, suggesting a lateral spread of premalignant alterations. These fields represent patchy areas of mutated cell clones that have undergone selective expansion but lack the full transformative changes required for overt . At the molecular level, field defects involve the accumulation of low-level somatic mutations and epigenetic changes, such as TP53 alterations, without progression to invasive cancer, creating a primed tissue environment vulnerable to further oncogenic hits. For instance, in head and neck squamous cell carcinomas associated with exposure, clonal TP53 mutations are detected in normal-appearing epithelium adjacent to tumors, contributing to the risk of synchronous or metachronous lesions. Similarly, in , low-frequency TP53 mutations in metaplastic epithelium serve as a field defect predisposing to esophageal . Other examples include in sun-exposed skin, where p53-mutated clones form fields that progress to , and the colonic mucosa in (FAP), where germline APC mutations create widespread polypoid fields prone to development. Detection of field defects relies on molecular analysis of biopsies from surrounding tissue, including assessment of (LOH) at key loci like 17p13 (TP53) or 9p21, and epigenetic markers such as promoter hypermethylation patterns (e.g., or ). In head and neck cancers, LOH analysis has identified clonal fields in over 60% of cases with recurrent disease, while methylation profiling in colorectal mucosa detects field alterations up to 10 cm from tumors. Clinically, field defects explain elevated rates of local recurrence and multiple primary tumors, necessitating wider surgical margins or field-directed therapies like topical chemoprevention to eradicate subclinical lesions. In skin cancers, recognizing actinic fields guides to reduce incidence, while in FAP, prophylactic addresses the entire colonic field to prevent inevitable progression. This understanding enhances risk stratification and strategies for at-risk tissues.

Genome Instability

Genome instability in neoplasms encompasses the heightened propensity for chromosomal and epigenetic alterations that drive tumor progression, often arising from the accumulation of unrepaired DNA damage in preceding pathophysiological stages. This instability manifests as dynamic changes within tumor cells, promoting heterogeneity and evolutionary adaptation, distinct from static initial lesions. Chromosomal instability (CIN) is a primary form of genome instability characterized by recurrent errors in chromosome segregation and structure, leading to aneuploidy and structural rearrangements such as translocations. A classic example is the Philadelphia chromosome, a t(9;22) translocation resulting in the BCR-ABL fusion gene that drives chronic myeloid leukemia (CML). CIN contributes to the malignant phenotype by generating diverse karyotypes that enhance tumor adaptability. Microsatellite instability (MSI) represents another key type, arising from defects in DNA mismatch repair (MMR) proteins, which fail to correct replication errors in repetitive microsatellite sequences, resulting in hypermutable DNA tracts. This is prominently featured in Lynch syndrome, an autosomal dominant condition caused by germline mutations in MMR genes like MLH1, MSH2, MSH6, or PMS2, predisposing individuals to colorectal and other cancers with high MSI. MSI-high tumors exhibit a distinct mutational profile that influences immune recognition and therapeutic response. Epigenetic instability involves aberrant modifications that alter gene expression without changing the DNA sequence, including hypermethylation of promoter CpG islands that silences tumor suppressor genes. For instance, hypermethylation of the MLH1 promoter leads to MMR deficiency and MSI in sporadic colorectal cancers. Additionally, dysregulated histone modifications, such as altered acetylation or methylation patterns, contribute to chromatin remodeling that favors oncogenic states and genomic instability. Key drivers of genome instability include telomere dysfunction, where critically short telomeres lose protective function, prompting end-to-end chromosomal fusions and breakage-fusion-bridge cycles that amplify rearrangements. Centrosome amplification, often triggered by oncogenic signaling, disrupts mitotic spindle assembly, leading to multipolar mitoses and unequal chromosome distribution. These mechanisms perpetuate a cycle of ongoing genomic alterations within the tumor. Genome instability fuels Darwinian evolution in neoplasms by generating variant subclones, with selective pressures favoring aggressive phenotypes that evade and metastasize. In breast cancer, elevated CIN correlates with poor prognosis, as it promotes intratumor heterogeneity and resistance to treatment. This evolutionary dynamic underscores instability's role in transitioning from benign to malignant states. Recent advances in , as of 2025, have illuminated how drives intratumor heterogeneity, revealing subclonal variations in copy number alterations and mutational burdens that underpin tumor adaptability. For example, in , single-cell sequencing has shown that metastatic lesions exhibit heightened chromosomal instability signatures, correlating with increased heterogeneity and worse outcomes. These insights highlight the spatial and temporal dynamics of instability in neoplasm progression.

Terminology

Etymology

The term neoplasm derives from the Greek roots neo- meaning "new" and plasma meaning "formation" or "mold," literally translating to "new formation." This etymology emphasizes the concept of an autonomous tissue growth arising independently of normal physiological processes. The word was first coined in 1864 by the German anatomist and physiologist Karl Friedrich Burdach to describe a pathological new growth distinct from the surrounding tissues, marking a precise linguistic distinction in medical terminology. It was subsequently popularized in the mid-19th century following Rudolf Virchow's advancement of cellular pathology; his 1858 work Die Cellularpathologie framed abnormal growths as arising from disordered cellular proliferation rather than simple inflammatory swellings, contributing to the conceptual framework for terms like "neoplasm" and differentiating them from the broader Latin-derived term "tumor" (meaning "swelling"). The related term neoplasia, denoting the abnormal process of new tissue formation, entered around 1871, further refining the conceptual framework for understanding uncontrolled growth. Overall, the adoption of "neoplasm" and its variants reflects the pivotal 19th-century transition from ancient humoral theories of disease—viewing imbalances in bodily fluids as the root of —to Virchow's revolutionary cellular paradigm, which grounded disease in microscopic tissue changes.

Neoplasm vs. Tumor

In medical contexts, the terms "neoplasm" and "tumor" are often employed synonymously to describe abnormal tissue growths, especially palpable masses, though "tumor" traditionally denotes any localized swelling, including non-neoplastic examples such as abscesses formed by . A neoplasm, by contrast, specifically indicates an abnormal proliferation of cells driven by neoplastic changes in cellular regulation, distinguishing it from mere swellings caused by , trauma, or other reactive processes. This distinction clarifies that while all neoplasms have the potential to manifest as tumors when they aggregate into a discrete mass, not all tumors qualify as neoplasms; for example, a —a localized collection of extravasated blood following —forms a swelling classified as a tumor but arises from vascular disruption rather than neoplastic . Likewise, an , characterized by pus accumulation due to bacterial and , represents an inflammatory tumor without the uncontrolled cellular replication inherent to neoplasms. In practice, "tumor" is predominantly reserved for solid, localized growths, such as carcinomas of the or tumors, whereas "neoplasm" encompasses a broader , including non-solid forms like , a hematopoietic neoplasm involving widespread abnormal proliferation in the blood and bone marrow without forming a distinct tumor mass. The term "tumor" originated in ancient as one of the four cardinal signs of —tumor (swelling), rubor (redness), calor (heat), and dolor (pain)—as articulated by the Roman physician around 25 AD, reflecting its initial association with any inflammatory response rather than specifically neoplastic . By the , pathological advancements, including microscopic examination of tissues, shifted its primary usage toward neoplastic contexts, reserving the broader sense of swelling for descriptive rather than diagnostic purposes. Among the general public, a prevalent misconception equates "tumor" directly with cancer, overlooking that tumors include both benign (non-invasive) and malignant (invasive) neoplasms, as well as entirely non-neoplastic swellings, with only the malignant subset representing cancerous growth.

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