Abstract
Gingival fibromatosis is a rare and heterogeneous group of disorders that develop as slowly progressive, local or diffuse enlargements within marginal and attached gingiva or interdental papilla. In severe cases, the excess tissue may cover the crowns of the teeth, thus causing functional, esthetic, and periodontal problems, such as bone loss and bleeding, due to the presence of pseudopockets and plaque accumulation. It affects both genders equally. Hereditary, drug-induced, and idiopathic gingival overgrowth have been reported. Hereditary gingival fibromatosis can occur as an isolated condition or as part of a genetic syndrome. The pathologic manifestation of gingival fibromatosis comprises excessive accumulation of extracellular matrix proteins, of which collagen type I is the most prominent example. Mutation in the Son-of-Sevenless-1 gene has been suggested as one possible etiological cause of isolated (non-syndromic) hereditary gingival fibromatosis, but mutations in other genes are also likely to be involved, given the heterogeneity of this condition. The most attractive concept of mechanism for drug-induced gingival overgrowth is epithelial-to-mesenchymal transition, a process in which interactions between gingival cells and the extracellular matrix are weakened as epithelial cells transdifferentiate into fibrogenic fibroblast-like cells. The diagnosis is mainly made on the basis of the patient’s history and clinical features, and on histopathological evaluation of affected gingiva. Early diagnosis is important, mostly to exclude oral malignancy. Differential diagnosis comprises all pathologies in the mouth with excessive gingival overgrowth. Hereditary gingival fibromatosis may present as an autosomal-dominant or less commonly autosomal-recessive mode of inheritance. If a systemic disease or syndrome is suspected, the patient is directed to a geneticist for additional clinical examination and specialized diagnostic tests. Treatments vary according to the type of overgrowth and the extent of disease progression, thus, scaling of teeth is sufficient in mild cases, while in severe cases surgical intervention is required. Prognosis is precarious and the risk of recurrence exists.
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Background
Gingival fibromatosis (GF) is a rare condition characterized by pathological, diffuse or local growth of gingiva. In severe cases functional, periodontal, esthetic and psychological problems may occur. The condition may be related to hereditary factors and occurs as a non-syndromic hereditary gingival fibromatosis (HGF) or as a part of a syndrome. It may also develop in susceptible individuals as a side effect of systemic medications, including the anti-seizure, immunosuppressant, or calcium channel blockers. In some cases the etiology of the enlargement remains unknown. Excessive accumulation of extracellular matrix (ECM) components seems to contribute to the pathologic manifestation of GF, however, the molecular mechanisms responsible for it remain undefined. The risk of recurrence and lack of non-invasive therapies for GF used in dental practice highlight the necessity of searching for novel alternate therapies for this condition. The aim of this article is to present an updated review of the clinical features, etiology, differential diagnosis, pathological mechanisms and management of GF.
Review
Disease name and synonyms
GF is also called gingivomatosis, gingival enlargement, gingival hyperplasia, gingival overgrowth (GO), elephantiasis gingivae, familial elephantiasis, gigantism of the gingiva, and congenital macrogingivae [1].
Definition
GF is a condition characterized by the pathological growth of gingival tissue. It is also described as “gingival enlargement”, which comprises gingival hyperplasia and hypertrophy. Hyperplasia refers to an increased number of cells, and hypertrophy refers to an increase in the size of the individual cells. GF can present as HGF, which may appear as an isolated entity or as part of a genetic disease or syndrome, as drug-induced gingival overgrowth (DIGO, GO) or as idiopathic gingival fibromatosis (IGF).
Epidemiology
GF associated with hereditary factors (non-syndromic)
HGF (GINGF, ORPHA 2024, MIM 135300) is a rare disease with unknown prevalence [2–4] (Table 1).
GF associated with genetic diseases and syndromes
GF may also co-exist with rare genetic syndromes and diseases, i.e. GF with craniofacial dysmorphism (ORPHA 2025, MIM 228560) [5], GF with progressive deafness (ORPHA 2027, MIM 135550) [6], infantile systemic hyalinosis (ISH, ORPHA 2176, MIM 236490) [7], juvenile hyaline fibromatosis (JHF, Murray-Puretic-Drescher syndrome, ORPHA 2028, MIM 228600) [8], Zimmermann-Laband syndrome (ZLS, ORPHA 3473, MIM 135500) [9], amelogenesis imperfecta/nephrocalcinosis syndrome (ORPHA 1031, MIM 204690) [10], amelogenesis imperfecta/GF syndrome (AIGFS, ORPHA 171836, MIM 614253) [11], and oculodental syndrome (Rutherfurd syndrome, ORPHA 2709, MIM 180900) [12], which occur with a prevalence of one or less per million population. The frequency of other genetic entities that present with a periodontal phenotype, i.e. GF/hypertrichosis syndrome (ORPHA 2026, MIM 135400) [13] and Ramon syndrome (ORPHA 3019, MIM 266270) [14], is unknown (Table 1).
DIGO
The reported incidence of GF induced by the anti-epileptic drug, phenytoin could be as high as 70 % [15]. It also occurs in 15–83 % of patients treated with nifedipine [16, 17], 21 % of patients taking diltiazem [18], and approximately 4 % of patients cured with verapamil [19], while the prevalence rate of gingival enlargement in patients treated with cyclosporine A (CsA) is estimated at between 8 and 70 % [20–22].
IGF
IGF is known to affect 1 in 750,000 individuals, and can occur in both genders and in either of the jaws [1, 23, 24].
Clinical description
The most common form of GF occurs as a benign, slowly progressive and non-hemorrhagic enlargement of the gingiva. It affects the masticatory mucosa (the marginal and attached gingiva and the interdental papilla), but it does not spread beyond the muco-gingival junction. GF can be generalized, idiopathic or hereditary (non-syndromic) (Figs. 1a and 2a) or associated with different genetic diseases. Clinically, the onset coincides with the eruption of primary or permanent dentition, and rarely presents at birth [25]. GF may also occur as a local, nodular-like lesion. The excess gingival tissue can cover part of or the entire crown, and can result in diastemas, teeth displacement, or retention of primary or impacted teeth, and may also cause masticatory, phonetic, psychological, and esthetic problems [26]. An example of a local, nodular-like lesion in the posterior maxillary region of the gingiva in a 35-year-old patient diagnosed as an IGF is depicted in Fig. 3a. Clinical features of isolated HGF, and genetic syndromes and diseases co-existing with HGF are presented in Table 1. DIGO usually occurs as a generalized (diffuse) enlargement usually visible within several months after the onset of systemic therapy. This is in contrast to HGF, which is characterized by a slow, progressive growth of the gingival tissue. GO may vary from mild to severe, depending on the dose of the drug. Combination therapy, such as with amlodipine, a calcium channel blocker used in the management of hypertension and angina, and cholesterol-lowering drugs, can result in more severe GO than single-agent therapy [17]. Although the clinical appearance of lesions resulting from different medications is similar, the histopathology of DIGO lesions varies depending on the inducing drug [27]. Hyperplastic gingiva usually presents a normal coloration or can be erythematous. Periodontal problems, such as bleeding and bone loss, might occur due to the excess of gingival tissue, presence of pseudopockets and plaque accumulation [17, 28–30].
Histopathological description
The typical histopathology of the lesion involves hyperplasia of the epithelium with elongated rete ridges extending into the underlying connective tissue [31–34] (Figs. 1b and 2b). The connective tissue consists of excess collagen, but has relatively few fibroblasts and blood vessels [35, 36] (Fig. 1b). Enlarged fibroblasts appear to alternate with thin and thick collagen fibrils. Elastic and oxytalan fibers are also present in GF lesions. Unlike in normal gingiva, coarse and fine dense collagen fiber bundles are oriented in all directions [32, 33, 37] (Fig. 3b). Small osseous calcifications and abundant neurovascular bundles may also be present. The excess of gingival tissue may provide new niches for the growth of microorganisms, plaque accumulation and pseudopockets formation resulting in inflammatory infiltration of the gingival connective tissue [17, 38–41] (Fig. 2b).
Diseases associated with “gingival enlargement”
Gingival enlargement covers broad etiological entities classified into five general groups:
-
1.
Enlargement associated with non-genetic diseases
GF can be directly or indirectly linked to poor nutrition (vitamin C deficiency) [42], systemic hormonal stimulation (pregnancy or puberty) [43], blood dyscrasias (leukemia) [44–47], Wegener’s granulomatosis [48], orofacial granulomatosis [49], pyogenic granuloma [50] and sarcoidosis [51]. It may also be associated with pseudotumors [52, 53], benign neoplasms, e.g. giant cell fibroma [54], gingival and oral myofibroma [55–57], papilloma [58], giant cell granuloma [59], and malignant neoplasms, e.g. oral squamous cell carcinoma [60, 61], salivary gland tumors [62, 63], melanoma [64–67], adenoma and mucoepidermoid carcinoma [68].
-
2.
Enlargement associated with inflammatory diseases of the oral cavity
Gingival enlargement may develop during the course of inflammatory diseases of the oral cavity, for example localized and generalized aggressive periodontitis (AP) and primary gingival tuberculosis [69–73]. Plaque accumulation and bacterial infection resulting from poor oral hygiene are significant predisposing factors [41, 74]. Other examples are inflammatory pseudotumors [53] and inflammatory fibrous hyperplasia due to local irritants [75].
-
3.
Enlargement associated with hereditary factors and co-existing with genetic diseases and syndromes [4, 9–14, 25, 35, 41]
- 4.
- 5.
Etiology
GF associated with hereditary factors (non-syndromic and associated with genetic diseases and syndromes)
HGF (ORPHA 2024, MIM 135300) is a rare and slowly progressive condition characterized by etiological heterogeneity [4, 23, 29, 41, 77]. Additionally, it may co-exist with several genetic diseases or syndromes (Table 1). Moreover, it may occur sporadically in several other syndromes and diseases. An example is Cowden syndrome (multiple hamartoma syndrome, CWS1-6, ORPHA201, MIM 158350) [78], a rare autosomal dominant disorder characterized by multiple hamartomas and a high risk of development of malignancy. It is now believed that 25 % of CWS cases (CWS1) are caused by germline mutations in the phosphatase and tensin homolog (PTEN) gene (10q23), which encodes PTEN, a dual-specificity phosphatase. Patients with CWS and CWS-like phenotypes without PTEN involvement have been found to have germline promoter methylation of KLLN (10q23; CWS4) (30 % of cases); germline variations in SDHB (1p36; CWS2), SDHC or SDHD (11q23; CWS3) (10 % of cases); or germline mutations in AKT1 (14q32; CWS6) or PIK3CA (3q26; CWS5) (10 % of cases) [79–82]. The most predominant features of the syndrome are small papular cutaneous lesions, papillomatous outgrowth, and fibromas of the oral mucosa and tongue [83, 84]. The co-existence of gingival hyperplasia with Cowden syndrome was reported by two groups [85, 86]. Another example is Bardet-Biedl syndrome (BBS1-19, ORPHA 110, MIM 209900) [87], a rare, heterogeneous, oligogenic or autosomal recessive condition with a prevalence in Europe estimated at between 1/125,000 and 1/175,000. Clinical features include obesity, pigmentary retinopathy, post-axial polydactyly, polycystic kidneys, hypogenitalism, and learning disabilities, many of which appear several years after disease onset. The clinical expression is variable, but most patients exhibit the majority of these clinical features during the disease course [88–91]. Dental anomalies, regarded as secondary manifestations, include hypodontia, microdontia, short roots, and a deep palate. The first case of BBS with generalized GO was reported by Drugowick et al. [92]. An example of a disease where genetic and infective factors are involved is AP. It is a rare, severe, and rapidly progressive form of periodontitis that develops as a result of complex interactions between specific host genes and the local microenvironment of the oral cavity. Factors which increase the risk of AP development include: familial aggregation, single nucleotide polymorphisms, functional defects in neutrophils, antibodies to specific bacteria, herpes virus infection, stress and smoking [69]. Though GF and AP usually occur as separate entities, several reports describe the co-existence of these diseases. The first report was published by Mahajan et al. [70], followed by reports by Jadwat et al. [71], Chaturvedi [93], Sandhu et al. [94], and Vishnoi and Phadnaik [72]. Recently, Ramachandra et al. [95] reported a case of gingival enlargement associated with generalized AP and the presence of mesiodens. The common features of GF and localized AP are their onset around puberty, female predilection, hereditary background, and progression in the presence of minimal local factors, although secondary involvement can aggravate the pre-existing condition [96].
HGF may be transmitted as a Mendelian trait in an autosomal dominant or, less commonly, an autosomal recessive fashion [29]. Linkage analysis has provided clues about the etiology of the disease, and showed several chromosomal regions that may contain mutations responsible for HGF. Loci for isolated, non-syndromic autosomal dominant forms of HGF have been localized to chromosome 2p21-p22 in a Brazilian family [97], and to chromosome 5q13-q22 [98] and 11p15 in a number of Chinese families [99]. The candidate loci are GINGF, GINGF2 and GINGF4, respectively.
After sequencing 16 genes in the candidate interval (2p21-p22), a single base insertion in the Son-of-Sevenless-1 (SOS-1) gene (MIM 182530) underlying GINGF locus, was detected in a Brazilian family [100], but not in three Chinese families [101]. Similar to the observations of Ma et al., our recent study did not confirm the presence of a single nucleotide insertion in the SOS-1 gene in two Polish families diagnosed with non-syndromic HGF (unpublished data). Interestingly, in four other Chinese families, non-syndromic HGF was linked to a mutation in the 2p21 locus (GINGF), as previously reported by Hart et al. [97]. A mutation in the SOS-1 gene has been suggested as one possible etiological factor/causing gene for isolated, non-syndromic HGF, but considering the genetic heterogeneity of HGF, mutations in other genes are also likely to be involved.
By haplotype construction and analysis in a five-generation Chinese family segregating autosomal dominant HGF, Ye et al. [102] identified a novel locus, which they designated GINGF3, in an 11.4 cM interval between markers D2S2221 and D2S1788 on chromosome 2p23.3-p22.3. Authors noted that this locus is distal to and does not overlap with the previously described GINGF locus on 2p22-p21 [102].
DIGO
Drug-induced GF occurs in susceptible individuals as a side effect of systemic medications, including the anti-epileptic drug phenytoin, the immunosuppressant CsA, and calcium channel blockers, namely, dihydropyridines, particularly nifedipine, diltiazem, and verapamil, which are widely used to control hypertension [103, 104]. Currently, more than 20 drugs are associated with gingival enlargement [17, 105]. Although the drugs that can cause GO have distinct mechanisms of action and act on different primary target tissues, they all seem to have a similar adverse effect on the gingival connective tissue [22, 104, 106]. In addition to being disfiguring, GO may also lead to poor oral hygiene and decreased oral function in individuals already suffering from conditions such as epilepsy, cardiovascular diseases, or immunosuppression [107]. The pathogenesis of DIGO is dependent on several factors, such as: age, genetic predisposition, pharmacokinetic variables, alterations in gingival connective tissue homeostasis, pre-existing dental plaque and gingival inflammation, and interaction of drugs and growth factors [106, 108, 109].
Pathogenesis and Pathophysiology
The pathologic manifestation of GF is excessive accumulation of ECM proteins, including collagen type I [110–114]. Thus far, however, the molecular and biochemical mechanisms that trigger this pathological process are not completely understood.
During collagen biosynthesis, nascent single procollagen polypeptides undergo post-translational modification in the endoplasmic reticulum (ER), form triple-helical chains, and are secreted into the extracellular space. This process involves heat shock protein 47 (HSP47), a 47 kDa glycoprotein localized in the ER. It binds to the nascent type I procollagen peptides to prevent premature folding and aggregation of procollagen chains, and participates in the translocation and secretion of procollagen I into the extracellular space [115]. Type I collagen and HSP47 mRNA and protein levels are increased significantly in fibroblast cultures derived from patients with HGF [116]. Moreover, transforming growth factor (TGF)-β1 and interleukin (IL)-6 induce the expression of type I collagen and HSP47 and to downregulate matrix metalloproteinase (MMP)-1 and MMP-2 in fibroblast cultures from HGF patients. The effect of TGF-β1 and IL-6 on the synthesis of other ECM proteins was also reported in DIGO [112, 117–120]. By contrast, interferon-γ (IFN-γ) reduced collagen I and HSP47 expression, and it slightly affected MMP-1 and MMP-2 expression [116]. This observation suggests that HSP47 may be a crucial molecule in the post-translational processing of the overproduced type I procollagen chains, while enhanced TGF-β1 and IL-6 production in patients with GF may favor the accumulation of collagen fibrils in the gingiva.
Prolyl 4 hydroxylases (P4Hs) are equally essential enzymes in the biosynthesis and folding of newly-synthesized collagen polypeptide chains into triple-helical molecules [121]. P4Hs are α2β2 tetramers consisting of one of three isoforms of subunit α [α(I), α(II), or α(III)] that have similar catalytic activity [122]. The expression of the α subunit of P4Hs limits the rate of active P4H formation, P4H activity, and collagen synthesis [123]. Increased levels of P4H activity are reported in a number of fibrotic conditions such as keloids and hepatic fibrosis [124, 125]. Some studies report increased expression and activity of prolyl hydroxylases in IGF, DIGO, and HGF [126, 127]. Notably, Meng et al. [127] identified isoform I of the α subunit of P4Hα as the isoform associated with GO, while the type II and III forms of P4H were not affected. These findings suggest that P4Hα (I) might be involved in the pathogenesis of HGF and confirm that HGF fibroblasts are deregulated at the level of post-translational protein modification.
Alterations in the expression of MMPs, key enzymes regulating the composition of the ECM, have been implicated in the pathogenesis of GF. Several studies show a significant decrease in the expression and activity of MMP-1 and MMP-2 in fibroblasts from HGF patients in comparison with controls [116, 128]. MMP-1 is a collagenase that degrades interstitial collagen, while MMP-2 acts predominantly on type IV collagen, but it has also been shown to degrade type I collagen in its native form [129]. Similarly, the inhibition of MMP-1, MMP-2, and MMP-3 has been reported in CsA-induced GO, a condition also associated with enhanced TGF-β1 production [114, 130, 131]. The catalytic activity of the MMPs is regulated at the transcriptional level as well as by tissue matrix metalloproteinase inhibitors (TIMPs). Interestingly, addition of anti-TGF-β1 antibodies in the study by Coletta et al. [128] resulted in a slight increase in MMP-1 and a decrease in MMP-2 expression, whereas TIMP-1 and TIMP-2 expression were unaffected. These results confirm previous observations that enhanced TGF-β1 production may lead to the accumulation of ECM by altering the proteolytic activities of fibroblasts.
Systemic therapy with CsA, phenytoin, and nifedipine modulates cytokine levels and indirectly affects gingival connective tissue metabolism. For example, Hong and Trackman [132] observed that the mRNA expression of lysyl oxidase and collagen type I by human gingival fibroblasts decreased to 53 % and to less than 10 % of control levels, respectively, after 48 h of treatment with 1 nM basic fibroblast growth factor (bFGF), while lysyl oxidase enzymatic activity was downregulated by 10–20 %. By contrast, interleukin - 1 (IL-1), IL-6, and platelet-derived growth factor-BB (PDGF-BB) did not significantly regulate the enzymatic activity of lysyl oxidase or the mRNA levels of lysyl oxidase, collagen type I or elastin [132]. The opposite effect was found by stimulation of gingival fibroblasts with TGF-β1. In brief, TGF-β1 upregulated lysyl oxidase and collagen type I, but not elastin, in a dose- and time-dependent manner. The maximal effect on lysyl oxidase activity and mRNA expression, as well as the mRNA expression of collagen I occurred after 48 h of treatment of gingival fibroblastic cells with 400 pM TGF-β1.
It has also been shown that mRNA and protein synthesis of connective tissue growth factor (CTGF or CCN2) are significantly induced by TGF-β1 in human gingival fibroblasts [133]. CTGF/CCN2 is a member of the CCN family, members of which contain conserved cysteine-rich domains and have a variety of biological activities [134]. CTGF promotes the proliferation of various cell types [135, 136] and is highly expressed in a wide variety of fibrotic lesions, including skin and kidney fibrosis, and atherosclerosis [137–139]. Uzel et al. [27] assessed the expression and localization of CTGF in GO induced by three different systemic medications. CTGF expression was significantly higher in phenytoin-induced GO than in CsA- or nifedipine-induced GO. Similar observations are reported by Hong et al. [133]. Considering that phenytoin-induced lesions are more fibrotic than nifedipine- and CsA-induced lesions, it seems that CTGF levels correlate positively with fibrosis and have a role in promoting and maintaining fibrosis. Development of fibrotic events can involve the process known as epithelial/mesenchymal transition (EMT). It occurs physiologically during organ and tissue development. In this process, partial destruction of the basement membrane can lead to inappropriate diffusion of factors between the connective tissue and the epithelial layers of gingival tissues. These factors can stimulate epithelial cells to lose cell-cell contacts, decrease E-cadherin expression, and increase cell motility, promoting their invasion into the underlying connective tissue stroma, where they differentiate further into cells that are indistinguishable from fibroblasts and myofibroblasts. These fibroblastic cells, in turn, produce connective tissue proteins that contribute to fibrosis [140–142].
Diagnosis
A diagnosis of GF is made mainly on the basis of clinical and periodontal examination, a medical and family history and laboratory tests. Clinical examination, medical history and laboratory tests determine initially whether the condition is inherited or acquired, the presence of other diseases, the prior therapies used, and the involvement of primary dentition. Histopathological analysis characterizes the typical features of fibromatotic gingiva, such as the rate of epithelial acanthosis, connective tissue density and cellular content, the extent of fibrosis or inflammatory infiltrates. Periodontal examination, including X-ray and histopathology serve mainly to assess the type (local, diffuse, fibrous or inflammatory) and the severity of gingival involvement, including bone erosion, and allow the physician to choose the optimal treatment option [143–146].
Differential diagnosis
If a genetic background is found, it is important to verify whether the lesion is an isolated entity or occurs as part of a multisystem pathology. The list of the syndromes associated with periodontal involvement is presented in Table 1. Particularly important are neoplasms, though benign tumors and pseudotumors can given similar patterns of clinical involvement [52]. Amongst benign tumors of the gingiva, giant cell fibroma, irritation fibroma, neurofibroma, angiofibroma (tuberous sclerosis or Bourneville-Pringle disease), inflammatory myofibroblastoma and epulis fissuratum should be considered. Epulis fissuratum is a specific condition usually found in patients with removable full dentures. Inflammatory myofibroblastoma ranges from completely benign to malignant tumors with a fatal outcome [53–57, 147, 148]. Malignant neoplasms which have to be considered are oral squamous cell carcinoma [60, 61], salivary gland adenocarcinoma [62, 63], melanoma 64–67], adenoma and mucoepidermoid carcinoma [68]. Regarding DIGO, it may occur not only for calcium channel blockers, CsA and phenytoin but also with other immunosuppressants or anticonvulsants, antibiotics, and oral contraceptives [149]. Differential diagnosis of GF with granulomatous lesions includes systemic diseases such as sarcoidosis, Crohn’s disease, and tuberculosis, as well as lesions localized to the orofacial region like orofacial granulomatosis [48, 49, 51, 150]. Although leukemia is a malignant disease of the blood, where the uncontrolled proliferation of immature blood cells takes place, leukemic infiltration of oral tissues may occur, resulting in a pale mucosa, poor wound healing, and bleeding, which in some cases can resemble GF [45, 46]. Lymphomas rarely manifest initially in the oral cavity, but misdiagnosis is highly probable because maxillary and mandibular swelling can mimic fibrotic lesion [47, 151]. All these conditions require thorough analysis of medical history, laboratory tests, and histopathology as a delay in the diagnosis, particularly in the case of malignancy may worsen the prognosis.
Genetic counseling
HGF may present as an autosomal-dominant or less commonly autosomal-recessive mode of inheritance, as an isolated disorder or as part of a syndrome [4, 9, 10, 13, 152]. Autosomal dominant forms are usually isolated (non-syndromic) and have been genetically linked to several loci, i.e. GINGF, GINGF2, GINGF3, GINGF4 [97–100, 102] (Table 1). If clinical/periodontal examination, family history and laboratory tests initially indicate a genetic background, other family members are called to the clinic to confirm the presence of HGF, draw up a pedigree diagram, and determine whether it constitutes an isolated entity or co-exists with another disease or syndrome. If a systemic disease or syndrome is suspected, the patient is directed to a geneticist for additional clinical examination and specialized diagnostic tests. In such cases psychological support is needed to assess a risk of occurrence in future pregnancies, the option of early prenatal diagnosis and optimal treatment.
Management including treatment
The patient’s medical history (e.g. patient’s age and the presence of other diseases) and the findings of the clinical examination (e.g. the type and severity of overgrowth) influence the patient’s management. While some surgical approaches, such as the use of laser excision, reportedly reduce the recurrence, re-growth of the excised gingival tissue due to the continuous use of the drug presents a significant challenge [153]. The usual treatment of GF includes external bevel gingivectomy using a scalpel, unless this is complicated by bony defects, in which case, a flap surgery is carried out. The surgery is followed by 0.12 % chlorhexidine oral rinses twice a day for 2 weeks. Removal of the hypertrophic tissue can be also done by electrosurgery or by laser, reducing the risk of bleeding and pain. This type of procedure decreases significantly the quantity of local anesthetic used, leads to better visibility, which reduces the chairside time, and results in better patient acceptance [74, 154, 155]. Non-surgical treatment includes scaling and root planing, oral hygiene instructions and administration of antibiotics, usually amoxicillin and metronidazole, along with anti-inflammatory (ibuprofen) and analgesic (paracetamol) drugs and the use of chlorhexidine mouth rinses. At the end of the fourth week, internal bevel gingivectomy along with open flap debridement is carried out. This procedure eliminates the pocket, reduces the bulk of the tissue and makes plaque control much easier. Management of patients diagnosed with GF and AP includes non-surgical treatments, surgery with regenerative or resective therapy and anti-microbial treatment. Regenerative techniques include the use of bone grafts, barrier membranes, wound healing agents and enamel matrix protein. Local drug delivery, full mouth disinfection and host immune response modulation are other modes of treatment [38, 72, 76, 95, 156–158].
Because of difficulties in the treatment of DIGO, the status of oral health prior to and during drug administration, in combination with drug serum levels and the duration of therapy, are key factors in the management of the condition. Discontinuing or dramatically lowering the dose of the drug often results in resolution of clinical signs and lesions. However, this is not always medically feasible, particularly in whole-organ transplant recipients.
Evidence suggests that 34 % of cases demonstrate recurrence during the 18 months following periodontal surgery regardless of the drug [156]. Although GO lesions are not directly life-threatening and may be tolerated by some patients without treatment, the quality of life is clearly compromised among affected individuals. Therefore, to stabilize the long-term outcomes and alleviate suffering for those who are adversely affected, non-surgical therapies to treat GO are of importance. Although progress in the clinical management of human GO has been made in relatively affluent societies, approaches of drug substitutions and careful dose adjustments are not universally practiced by physicians worldwide, and this contributes to the global public health impact of GO [157, 159].
Prognosis
Complications related to GF include difficulties with mastication, speech problems, displacement of teeth, esthetic effects, and psychological difficulties for the patient; therefore, appropriate treatment and postoperative management are crucial. Gingival enlargement as a form of periodontal tissue reaction may impose a challenge to periodontists as well. Routine treatment of minimal and local enlargements relies on keeping appropriate oral hygiene and/or root scaling, while cases of advanced, diffuse gingival enlargement require surgical intervention. Recurrence can occur several months to several years after surgery [36, 41, 160–162].
Conclusions
GF is a rare and slowly progressive condition that is also characterized by etiological heterogeneity. Additionally, this condition constitutes a typical symptom of several genetic syndromes, and it may occur sporadically in several other syndromes and diseases, as reported recently. By contrast, DIGO may occur as soon as several months from the onset of systemic therapy in susceptible individuals treated with certain anti-seizure drugs, immunosuppressants or calcium channel blockers. Diagnosis is made based on medical history, clinical examination, blood tests and histopathological evaluation of affected gingival tissue. Differential diagnosis includes consideration of all pathologies in the mouth that involve excessive accumulation of gingival tissue, including syndromic HGF. In general, the histological features of GF are similar, but phenytoin-induced GO is reported to be most fibrotic and to express higher levels of CTGF than nifedipine- and CsA-induced GO. Excessive accumulation of ECM components, particularly collagen type I, seems to contribute to the pathologic manifestation of all etiological types of GF; however, the molecular mechanisms responsible for it remain undefined. Further studies concerning interactions among medications, the innate and acquired immune response, cytokines and growth factors, and gingival epithelial and connective tissue cells are essential for a better understanding of the detailed molecular and mechanistic pathways controlling the unique metabolism of gingival connective tissue. This would improve disease management and allow the implementation of less invasive therapeutic methods than surgery into routine dental practice.
Abbreviations
- ABCA5 :
-
ATP-binding cassette, subfamily A, member 5
- AIGFS:
-
amelogenesis imperfecta/gingival fibromatosis syndrome
- AKT1 :
-
v-akt murine thymoma viral oncogene homolog 1
- ANTXR2 :
-
anthrax toxin receptor 2
- AP:
-
aggressive periodontitis
- BBS:
-
Bardet-Biedl syndrome
- bFGF:
-
basic fibroblast growth factor
- CAMK :
-
calcium/calmodulin-dependent protein kinase IV
- CGHT:
-
congenital generalized hypertrichosis terminalis
- CsA:
-
cyclosporine A
- CTGF/CCN2:
-
connective tissue growth factor
- CWS:
-
Cowden syndrome
- DIGO:
-
drug-induced gingival overgrowth
- ECM:
-
extracellular matrix
- EMT:
-
epithelial/mesenchymal transition
- ER:
-
endoplasmic reticulum
- ERS:
-
enamel-renal syndrome
- FAM20A :
-
family with sequence similarity 20, member A
- GF:
-
gingival fibromatosis
- GO:
-
gingival overgrowth
- HGF:
-
hereditary gingival fibromatosis
- HSP 47:
-
heat shock protein 47
- HTC3:
-
gingival fibromatosis/hypertrichosis syndrome
- IFN γ:
-
Interferon γ
- IGF:
-
idiopathic gingival fibromatosis
- IHC:
-
immunohistochemistry
- IL-1:
-
Interleukin-1
- IL-6:
-
Interleukin-6
- ISH:
-
infantile systemic hyalinosis
- JHF:
-
juvenile hyaline fibromatosis
- KCNH1 :
-
potassium channel, voltage-gated, subfamily H, member-1
- KLLN :
-
killin, p53-regulated DNA replication inhibitor
- MIM:
-
mendelian inheritance in man
- MMP:
-
matrix metalloproteinase
- P4H:
-
prolyl 4 hydroxylase
- PCNA:
-
proliferating cell nuclear antigen
- PDGF-BB:
-
platelet-derived growth factor-BB
- PIK3CA :
-
phosphatidylinositol-4,5-bisphosphate 3-kinase, catalytic subunit alpha
- PTEN :
-
phosphatase and tensin homolog
- SDHB :
-
succinate dehydrogenase complex, subunit B, iron sulfur (Ip)
- SDHC :
-
succinate dehydrogenase complex, subunit C, integral membrane protein
- SDHD :
-
succinate dehydrogenase complex, subunit D, integral membrane protein
- SOS-1 :
-
Son-of-Sevenless-1
- TGF-β1 :
-
transforming growth factor-β1
- TIMP:
-
tissue matrix metalloproteinase inhibitor
- ZLS:
-
Zimmermann-Laband syndrome
References
Pappachan B, Narayan JV, Nayak A. Idiopathic gingival fibromatosis: A neglected case. Indian J Radiol Imaging. 2002;12:335–38.
Kavvadia K, Pepelassi E, Alexandridis C, Arkadopoulou A, Polyzois G, Tossios K. Gingival fibromatosis and significant tooth eruption delay in an 11-year-old male: a 30-month follow-up. Int J Paediatr Dent. 2005;15:294–302.
Kather J, Salgado MA, Salgado UF, Cortelli JR, Pallos D. Clinical and histomorphometric characteristics of three different families with hereditary gingival fibromatosis. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2008;105:348–52.
Hereditary gingival fibromatosis. Orphanet. January 2013. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=1955. (Accessed 09/09/2015).
Gingival fibromatosis – facial dysmorphism. Orphanet. 2010. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=1956. (Accessed 15/09/2015).
Gingival fibromatosis–progressive deafness. Orphanet. May 2007. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=1958. (Accessed 15/09/2015).
Infantile systemic hyalinosis (ISH). Orphanet. June 2008. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=2069. (Accessed 17/09/2015).
Juvenile hyaline fibromatosis (Murray-Puretic-Drescher syndrome, Puretic syndrome). Orphanet. November 2014. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=1959. (Accessed 17/09/2015).
Zimmermann-Laband syndrome (Laband syndrome). Orphanet. November 2011. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=3052. (Accessed 17/09/2015).
Amelogenesis imperfecta-nephrocalcinosis syndrome. Orphanet. January 2013. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=1339. (Accessed 17/09/2015).
Amelogenesis imperfecta-gingival hyperplasia syndrome. Orphanet. October 2009. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=17937. (Accessed 17/09/2015).
Oculodental syndrome, Rutherfurd type (Gingival hypertrophy-corneal dystrophy). Orphanet. July 2015. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=2470. (Accessed 17/09/2015).
Gingival fibromatosis-hypertrichosis syndrome. Orphanet. January 2013. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=1957. (Accessed 15/09/2015).
Ramon syndrome (cherubism-gingival fibromatosis-intellectual disability). Orphanet. December 1986. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=2715. (Accessed 15/09/2015).
Hassell TM. Phenytoin: gingival overgrowth. In: Myers HM, editor. Epilepsy and the oral manifestations of phenytoin therapy. New York: Karger; 1981. p. 116–202.
Barak S, Engelberg IS, Hiss Z. Gingival hyperplasia caused by nifedipine: Histopathologic findings. J Periodontol. 1987;58:639–42.
Pasupuleti MK, Musalaiah SV, Nagasree M, Kumar PA. Combination of inflammatory and amlodipine induced gingival overgrowth in a patient with cardiovascular disease. Avicenna J Med. 2013;3:68–72.
Steel RM, Schuna AA, Schreilber RT. Calcium antagonist-induced gingival hyperplasia. Ann Intern Med. 1994;120:663–64.
Miller CS, Damm DD. Incidence of verapamil-induced gingival hyperplasia in a dental population. J Periodontol. 1992;63:453–56.
Seymour RA, Heasman PA. Drugs and the periodontium. J Clin Periodontol. 1988;15:1–16.
Hefti AF, Eshenaur AE, Hassell TM, Stone C. Gingival overgrowth in cyclosporine A treated multiple sclerosis patients. J Periodontol. 1994;65:744–49.
Kataoka M, Kido J, Shinohara Y, Nagata T. Drug-induced gingival overgrowth-a review. Biol Pharm Bull. 2005;28:1817–21.
Bittencourt LP, Campos V, Moliterno LF, Ribeiro DP, Sampaio RK. Hereditary gingival fibromatosis: review of the literature and a case report. Quintessence Int. 2000;31:415–18.
Tiwana PS, De Kok IJ, Stoker DS, Cooper LF. Facial distortion secondary to idiopathic gingival hyperplasia: Surgical management and oral reconstruction with endosseous implants. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2005;100:153–57.
Breen GH, Addante R, Black CC. Early onset of hereditary gingival fibromatosis in a 28-month-old. Pediatr Dent. 2009;31:286–88.
Millet C, Rodier P, Farges JC, Labert N, Duprez JP. Surgical and prosthetic treatment in an elderly patient affected by unilateral idiopathic gingival fibromatosis: a case report. Gerodontology. 2012;29:e1185–89.
Uzel MI, Kantarci A, Hong HH, Uygur C, Sheff MC, Firatli E, et al. Connective tissue growth factor in drug-induced gingival overgrowth. J Periodontol. 2001;72:921–31.
Aimetti M, Romano F, Debernardi C. Effectiveness of periodontal therapy on the severity of cyclosporin A-induced gingival overgrowth. J Clin Periodontol. 2005;32:846–50.
Häkkinen L, Csiszar A. Hereditary gingival fibromatosis: Characteristics and novel putative pathogenic mechanisms. J Dent Res. 2007;86:25–34.
Kumar R, Singh RK, Verma N, Verma UP. Phenytoin-induced severe gingival overgrowth in a child. BMJ Case Rep. 2014;21:2014.
Pernu HE, Oikarinen K, Hietanen J, Knuuttila M. Verapamil-induced gingival overgrowth: a clinical, histologic, and biochemic approach. J Oral Pathol Med. 1989;18:422–25.
Kelekis-Cholakis A, Wiltshire WA, Birek C. Treatment and long-term follow-up of a patient with hereditary gingival fibromatosis: a case report. J Can Dent Assoc. 2002;68:290–94.
Sakamoto R, Nitta T, Kamikawa Y, Kono S, Kamikawa Y, Sugihara K, et al. Histochemical, immunohistochemical, and ultrastructural studies of gingival fibromatosis: a case report. Med Electron Microsc. 2002;35:248–54.
Kantarci A, Nseir Z, Kim YS, Sume SS, Trackman PC. Loss of basement membrane integrity in human gingival overgrowth. J Dent Res. 2011;90:887–93.
Hart TC, Pallos D, Bozzo L, Almeida OP, Marazita ML, O’Connell JR, et al. Evidence of genetic heterogeneity for hereditary gingival fibromatosis. J Dent Res. 2000;79:1758–64.
Baptista IP. Hereditary gingival fibromatosis: A case report. J Clin Periodontol. 2002;29:871–74.
Gawron K, Łazarz-Bartyzel K, Chomyszyn-Gajewska M. Clinical presentation and management of a rare case of unilateral idiopathic gingival fibromatosis. Dent Med Probl. 2014;51:546–52.
Casavecchia P, Uzel MI, Kantarci A, Hatice Hasturk H, Dibart S, Hart TC, et al. Hereditary gingival fibromatosis associated with generalized aggressive periodontitis: a case report. J Periodontol. 2004;75:770–78.
Dongari-Bagtzoglou A. Research, Science and Therapy Committee, American Academy of Periodontology. Drug-associated gingival enlargement. J Periodontol. 2004;75:1424–31.
Tavargeri AK, Kulkarni SS, Sudha P, Basavprabhu SP. Idiopathic gingival fibromatosis - a case report. J Indian Soc Pedod Prev Dent. 2004;22:180–82.
Gawron K, Lazarz-Bartyzel K, Lazarz M, Steplewska K, Pyrc K, Potempa J, et al. In vitro testing the potential of a novel chimeric IgG variant for inhibiting collagen fibrils formation in recurrent hereditary gingival fibromatosis: chimeric antibody in a gingival model. J Physiol Pharmacol. 2014;65:585–91.
Li R, Byers K, Walvekar RR. Gingival hypertrophy: a solitary manifestation of scurvy. Am J Otolaryngol. 2008;29:426–28.
McIntosh CL, Kolhatkar S, Winkler JR, Ojha J, Bhola M. An unusual case of generalized severe gingival enlargement during pregnancy. Gen Dent. 2010;58(6):e272–78.
Howard MR, Hamilton PJ. Haematology. 3rd ed. Philadelphia: Elsevier; 2008.
Dalirsani Z, Bolouri AJ, Delavarian Z, Bidad S, Sanatkhani M, Amirchaghmaghi M. Human T-lymphotropic virus-1 associated with adult T-cell lymphoma/ leukemia and generalized expansion of palatal and jaw bones: a rare case report. J Dent Shiraz Univ Med Sci. 2015;16:214–18.
Zimmermann C, Meurer MI, Grando LJ, Gonzaga Del Moral JA, da Silva Rath IB, Schaefer Tavares S. Dental treatment in patients with leukemia. J Oncol. 2015;2015:571739.
Dalirsani Z, Ghazi A. T-cell lymphoblastic lymphoma in the maxilla and mandible of a child: a rare case report. J Clin Diagn Res. 2015;9:ZD22–24.
Stewart C, Cohen D, Bhattacharyya I, Scheitler L, Riley S, Calamia K, et al. Oral manifestations of Wegener’s granulomatosis: a report of three cases and a literature review. J Am Dent Assoc. 2007;138:338–48.
Rangdhol RV, Madhulika N, Dany A, Jeelani S, Asokan GS. Idiopathic orofacial granulomatosis - a diagnostic and treatment challenge. J Clin Diagn Res. 2014;8:ZD07–10.
Jané-Salas E, Albuquerque R, Font-Muñoz A, González-Navarro B, Estrugo Devesa A, López-López J. Pyogenic Granuloma/Peripheral Giant-Cell Granuloma Associated with Implants. Int J Dent. 2015;2015:839032.
Tripathi P, Aggarwal J, Chopra D, Bagga S, Sethi K. Sarcoidosis presenting as isolated gingival enlargement: a rare case entity. J Clin Diagn Res. 2014;8:ZD25–26.
Oota S, Shibuya H, Hamagaki M, Yoshimura R, Iwaki H, Kojima M, et al. Oral pseudotumor: benign polypoid masses following radiation therapy. Cancer. 2003;97:1353–57.
Liston SL, Dehner LP, Jarvis CW, Pitzele C, Huseby TL. Inflammatory pseudotumors in the buccal tissues of children. Oral Surg Oral Med Oral Pathol. 1981;51:287–91.
Magnusson BC, Rasmusson LG. The giant cell fibroma. A review of 103 cases with immunohistochemical findings. Acta Odontol Scand. 1995;53:293–96.
Abdul Jalil A, Lau SH. Gingival myofibroma in children: report of 4 cases with immunohistochemical findings. Malays J Pathol. 2007;29:53–56.
Vered M, Allon I, Buchner A, Dayan D. Clinico-pathologic correlations of myofibroblastic tumors of the oral cavity. II. Myofibroma and myofibromatosis of the oral soft tissues. J Oral Pathol Med. 2007;36:304–14.
Brasileiro BF, Martins-Filho PR, Piva MR, da Silva LC, Nonaka CF, Miguel MC. Myofibroma of the oral cavity. A rare spindle cell neoplasm. Med Oral Patol Oral Cir Bucal. 2010;15:e596–600.
Scrieciu M, Mercuţ V, Mercuţ R, Amărăscu MO, Popescu SM, Predescu AM, et al. Immunohistochemical aspects of apoptosis in gingival mucosa with papilloma and condyloma acuminate. Rom J Morphol Embryol. 2015;56:425–31.
Tandon PN, Gupta SK, Gupta DS, Jurel SK, Saraswat A. Peripheral giant cell granuloma. Contemp Clin Dent. 2012;3 Suppl 1:S118–21.
Qaisi M, Vorrasi J, Lubek J, Ord R. Multiple primary squamous cell carcinomas of the oral cavity. J Oral Maxillofac Surg. 2014;72:1511–16.
Tsubochi H, Suzuki T, Suzuki S. Immunohistochemical study of basaloid squamous cell carcinoma, adenoid cystic and mucoepidermoid carcinoma in the upper aerodigestive tract. Anticancer Res. 2000;20:1205–11.
Namboodiripad PC. A review: immunological markers for malignant salivary gland tumors. J Oral Biol Craniofac Res. 2014;4:127–34.
Alos L, Lujan B, Castillo M, Nadal A. Expression of membrane-bound mucins (MUC1 and MUC4) and secreted mucins (MUC2, MUC5AC, MUC5B, MUC6 and MUC7) in mucoepidermoid carcinomas of salivary glands. Am J Surg Pathol. 2005;29:806–13.
Ardekian L, Rosen DJ, Peled M, Rachmiel A, Machtei EE, el Naaj IA, et al. Primary gingival malignant melanoma. Report of 3 cases. J Periodontol. 2000;71:117–20.
Reddy BV, Sridhar GR, Anuradha CH, Chandrasekhar P, Lingamaneni KP. Malignant melanoma of the mandibular gingiva: a rare occurrence. Indian J Dent Res. 2010;21:302–5.
Mendenhall WM, Amdur RJ, Hinerman RW, Werning JW, Villaret DB, Mendenhall NP. Head and neck mucosal melanoma. Am J Clin Oncol. 2005;28:626–30.
Thomas PS, Babu GS, Anusha RL, Shetty S. Oral malignant melanoma-an unusual presentation. Gerodontology. 2012;29:e1241–43.
Rasheed FS, Majeed Ahlam H. Immunohistochemical expression of actin and S100 in pleomorphic adenoma and mucoepidermoid carcinoma. Oral Diag. 2011;23:51–54.
Meng H, Xu L, Li Q, Han J, Zhao Y. Determinants of host susceptibility in aggressive periodontitis. Periodontol 2000. 2007;43:133–59.
Mahajan A, Dixit J, Umesh V. An intriguing case of gingival enlargement associated with generalized aggressive periodontitis. Periodontal Pract Today. 2007;4:295–99.
Jadwat Y, Anagnostopoulos C, Wood NH, Lemmer J, Meyerov RH, Feller L. Localized aggressive periodontitis associated with unusual gingival enlargement posing a diagnostic dilemma: A case report. SADJ. 2008;63:230–32.
Vishnoi SL, Phadnaik MB. Unusual gingival enlargement with aggressive periodontitis: A case report. J Contemp Dent Pract. 2010;11:49–55.
Gupta G, Khattak BP, Agrawal V. Primary gingival tuberculosis: a rare clinical entity. Contemp Clin Dent. 2011;2:31–33.
Pihlstrom BL, Michalowicz BS, Johnson NW. Periodontal diseases. Lancet. 2005;366:1809–2000.
Shukla P, Dahiya V, Kataria P, Sabharwal S. Inflammatory hyperplasia: From diagnosis to treatment. J Indian Soc Periodontol. 2014;18:92–94.
Shetty AK, Shah HJ, Patil MA, Jhota KN. Idiopathic gingival enlargement and its management. J Indian Soc Periodontol. 2010;14:263–65.
Becker W, Collings CK, Zimmerman ER, De La Rosa M, Singdahlsen D. Hereditary gingival fibromatosis. A report on a family in which three members were affected with fibromatosis of the gingiva. Oral Surg. 1967;24:313–18.
Cowden syndrome (Multiple hamartoma syndrome). Orphanet. July 2013. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=243. (Accessed 17/09/2015).
Liaw D, Marsh DJ, Li J, Dahia PLM, Wang SI, Zheng Z, et al. Germline mutations of the PTEN gene in Cowden disease, an inherited breast and thyroid cancer syndrome. Nature Genet. 1997;16:64–67.
Blumenthal GM, Dennis PA. PTEN hamartoma tumor syndromes. Eur J Hum Genet. 2008;16:1289–300.
Hobert JA, Mester JL, Moline J, Eng C. Elevated plasma succinate in PTEN, SDHB, and SDHD mutation-positive individuals. Genet Med. 2012;14:616–19.
Orloff MS, He X, Peterson C, Chen F, Chen JL, Mester JL, et al. Germline PIK3CA and AKT1 mutations in Cowden and Cowden-like syndromes. Am J Hum Genet. 2013;92:76–80.
Swart JG, Lekkas C, Allard RH. Oral manifestations in Cowden’s syndrome. Report of four cases. Oral Surg Oral Med Oral Pathol. 1985;59:264–68.
Lee HR, Moon YS, Yeom CH, Kim KW, Chun JY, Kim HK, et al. Cowden’s disease-a report on the first case in Korea and literature review. J Korean Med Sci. 1997;12:570–75.
Breton P, Cambazard M, Rougier M, Freidel M, Angoh JJ. Maxillofacial manifestations of Cowden’s disease. Apropos of 2 cases. Rev Stomatol Chir Maxillofac. 1988;89:87–91.
Feitosa DS, Santamaria MP, Casati MZ, Sallum EA, Nociti Júnior FH, de Toledo S. Surgical management of gingival overgrowth associated with Cowden sydrome: a case report and current understanding. Quintessence Int. 2011;42:e60–64.
Bardet-Biedl syndrome (BBS). Orphanet. December 2008. http://www.orpha.net/consor/cgi-bin/Disease_Search.php?lng=EN&data_id=3244. (Accessed 04/10/2015).
Leppert M, Baird L, Anderson KL, Otterud B, Lupski JR, Lewis RA. Bardet-Biedl syndrome is linked to DNA markers on chromosome 11q and is genetically heterogeneous. Nature Genet. 1994;7:108–12.
Croft JB, Morrell D, Chase CL, Swift M. Obesity in heterozygous carriers of the gene for the Bardet-Biedl syndrome. Am J Med Genet. 1995;55:12–15.
Beales PL, Elcioglu N, Woolf AS, Parker D, Flinter FA. New criteria for improved diagnosis of Bardet-Biedl syndrome: results of a population survey. J Med Genet. 1999;36:437–46.
Scheidecker S, Etard C, Pierce NW, Geoffroy V, Schaefer E, Muller J, et al. Exome sequencing of Bardet-Biedl syndrome patient identifies a null mutation in the BBSome subunit BBIP1 (BBS18). J Med Genet. 2014;51:132–36.
Drugowick RM, Da Rós Gonçalves L, Barrôso AS, Feres-Filho EJ, Maia LC. Treatment of gingival overgrowth in a child with Bardet-Biedl syndrome. J Periodontol. 2007;78:1159–63.
Chaturvedi R. Idiopathic gingival fibromatosis associated with generalized aggressive periodontitis: a case report. J Can Dent Assoc. 2009;75:291–95.
Sandhu SP, Kakar V, Gogia G, Narula SC. Unilateral gingival fibromatosis with localized aggressive periodontitis (involving first molars): An unusual case report. J Indian Soc Periodontol. 2009;13:109–13.
Ramachandra SS, Hegde M, Prasad UC. Gingival enlargement and mesiodens associated with generalized aggressive periodontitis: a case report. Dent Update. 2012;39:364–66.
Novak KF, Novak MJ. Aggressive periodontitis. In: Newman MG, Takei HH, Klokkevold PR, Carranza FA, editors. Clinical Periodontology. India: WB Saunders Co; 2007. p. 507.
Hart TC, Pallos D, Bowden DW, Bolyard J, Pettenati MJ, Cortelli JR. Genetic linkage of hereditary gingival fibromatosis to chromosome 2p21. Am J Hum Genet. 1998;62:876–83.
Xiao S, Bu L, Zhu L, Zheng G, Yang M, Qian M, et al. A new locus for hereditary gingival fibromatosis (GINGF2) maps to 5q13-q22. Genomics. 2001;74:180–85.
Zhu Y, Zhang W, Huo Z, Zhang Y, Xia Y, Li B, et al. A novel locus for maternally inherited human gingival fibromatosis at chromosome 11p15. Hum Genet. 2007;121:113–23.
Hart TC, Zhang Y, Gorry MC, Hart PS, Cooper M, Marazita ML, et al. A mutation in the SOS1 gene causes hereditary gingival fibromatosis type 1. Am J Hum Genet. 2002;70:943–54.
Ma Y, Sun Z, Hu Y, Liu Y, Jin L, Zhang F. Non-syndromic hereditary gingival fibromatosis in three chinese families is not due to SOS1 gene mutations. Cell Biochem and Biophys. 2014;70:1869–73.
Ye X, Shi L, Cheng Y, Peng Q, Huang S, Liu J, et al. A novel locus for autosomal dominant hereditary gingival fibromatosis, GINGF3, maps to chromosome 2p22.3-p23.3. Clin Genet. 2005;68:239–44.
Nishikawa S, Nagata T, Morisaki I, Oka T, Ishida H. Pathogenesis of drug-induced gingival overgrowth. A review of studies in the rat model. J Periodontol. 1996;67:463–71.
Trackman PC, Kantarci A. Connective tissue metabolism and gingival overgrowth. Crit Rev Oral Biol Med. 2004;15:165–75.
Rees TD, Levine RA. Systemic drugs as a risk factor for periodontal disease initiation and progression. Compend Contin Educ Dent. 1995;16:20–42.
Seymour RA, Thomason JM, Ellis JS. The pathogenesis of drug-induced gingival overgrowth. J Clin Periodontol. 1996;23:165–75.
Li X, Kolltveit KM, Tronstad L, Olsen I. Systemic diseases caused by oral infection. Clin Microbiol Rev. 2000;13:547–58.
Meisel P, Schwahn C, John U, Kroemer HK, Kocher T. Calcium antagonists and deep gingival pockets in the population-based SHIP study. Br J Clin Pharmacol. 2005;60:552–59.
Jean SM, Sharma P, Taylor D, Mook D. Cyclosporine-induced gingival overgrowth in New Zealand white rabbits (Oryctolagus cuniculus). Comparative Med. 2009;59:357–62.
Bonnaure-Mallet M, Tricot-Doleux S, Godeau GJ. Changes in extracellular matrix macromolecules in human gingiva after treatment with drugs inducing gingival overgrowth. Arch Oral Biol. 1995;40:393–400.
Tipton DA, Howell KJ, Dabbous MK. Increased proliferation, collagen, and fibronectin production by hereditary gingival fibromatosis fibroblasts. J Periodontol. 1997;68:524–30.
Tipton DA, Dabbous MK. Autocrine transforming growth factor beta stimulation of extracellular matrix production by fibroblasts from fibrotic human gingiva. J Periodontol. 1998;69:609–19.
Coletta RD, Almeida OP, Ferreira LR, Reynolds MA, Sauk JJ. Increase in expression of Hsp47 and collagen in hereditary gingival fibromatosis is modulated by stress and terminal procollagen N-propeptides. Connect Tissue Res. 1999;40:237–49.
Bolzani G, Della Coletta R, Martelli Júnior H, Martelli Júnior H, Graner E. Cyclosporin A inhibits production and activity of matrix metalloproteinases by gingival fibroblasts. J Periodontal Res. 2000;35:51–58.
Satoh M, Hirayoshi K, Yokota S, Hosokawa N, Nagata K. Intracellular interaction of collagen-specific stress protein HSP47 with newly synthesized procollagen. J Cell Biol. 1996;133:469–83.
Martelli-Junior H, Cotrim P, Graner E, Sauk JJ, Coletta RD. Effect of transforming growth factor-beta1, interleukin-6, and interferon-gamma on the expression of type I collagen, heat shock protein 47, matrix metalloproteinase (MMP)-1 and MMP-2 by fibroblasts from normal gingiva and hereditary gingival fibromatosis. J Periodontol. 2003;74:296–306.
James JA, Irwin CR, Linden GJ. Gingival fibroblast response to cyclosporin A and transforming growth factor beta 1. J Periodont Res. 1998;33:40–48.
Morton RS, Dongari-Bagtzoglou AI. Regulation of gingival fibroblast interleukin-6 secretion by cyclosporine A. J Periodontol. 1999;70:1464–71.
de Andrade CR, Cotrin P, Graner E, Almeida OP, Sauk JJ, Coletta RD. Transforming growth factor-beta1 autocrine stimulation regulates fibroblast proliferation in hereditary gingival fibromatosis. J Periodontol. 2001;72:1726–33.
Wright HJ, Chapple IL, Matthews JB. THF-beta isoforms and TGF-beta receptors in drug-induced and hereditary gingival overgrowth. J Oral Pathol Med. 2001;30:281–89.
Kivirikko KI, Myllyharju J. Prolyl 4-hydroxylases and their protein disulfide isomerase subunit. Matrix Biol. 1998;16:357–68.
Kukkola L, Hieta R, Kivirikko KI, Myllyharju J. Identification and characterization of a third human, rat, and mouse collagen prolyl 4-hydroxylase isoenzyme. J Biol Chem. 2003;278:47685–93.
Han XY, Wang W, Myllyla R, Virtanen P, Karpakka J, Takala TE. mRNA levels for alpha-subunit of prolyl 4-hydroxylase and fibrillar collagens in immobilized rat skeletal muscle. J Appl Physiol. 1999;87:90–96.
Abergel RP, Pizzurro D, Meeker CA, Lask G, Matsuoka LY, Minor RR, et al. Biochemical composition of the connective tissue in keloids and analysis of collagen metabolism in keloid fibroblast cultures. J Invest Dermatol. 1985;84:384–90.
Pereira TN, Lewindon PJ, Smith JL, Murphy TL, Lincoln DJ, Shepherd RW, et al. Serum markers of hepatic fibrogenesis in cystic fibrosis liver disease. J Hepatol. 2004;41:576–83.
Huang JS, Ho KY, Chen CC, Wu YM, Wang CC, Ho YP, et al. Collagen synthesis in idiopathic and dilantin-induced gingival fibromatosis. Kaohsiung J Med Sci. 1997;13:141–48.
Meng LY, Huang MJ, Ye XQ, Fan MW, Bian Z. Increased expression of collagen prolyl 4-hydroxylases in Chinese patients with hereditary gingival fibromatosis. Arch Oral Biol. 2007;52:1209–14.
Coletta RD, Almeida OP, Reynolds MA, Sauk JJ. Alteration in expression of MMP-1 and MMP-2 but not TIMP-1 and TIMP-2 in hereditary gingival fibromatosis is mediated by TGF-beta 1 autocrine stimulation. J Periodontal Res. 1999;34:457–63.
Aimes RT, Quigley JP. Matrix metalloproteinase-2 is an interstitial collagenase. Inhibitor-free enzyme catalyzes the cleavage of collagen fibrils and soluble native type I collagen generating the specific 3/4- and 1/4-length fragments. J Biol Chem. 1995;270:5872–76.
Shin GT, Khanna A, Ding R, Sharma VK, Lagman M, Li B, et al. In vivo expression of transforming growth factor beta-1 in humans: stimulation by cyclosporine. Transplantation. 1998;65:313–18.
Thomason JM, Sloan P, Seymour RA. Immunolocalization of collagenase (MMP-1) and stromelysin (MMP-3) in the gingival tissues of organ transplant patients medicated with cyclosporin. J Clin Periodontol. 1998;25:554–60.
Hong HH, Trackman PC. Cytokine regulation of gingival fibroblast lysyl oxidase, collagen, and elastin. J Periodontol. 2002;73:145–52.
Hong HH, Uzel MI, Duan C, Sheff MC, Trackman PC. Regulation of lysyl oxidase, collagen, and connective tissue growth factor by TGF-beta1 and detection in human gingiva. Lab Invest. 1999;79:1655–67.
Perbal B. CCN proteins: multifunctional signalling regulators. Lancet. 2004;363:62–64.
Nakanishi T, Nishida T, Shimo T, Kobayashi K, Kubo T, Tamatani T, et al. Effects of CTGF/Hcs24, a product of a hypertrophic chondrocyte-specific gene, on the proliferation and differentiation of chondrocytes in culture. Endocrinology. 2000;141:264–73.
Nishida T, Nakanishi T, Asano M, Shimo T, Takigawa M. Effects of CTGF/Hcs24, a hypertrophic chondrocyte-specific gene product, on the proliferation and differentiation of osteoblastic cells in vitro. J Cell Physiol. 2000;184:197–206.
Igarashi A, Nashiro K, Kikuchi K, Sato S, Ihn H, Fujimoto M, et al. Connective tissue growth factor gene expression in tissue sections from localized scleroderma, keloid, and other fibrotic skin disorders. J Invest Dermatol. 1996;106:729–33.
Oemar BS, Luscher TF. Connective tissue growth factor. Friend or foe? Arterioscler Thromb Vasc Biol. 1997;17:1483–89.
Ito Y, Aten J, Bende RJ, Oemar BS, Rabelink TJ, Weening JJ, et al. Expression of connective tissue growth factor in human renal fibrosis. Kidney Int. 1998;53:853–61.
Kalluri R, Neilson EG. Epithelial-mesenchymal transition and its implications for fibrosis. J Clin Invest. 2003;112:1776–84.
Kantarci A, Black SA, Xydas CE, Murawel P, Uchida Y, Yucekal-Tuncer B, et al. Epithelial and connective tissue cell CTGF/CCN2 expression in gingival fibrosis. J Pathol. 2006;210:59–66.
Sume SS, Kantarci A, Lee A, Hasturk H, Trackman PC. Epithelial to mesenchymal transition in gingival overgrowth. Am J Pathol. 2010;177:208–18.
Jordan RC, Daniels TE, Greenspan JS, Regezi JA. Advanced diagnostic methods in oral and maxillofacial pathology. Part I: molecular methods. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2001;92:650–69.
Jordan RC, Daniels TE, Greenspan JS, Regezi JA. Advanced diagnostic methods in oral and maxillofacial pathology. Part II: immunohistochemical and immunofluorescent methods. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2002;93:56–74.
Jordan RC. Diagnosis of periodontal manifestations of systemic diseases. Periodontol 2000. 2004;34:217–29.
Pagana KD, Pagana TJ. Mosby’s Manual of Diagnostic and Laboratory Tests. 5th ed. St. Louis: Elsevier/Mosby; 2014.
Korol UB, Schoor R, Nanda V, Almas K, Phelan JA. Gingival enlargement as a manifestation of tuberous sclerosis: case report and periodontal management. J Periodontol. 2008;79:759–63.
Salehinejad J, Pazouki M, Gerayeli MA. Malignant inflammatory myofibroblastic tumor of the maxillary sinus. J Oral Maxillofac Pathol. 2013;17:306–10.
Bondon-Guitton E, Bagheri H, Montastruc JL. Drug-induced gingival overgrowth: a study in the French Pharmacovigilance Database. J Clin Periodontol. 2012;39:513–18.
Harikishan G, Reddy NR, Prasad H, Anitha S. Oral Crohn’s disease without intestinal manifestations. J Pharm Bioallied Sci. 2012;4 Suppl 2:S431–4.
Elyamany G, Al Mussaed E, Alzahrani AM. Plasmablastic lymphoma: a review of current knowledge and future directions. Adv Hematol. 2015;2015:315289.
Coletta RD, Graner E. Hereditary gingival fibromatosis: a systematic review. J Periodontol. 2006;77:753–64.
Mavrogiannis M, Ellis JS, Seymour RA, Thomason JM. The efficacy of three different surgical techniques in the management of drug-induced gingival overgrowth. J Clin Periodontol. 2006;33:677–82.
Martelli-Junior H, Bonan PR, Dos Santos LA, Santos SM, Cavalcanti MG, Coletta RD. Case reports of a new syndrome associating gingival fibromatosis and dental abnormalities in a consanguineous family. J Periodontol. 2008;79:1287–96.
Gontiya G, Bhatnagar S, Mohandas U, Galgali SR. Laser-assisted gingivectomy in pediatric patients: a novel alternative treatment. J Indian Soc Pedod Prev Dent. 2011;29:264–69.
Ilgenli T, Atilla G, Baylas H. Effectiveness of periodontal therapy in patients with drug-induced gingival overgrowth. Long-term results. J Periodontol. 1999;70:967–72.
Kantarci A, Cebeci I, Tuncer O, Carin M, Firatli E. Clinical effects of periodontal therapy on the severity of cyclosporin A-induced gingival hyperplasia. J Periodontol. 1999;70:587–93.
Argani H, Pourabbas R, Hassanzadeh D, Masri M, Rahravi H. Treatment of cyclosporine-induced gingival overgrowth with azithromycin-containing toothpaste. Exp Clin Transplant. 2006;4:420–24.
Bharti V, Bansal C. Drug-induced gingival overgrowth: the nemesis of gingiva unravelled. J Indian Soc Periodontol. 2013;17:182–87.
Zhou M, Xu L, Meng HX. Diagnosis and treatment of a hereditary gingival fibromatosis case. Chin J Dent Res. 2011;14:155–58.
Jadhav AS, Marathe SP. Recurrent idiopathic gingival fibromatosis with generalized aggressive periodontitis: A rare case report. J Indian Soc Periodontol. 2015;19:93–95.
Tripathi AK, Dete G, Saimbi CS, Kumar V. Management of hereditary gingival fibromatosis: a 2 years follow-up case report. J Indian Soc Periodontol. 2015;19:342–44.
Shashi V, Pallos D, Pettenati MJ, Cortelli JR, Fryns JP, von Kap-Herr C, et al. Genetic heterogeneity of gingival fibromatosis on chromosome 2p. J Med Genet. 1999;36:683–86.
Witkop Jr CJ. Heterogeneity in gingival fibromatosis. Birth Defects Orig Artic Ser. 1971;7:210–21.
Jorgenson RJ, Cocker ME. Variation in the inheritance and expression of gingival fibromatosis. J Periodontol. 1974;45:472–77.
Goldblatt J, Singer SL. Autosomal recessive gingival fibromatosis with distinctive facies. Clin Genet. 1992;42:306–8.
Kanagotagi S, Sidana S, Rajquru S, Padhye A. Gingival fibromatosis with distinctive facies - a three generation case report. J Clin Diagn Res. 2015;9:ZD05–07.
Jones G, Wilroy Jr RS, McHaney V. Familial gingival fibromatosis associated with progressive deafness in five generations of a family. Birth Defects Orig Art Ser. 1977;13:195–201.
Hartsfield Jr JK, Bixler D, Hazen RH. Gingival fibromatosis with sensorineural hearing loss: an autosomal dominant trait. Am J Med Genet. 1985;22:623–27.
Fantauzzo KA, Kurban M, Levy B, Christiano AM. Trps1 and its target gene Sox9 regulate epithelial proliferation in the developing hair follicle and are associated with hypertrichosis. PLoS Genet. 2012;8:e1003002.
DeStefano GM, Kurban M, Anyane-Yeboa K, Dall’Armi C, Di Paolo G, Feenstra H, et al. Mutations in the cholesterol transporter gene ABCA5 are associated with excessive hair overgrowth. PLoS Genet. 2014;10:e1004333.
Anderson J, Cunliffe WJ, Roberts DF, Close H. Hereditary gingival fibromatosis. Brit Med J. 1969;3:218–19.
Horning GM, Fisher JG, Barker BF, Killoy WJ, Lowe JW. Gingival fibromatosis with hypertrichosis: a case report. J Periodontol. 1985;56:344–47.
Bondeson J, Miles AEW. Julia Pastrana, the nondescript: an example of congenital, generalized hypertrichosis terminalis with gingival hyperplasia. Am J Med Genet. 1993;47:198–212.
Canun S, Guevara-Sangines EG, Elvira-Morales A, Sierra-Romero Mdel C, Rodriguez-Asbun H. Hypertrichosis terminalis, gingival hyperplasia, and a characteristic face: a new distinct entity. Am J Med Genet. 2003;116A:278–83.
Ramon Y, Berman W, Bubis JJ. Gingival fibromatosis combined with cherubism. Oral Surg. 1967;24:436–48.
de Pina-Neto JM, Moreno AFC, Silva LR, Velludo MASL, Patean EBL, Ribeiro M, et al. Cherubism, gingival fibromatosis, epilepsy, and mental deficiency (Ramon syndrome) with juvenile rheumatoid arthritis. Am J Med Genet. 1986;25:433–41.
Suhanya J, Aggarwal C, Mohideen K, Jayachandran S, Ponniah I. Cherubism combined with epilepsy, mental retardation and gingival fibromatosis (Ramon syndrome): a case report. Head Neck Pathol. 2010;4:126–31.
Stefanova M, Atanassov D, Krastev T, Fuchs S, Kutsche K. Zimmermann-Laband syndrome associated with a balanced reciprocal translocation t(3;8) (p21.2;q24.3) in mother and daughter: molecular cytogenetic characterization of the breakpoint regions. Am J Med Genet. 2003;117A:289–94.
Kim HG, Higgins AW, Herrick SR, Kishikawa S, Nicholson L, Kutsche K, et al. Candidate loci for Zimmermann-Laband syndrome at 3p14.3. Am J Med Genet. 2007;143A:107–11.
Castori M, Valiante M, Pascolini G, Leuzzi V, Pizzuti A, Grammatico P. Clinical and genetic study of two patients with Zimmermann-Laband syndrome and literature review. Eur J Med Genet. 2013;56:570–76.
Kortum F, Caputo V, Bauer CK, Stella L, Ciolfi A, Alawi M, et al. Mutations in KCNH1 and ATP6V1B2 cause Zimmermann-Laband syndrome. Nature Genet. 2015;47:661–67.
Laband PF, Habib G, Humphreys GS. Hereditary gingival fibromatosis: report of an affected family with associated splenomegaly and skeletal and soft-tissue abnormalities. Oral Surg. 1964;17:339–51.
Chacon-Camacho OF, Vazquez J, Zenteno JC. Expanding the phenotype of gingival fibromatosis-mental retardation-hypertrichosis (Zimmermann-Laband) syndrome. Am J Med Genet. 2011;155A:1716–20.
Keser G, Karabulut B, Oksel F, Calli C, Utsun E, Akalin T, et al. Two siblings with juvenile hyaline fibromatosis: case reports and review of the literature. Clin Rheum. 1999;18:248–52.
Rahman N, Dunstan M, Teare MD, Hanks S, Edkins SJ, Hughes J, et al. The gene for juvenile hyaline fibromatosis maps to chromosome 4q21. Am J Hum Genet. 2002;71:975–80.
El-Kamah GY, Fong K, El-Ruby M, Afifi HH, Clements SE, Lai-Cheong JE, et al. Spectrum of mutations in the ANTXR2 (CMG2) gene in infantile systemic hyalinosis and juvenile hyaline fibromatosis. Brit J Derm. 2010;163:208–34.
Denadai R, Raposo-Amaral CE, Bertola D, Kim C, Alonso N, Hart T, et al. Identification of 2 novel ANTXR2 mutations in patients with hyaline fibromatosis syndrome and proposal of a modified grading system. Am J Med Genet. 2012;158A:732–42.
Puretic S, Puretic B, Fiser-Herman M, Adamcic M. A unique form of mesenchymal dysplasia. Brit J Derm. 1962;74:8–19.
Gorlin RJ, Cohen MM, Levin LS. Syndromes of the head and neck. 3rd ed. New York: Oxford Press; 1990 (Oxford Monographs on Medical Genetics).
Nofal A, Sanad M, Assaf M, Nofal E, Nassar A, Almokadem S, et al. Juvenile hyaline fibromatosis and infantile systemic hyalinosis: a unifying term and a proposed grading system. J Am Acad Dermatol. 2009;61:695–700.
Rutherfurd ME. Three generations of inherited dental defect. Brit Med J. 1931;2:9–11.
Houston IB, Shotts N. Rutherfurd’s syndrome: a familial oculo-dental disorder. Acta Paediat Scand. 1966;55:233–38.
Higgs JE, Clayton-Smith J. Rutherfurd syndrome revisited: intellectual disability is not a feature. Clin Dysmorph. 2015;24:125–27.
O’Sullivan J, Bitu CC, Daly SB, Urquhart JE, Barron MJ, Bhaskar SS, et al. Whole-exome sequencing identifies FAM20A mutations as a cause of amelogenesis imperfecta and gingival hyperplasia syndrome. Am J Hum Genet. 2011;88:616–20.
Jaureguiberry G, De la Dure-Molla M, Parry D, Quentric M, Himmerkus N, Koike T, et al. Nephrocalcinosis (enamel renal syndrome) caused by autosomal recessive FAM20A mutations. Nephron Physiol. 2012;122:1–6.
Cho SH, Seymen F, Lee KE, Lee SK, Kweon YS, Kim KJ, et al. Novel FAM20A mutations in hypoplastic amelogenesis imperfecta. Hum Mutat. 2012;33:91–94.
De la Dure-Molla M, Quentric M, Yamaguti PM, Acevedo AC, Mighell AJ, Vikkula M, et al. Pathognomonic oral profile of Enamel Renal Syndrome (ERS) caused by recessive FAM20A mutations. Orphanet J Rare Dis. 2014;9:1–13.
Elizabeth J, Lakshmi Priya E, Umadevi KM, Ranganathan K. Amelogenesis imperfecta with renal disease-a report of two cases. J Oral Pathol Med. 2007;36:625–28.
Hall RK, Phakey P, Palamara J, McCredie DA. Amelogenesis imperfecta and nephrocalcinosis syndrome. Case studies of clinical features and ultrastructure of tooth enamel in two siblings. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 1995;79:583–92.
Kala Vani SV, Varsha M, Sankar YU. Enamel renal syndrome: a rare case report. J Indian Soc Pedod Prev Dent. 2012;30:169–72.
Phakey P, Palamara J, Hall RK, McCredie DA. Ultrastructural study of tooth enamel with amelogenesis imperfecta in AI-nephrocalcinosis syndrome. Connect Tissue Res. 1995;32:253–59.
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KG performed literature search, prepared figures, wrote and prepared the manuscript. KŁB performed literature search. JP prepared the manuscript. MCG performed literature search and wrote the manuscript. All authors read and approved the final version of the manuscript.
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Gawron, K., Łazarz-Bartyzel, K., Potempa, J. et al. Gingival fibromatosis: clinical, molecular and therapeutic issues. Orphanet J Rare Dis 11, 9 (2016). https://doi.org/10.1186/s13023-016-0395-1
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DOI: https://doi.org/10.1186/s13023-016-0395-1