| Review Article |
Open Access |
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| Lymphvasculogenesis and Lymphangioma – an Update |
| V Naveen Shankar, Ashwini. N Shankar and Praveena V |
| Kothiwal Dental College Research Centre and Hospital, Kanth Road, Moradabad, Uttar Pradesh, India |
| *Corresponding author: |
Dr. V Naveen Shankar
No#110, 5th Ward, National College
Road
Bagepalli, Chikkaballapura, Karnataka, India
Tel: + 00919286731312
E-mail: vnaveenshankar@gmail.com |
|
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| Received April 27, 2011; Accepted July 20, 2011; Published July 24, 2011 |
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| Citation: Shankar VN (2011) Lymphvasculogenesis and Lymphangioma - an
Update. J Cancer Sci Ther 3: 149-153. doi:10.4172/1948-5956.1000078 |
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| Copyright: © 2011 Shankar VN. This is an open-access article distributed under
the terms of the Creative Commons Attribution License, which permits unrestricted
use, distribution, and reproduction in any medium, provided the original author and
source are credited. |
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| Abstract |
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| Lymphangiomas are rare congenital benign lesions occurring mainly in the head, neck and oral cavity.
They consist in localized centres of abnormal development of the lymphatics. A commonly used classification
classifies these lesions into capillary lymphangioma or lymphangioma simplex, cavernous lymphangioma, and
cystic lymphangioma or cystic hygroma. Histologically, these lesions are composed of dilated lymphatic channels,
endothelially lined channels with or without an adventitial layer. These dilated lymphatic’s can vary in size, depending
upon the location and surrounding tissues. |
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| Surgical resection still remains the best treatment for lymphangiomas; other treatment options, such as
sclerotherapy have been proposed as an alternative to reduce the impact and complications of surgery. |
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| Keywords |
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| Lymphangiomas; Lymphatic endothelial cell;VEGFR |
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| Introduction |
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| Lymphangiomas are benign hemartomatous hyperplasia of
lymphatic vessels. Lymphangiomatous lesions are a rare congenital
malformation which usually appears within the first 2 decade of life
[1]. they are typically superficial but may extend deeply into underlying
connective tissue, rarely multiple lesions are also seen in infancy and
childhood [2]. Prevalence of lymphatic malformations can be 30
per 10,000 births, but if only live births are included 1–3 Lymphatic
Malformations per 10,000 live births are reported [3]. There has
been various research studies on lymphvasculogenesis, etiology of
lymphangioma and its treatment. Here is an attempt to update the
knowledge on all such research works. |
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| Lymphatic vessel development |
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| The first description of the lymphatic system dates back to the
seventeenth century, when the Italian anatomist Gasparo Aselli
identified lymphatic vessels as ‘‘milky veins’’ in the mesentery of a
‘‘well-fed’’ dog [4]. |
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| However, the lymphvasculogenesis remained unclear until
Florence Sabin in 1902 proposed a model based upon ink-injection
experiments in pigs – that endothelial cells bud off from the veins
during early embryonic development and form primitive lymph sacs.
The peripheral lymphatic system then originates from these primary
lymph sacs by endothelial sprouting into the surrounding tissues and
organs, where local capillaries are formed [5]. |
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| This was challenged in 1910 by Huntington and McClure who
alternatively suggested that lymph sacs arise independently of the
veins – from mesenchymal precursor cells (lymphangioblasts), with
consecutive establishment of venous connections [6]. |
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| The lymphatic vasculature runs in parallel, but develops secondarily
to the blood vasculature, and both are lined by endothelial cells (ECs).
The lymphatic vasculature is derived from venous ECs. Therefore, a
prerequisite for the genesis of the lymphatic network is the formation of
the blood vasculature. The development of the embryonic vasculature
requires the differentiation of endothelial cells (ECs). First step in this
process is the formation of endothelial precursors (angioblasts) from
mesodermal progenitors during gastrulation. The ETS transcription
factor Etv2 that leads to EC differentiation, and the Notch, BMP and Wnt signaling pathways regulate its expression. VEGF signaling is
also important during the differentiation of angioblasts into ECs.
Subsequently, Notch signaling is required to promote arterial endothelial
cell identity, and the expression of the orphan nuclear receptor COUP
transcription factor II (COUP-TFII) promotes venous endothelial
cell fate by downregulating Notch signaling. Upon its activation in a
subpopulation of the venous endothelial cells, the SRY-related HMGdomain
transcription factor Sox18 cooperates with COUP-TFII to
activate expression of the homeobox transcription factor Prox1. Prox1
expression is sufficient to specify lymphatic endothelial cell (LEC) fate.
Later on, Prox1 expression becomes independent of external stimuli, as
it regulates its own expression and maintains LEC identity [7]. |
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| Guillermo Oliver et al proposed that the lymphvasculogenesis
takes place in four stages comprising of competence, commitment,
specification, and lymphatic vessel coalescence and maturation [8].
(Table 1) |
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|
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| Lymphatic competence |
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| Competence is the capacity of cells to respond to an initial
inducing signal; this stage seems to be autonomous and controlled
by a developmental timer. Around 9-9.5day of murine embryonic life
all endothelial cells of the embryonic cardinal vein display the ability
to respond to unidentified initiating and instructive growth factor(s)
of lymphatic development [7,8]. At present, Lymphatic endothelial
cell (LEC) competence is defined by the surrogate expression of
lymphatic vessel endothelial hyaluronan receptor-1 (LYVE-1) and
vascular endothelial growth factor receptor-3 (VEGFR-3). LYVE-
1 is expressed on blood endothelial cells (BECs) early in the phase
of lymphatic competence. VEGFR-3 is broadly expressed on both
early blood and lymphatic vessel endothelium and plays a critical role in the development of both lineages of vasculature. With time,
VEGFR-3 expression becomes limited to LECs as BEC expression is
downregulated. With the attainment of vascular maturity, VEGFR-3 is
largely restricted to the lymphatic endothelium [8,9]. |
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| Tammela and Alitalo said that transcription factor SOX18 is
induced in the LYVE-1-positive lymphatic endothelial cell (LEC)
precursors. SOX18 induces Prox1 expression, the first marker for
LEC determination. At about this time, VEGFR-3 expression is
downregulated in the blood vessels, but it remains high in the LEC
precursors, which also begin to express neuropilin-2, rendering
them more responsive to VEGF-C signals arising from the lateral
mesenchyme. These signals are required for sprouting of the LECs [10]. |
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| In conjunction with primary VEGFR-3 ligands, VEGF-C and
VEGF-D, angiopoietin-2 (Ang2) is believed to be responsible for
lymphatic remodeling following differentiation, through interaction
with the Tie2 receptor, to form functionally mature lymphatics [9]. |
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| Lymphatic commitment |
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| Following the initial stage LECs acquire the ability to give rise to a
particular cell type or structure. This stage is marked by the expression
of prospero-related homeobox 1 (Prox1), a nuclear transcription factor
whose appearance is exclusive to cells of committed lymphatic lineage.
The Prox1-positive subpopulation of venous endothelial cells oriented
in a polarized fashion along the cardinal vein. The mechanism of this
differential and ordered expression remains unknown; nevertheless
Prox1 is clearly necessary and sufficient for lymphatic commitment
[7,8]. |
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| Francois et al. demonstrated that the homeobox transcription factor
SOX18 is expressed in cardinal vein endothelial cells prior to Prox1,
and that the Prox1 promoter contains SOX18-binding sites, indicating
that SOX18 is required for initiation of the LEC differentiation program
upstream of Prox [10]. |
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| Lymphatic specification and coalescence |
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| Specification is the stage at which cells will differentiate into the
desired phenotype, even if isolated and cultured alone. |
|
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| As the LECs attains a higher level of differentiation, additional
lymphatic specific markers are expressed, while those reflecting
the assumed blood vascular linage are increasingly suppressed.
Committed LEC eventually achieves complete autonomy from the
local microenvironment of the cardinal vein and migrates peripherally. |
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| Under the further influence of Prox1, neuropilin 2 (Nrp2) and
podoplanin/T1, LECs bud from the parental cardinal vein. This
budding and migration seed the periphery for the formation of nascent
lymphatic structures throughout the embryo. These are called primary
lymph sacs [7,8]. |
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| Maturation |
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| The primary lymph sac form capillaries around tissues and organs
in a centrifugal fashion to constitute the lymphatic vasculature. The cell continues to organize until the first few postnatal days. In the late
stage of differentiation and maturation lymphatic markers such as
desmoplakin and β-chemokine receptor D6 appear. These are thought
to be among the last markers expressed [8,9]. |
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| Association of lymphatic vessels with the extracellular matrix |
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| The elastic microfibril-associated protein Emilin1 is a component
of the anchoring filaments in lymphatic vessels [10]. |
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| History and lymphangiogenesis |
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| The first description of lymphangioma in the literature is credited
to Redenbacher who, in 1828, referred to a lesion as a ‘ranula congenita’
. In 1843 Wernher coined the descriptive term ‘cystic hygroma’,
hygroma being derived from the Greek ‘hydro’ = moist and ‘oma’ =
tumor. He thought the fluid-filled sacs represented new growth of
benign neoplastic tissue. In 1855 Rokitansky postulated that a cystic
hygroma was simply a collection of serous fluid held in place by
surrounding tissue [11]. |
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| Florence Sabin, proposed centrifugal theory of lymphatic
development, said that the human lymphatic system which originates
from 5 primordial sacs: two paired jugular sacs; two paired sacral
sacs; and an unpaired retroperitoneal sac. From these primitive sacs,
endothelial sprouts propagate outward to form the peripheral lymphatic
system. In support of this study Goetsch identified endothelial buds
sprouting from the growing edge of the tumour and infiltrating
surrounding tissue from histologic preparations of cystic hygroma. He
felt this represented true neoplastic growth of the lymphatic system
[11]. |
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| Several investigators have challenged this work, proposing instead
a centripetal theory in which peripheral lymphatics develop from
mesenchymal slits in sequestered portions of the primordial sacs.
These sequestrations enlarge and ultimately join the venous system.
Failure of this anastomosis results in formation of a cystic hygroma.
This hypothesis, however, accounts for neither the- histologic findings
nor the potential for rapid and extensive growth [11]. |
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| Now it has been widely accepted that lymphangiomas develop
as a result of sequestration of portions of the primitive embryonic
lymphatic anlage. These sequestered areas never achieve efficient
anastomoses with the larger lymph channels; therefore functionally
they exist as localized areas of lymphatic blockage, some appearing as
lymphangiomas, others as cystic hygromas [12]. |
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| Recently Norgall et al. suggested that Immunohistological
Characterization of lymphatic endothelial cells suggests an involvement
of VEGFR- 3 and -2 in the etiology of the lymphangioma. Upregulation
of VEGFR-3 and -2 signalling are the major cause for the
aberrant lymph vessel formation [13]. |
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| Classification |
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| Lyphamgiomas are classified as microcystic (capillary lymphangiomas),
macrocystic (cavernous lymphangiomas), and cystic hygromas according
to the size of the lymphatic cavities incorporated [14]. |
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| According to Kennedy et al Lymphangioma are classified based on
their extent as [15]: |
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| I. Superficial cutaneous lymphangioma |
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| Lymphangioma simplex |
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| Lymphangioma circumscriptum |
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| II. Cavernous lymphangioma |
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| Loose: |
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| Mucous membrane of lips, cheek, and floor of mouth Compact: |
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| Tongue, abdomen, or flank |
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| III. Cystic hygroma—cystic lymphangioma |
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| IV. Diffuse systemic lymphangioma |
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| Lymphangioma—hemangioma. |
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| De Serres et al. [16] proposed clinical staging system for
lymphangiomas involving neck based on extent and location, the
system classifies the disease as follows: |
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| stage I, unilateral infrahyoid disease; |
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| stage II, unilateral suprahyoid disease; |
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| stage III, unilateral infrahyoid and suprahyoid disease; |
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| stage IV, bilateral suprahyoid disease; and |
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| stage V, bilateral infrahyoid and suprahyoid disease [16]. |
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| Clinical features |
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| Lymphangiomas show neither racial nor sexual predilection and
are most often diagnosed in the pediatric population. Discovery in
adolescence or adulthood is reported but is distinctly uncommon
[1,11]. |
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| Approximately 75% of all cases of lymphangioma occur in the head
and neck region, and about 50% of all lesions are noted at birth. About
90% develop by 2 years of age [2,11]. Lymphangioma involving the
head and neck occurred most commonly in the submandibular and
floor of mouth regions. In the oral cavity tongue involvement is the
most common site followed by buccal mucosa. Lips and Palate [1,3].
Instances of cheek, orbit, and eyelid involvement are also reported
[2,11,16]. |
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| Associated anomalies include Turner’s syndrome, congenital heart
disease, cleft lip, spina bifida, and mental retardation [9]. |
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| When a lymphangioma is confined to fairly dense tissue, such
as the tongue, it presents as a cavernous lymphangioma, but when it
develops in the relatively loose fascia of the neck, a cystic lesion occurs
[17].The most prominent sign or symptom of all lymphangiomas is
the presence of a mass. the mass may be small and unnoticed at birth
only to present later [18]. These lesions commonly present with a
slowly growing, asymptomatic, fluctuant, soft-tissue mass. The lesions
are not attached to the skin or movable across deeper tissues, and
readily transilluminate [14]. Frequently, rapid enlargement occurs
following an upper respiratory tract disorder or incidental trauma at
the site [11]. Most lesions, however, are recognized early on account
of their size and associated symptoms of respiratory obstruction
and problems with feeding, which are the second and third most
common presenting symptoms. Difficulty in swallowing results from
lymphangiomas extending to involve the oral cavity, oropharynx, and/
or the hypopharynx [1,12,16]. |
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| Isolated tongue involvement can lead to macroglossia with
dysphagia and airway obstruction. Airway and swallowing problems
may persist after surgery in the neck on account of mucosal oedema,
enlargement of internal lymphangiomas, and loss of neural innervation
to the pharynx or tongue [18]. |
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| The clinical course of the pathology varies from a spontaneously
regressing cyst to an aggressively invasive lesion. Spontaneous or
traumatic haemorrhage of the cysts is the most common complication
of the lesion [19]. Ultrasonography, CT and MRI can be used to define
the relationship of the lesion with the neighbouring structures and to
help plan surgical strategies [20]. |
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| Treatment options |
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| The principal goal of Lymphatic malformations management
is restoration or preservation of functional and aesthetic integrity.
All treatment is based on a thorough initial assessment to detect the
degree of functional impairment and/or disfigurement. Treatment
timing relative to the age of the patient is somewhat debatable.
Lymphangiomas of small dimensions, without functional impairment
or cosmetic disfigurement, do not necessarily require treatment. The
possibility of spontaneous regression in low-stage macrocystic lesions
suggests that observational monitoring may also be appropriate in
children with asymptomatic cervical Lymphangiomas, regardless of
size [20,21]. |
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| Various modalities have been reported for the treatment of
lymphangiomas. Procedures such as surgical excision, sclerotherapy,
radiation therapy, cryotherapy, electrocautery, steroid administration,
embolization, ligation, and laser surgery have all been used [12,20-22]. |
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| Surgery has been the main form of treatment, but total removal
is not possible in all cases because of the extent of the lesion, which
sometimes involves vital structures [23]. Complications include
postsurgical fluid accumulation, infection, Horner’s syndrome and
peripheral nerve injury including damage to the facial nerve branches,
the hypoglossal nerve, or the lingual nerve has been reported [24]. Saijo
et al. reported that when facial lymphangiomas are diffuse and locally
invasive, there is a 50% recurrence rate after the first excision, most
likely due to residual anomalous tissue [25]. |
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| Furthermore, the infiltrating nature of these lesions and the
involvement of vital structures make total excision nearly impossible
in most cases. In such cases sclerotherapy has been recommended
as a primary or adjunctive treatment for these lesions. Intralesional
injection of Sclerosing agents such as tetracycline or doxycycline,
sodium diatrizoate tetrahydrate (Ethibloc; Ethnor Laboratories/
Ethicon, Noderstedt, Germany), ethanol, sodium tetradecyl sulfate,
triamcinolone, sodium morrhuate, 50% dextrose, bleomycin sulfate,
bleomycin emulsion, pingyangmycin, and OK-432 are used [21,25].
Prior to any sclerosant injection, the aspirated fluid should be examined
to confirm the diagnosis. The fluid should be thin and tan in color. |
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| OK-432 is a lyophilized mixture of group A Streptococcus pyogenes
and benzylpenicillin. After injection, OK-432 remains confined within
the malformation, resulting in obliteration of lymphatic channels
with minimal local fibrosis. It is thought that endothelial damage
occurs secondary to activation of the host immune system. The main
disadvantage of OK-432 therapy is a theoretical risk of shock-like
symptoms, particularly in those with penicillin allergy. Additional
drawbacks include local edema and the need for multiple applications
[21,25,26]. |
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| Bleomycin was initially developed as an anti-tumor agent in 1966.
In addition to its activity as an inhibitor of DNA synthesis, bleomycin
incites a mild inflammatory effect on endothelial cells. Bleomycin may
be administered in one of two forms, as bleomycin oil or bleomycin
hydrochloride (aqueous). Common immediate side effects of
bleomycin sclerotherapy are slight local swelling and inflammation.
However, the major concern with bleomycin use is the potential risk of
interstitial pneumonia and pulmonary fibrosis [21,22,1]. |
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| Doxycycline, a broad-spectrum antibiotic, is also a
metalloproteinase inhibitor. Based on this finding, it has been used
as a vascular malformation sclerosant alone or in combination with
ethanol. It is a safe and effective sclerosant for macrocystic LM. This
agent creates an inflammatory effect and produces fibrosis similar
to other agents. Potential complications include tooth discoloration
when administered to patients less than eight years of age, electrolyte
abnormalities, local infection, and pain [21]. |
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| All of these sclerosants can still cause severe swelling with airway
compromise, skin breakdown, and other toxic side-effects. Also, it
must be emphasized that treatment outcomes are based on multiple
treatments, sometimes in excess of five to 10 treatments, and longterm
follow-up is necessary [27]. |
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| Laser treatments can be useful to treat airway malformations as
well as to treat the vesicular eruptions on the mucosal surfaces. Airway
lesions may require redundant tissue excision as is often seen in the
false vocal cord and supraglottis in order to prevent or decannulate a
tracheostomy. The CO2 laser can be used to accomplish these limited
resections as well as to laser resurface oral mucosal vesicles, which can
lead to pain and dysphagia [27]. |
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| Kennedy et al. [20] proposed a treatment plan according to him:
Initial counseling to the parents and the child (if of sufficient age) is
essential. The first sessions should include a thorough discussion of the
malformation and all possible treatment options. If symptoms are life
threatening, then surgical intervention is warranted. When a mass is
the only sign or symptom, observation is recommended for at least 18
months to 2 years of age. By age 5 no sign of regression or apparent
reduction in size in relationship to the growth of the child is seen. A
surgical approach or the use of a sclerosing agent, such as OK-432, is
two such options. If the lesion is below the level of the hyoid and mostly
in the posterior triangle, surgery is the preferred. However OK-432 is
a better choice for those enlarging hygromas above the hyoid that are
beginning to invade the oral and pharyngeal mucosa. Smaller lesions in
the submaxillary and parotid regions certainly can be managed safely
with surgery [15]. |
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| For those patients who develop lymphangiomas later in life,
Depending on the cosmetic concerns of the patient and the location
of the lesion, we would favor waiting 6 months to 1 year before
recommending surgery in these older patients [15]. |
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| Oosthuizen, Burns, and Russell in 2010 have proposed management
algorithm (Figure 1 and Figure 2) [26]. |
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|
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|
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| Histopathology |
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| Gross examination of excised lymphatic malformation tissue
reveals cysts of various sizes, some interconnected and few isolated.
The cysts contain serous fluid that may be clear, yellow, turbid or
hemorrhagic. Older cysts are separated by thick walls, filled with hyaline
and fibrous material whereas younger cysts are simply endothelial
layers separated by minimal connective tissue. The intercystic stroma
and capsule is made up of thin layers of smooth muscle in a connective
tissue matrix of varying thickness containing iron pigment and nodules
of lymphatics [12,24,28]. |
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| Lymphangiomas are unencapsulated lesions consisting of dilated,
endothelially lined channels that may contain lymphocytes. The stroma
consists of delicate collagen within which lymphoid aggregates are
sometimes encountered . Some lymphangiomas also have a vascular
component and may therefore contain some red blood cells. Cystic
hygromas differ only in that they are usually composed of very large,
interconnecting, endothelially lined, cyst‐like spaces [29]. |
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| Electron microscopic study of the basal lamina appears as
an electron-dense line which is composed of type IV collagen.”
Immunostaining for type IV collagen and electron microscopic
examination showed that the basement membrane of the lymph vessels
was not continuous. These discontinuities may partially explain why
sclerosing agents have not been effective in treating lymphangioma.
Perhaps the discontinuous basement membrane allows sclerosing
agents to permeate freely into the connective tissues, diluting the
concentration of the agent and rendering it less effective [12]. |
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| Conclusion |
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| Here is an attempt towards concised overview of lymphangioma covering the development of lymph vessels, lymphangioma and its
treatment. This would help the clinician to best understand the disease
process and its staging. Furthermore it helps in indulge/explore the
different types of treatment options which are available. |
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| Acknowledgements |
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| Mr C.Vemanna, Mrs.V Seethamma, Mrs V.Roja Rani, Mrs V.Dhanurenuka,
Mrs V.Chandrakala. |
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|
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