Management of Benign Neck Swellings involving Different Compartments – Case Series

Background:Lymphatic malformations (LMs) often pose treatment challenges due to a large size or a critical location that could lead to disfigurement, and there are no standardized treatment approaches for either refractory or unresectable cases.Methods:We examined the genomic landscape of a patient cohort of LMs (n = 30 cases) that underwent comprehensive genomic profiling using a large-panel next-generation sequencing assay. Immunohistochemical analyses were completed in parallel.Results:These LMs had low mutational burden with hotspot PIK3CA mutations (n = 20) and NRAS (n = 5) mutations being most frequent, and mutually exclusive. All LM cases with Kaposi sarcoma-like (kaposiform) histology had NRAS mutations. One index patient presented with subacute abdominal pain and was diagnosed with a large retroperitoneal LM harboring a somatic PIK3CA gain-of-function mutation (H1047R). The patient achieved a rapid and durable radiologic complete response, as defined in RECIST1.1, to the PI3Kα inhibitor alpelisib within the context of a personalized N-of-1 clinical trial (NCT03941782). In translational correlative studies, canonical PI3Kα pathway activation was confirmed by immunohistochemistry and human LM-derived lymphatic endothelial cells carrying an allele with an activating mutation at the same locus were sensitive to alpelisib treatment in vitro, which was demonstrated by a concentration-dependent drop in measurable impedance, an assessment of cell status.Conclusions:Our findings establish that LM patients with conventional or kaposiform histology have distinct, yet targetable, driver mutations.Funding:R.P. and W.A. are supported by awards from the Levy-Longenbaugh Fund. S.G. is supported by awards from the Hugs for Brady Foundation. This work has been funded in part by the NCI Cancer Center Support Grants (CCSG; P30) to the University of Arizona Cancer Center (CA023074), the University of New Mexico Comprehensive Cancer Center (CA118100), and the Rutgers Cancer Institute of New Jersey (CA072720). B.K.M. was supported by National Science Foundation via Graduate Research Fellowship DGE-1143953.Clinical trial number:NCT03941782

Pediatric Neck Masses

Case Scenario: Anesthesia for Maternal-Fetal Surgery

Index of Suspicion.

BackgroundCervical cystic hygroma is a benign congenital malformation of the lymphatic system. Incidence of cystic hygroma is 1/6000 live births. We present a case of right neck mass with potential respiratory compromise in a newborn.Case presentationThe patient was a full term baby girl with an incidental finding of right neck mass which was described on ultrasound and magnetic resonance imaging as a cystic lesion in the nasopharynx and right neck which inferiorly followed the course of the right carotid artery, consistent with cystic hygroma. She started with respiratory compromise, and a follow-up magnetic resonance imaging showed increased size of the cystic hygroma. Dexamethasone was started to reduce fluid build up in the mass. When the cystic hygroma was found to be inseparable from the right half of the thyroid gland, the otolaryngologist performed hemithyroidectomy.ConclusionThe patient had neuropraxia involving the marginal mandibular branch of the facial nerve, which was expected to correct with time. Large cervical cystic hygromas may surround or displace neurovascular structures making their identification quite challenging intraoperatively. A team of experienced surgeons will help to ensure a successful surgical outcome.

A term, large-for-gestational age boy is transferred from an outside hospital with a right anterior chest wall mass noted since birth. His mother is a healthy 33-year-old gravida 4, para 4 woman with good prenatal care and normal prenatal laboratory values who had an uncomplicated pregnancy and elective cesarean delivery. None of the patient’s siblings or family members have had similar masses.On physical examination the patient is well-appearing and moving all 4 extremities spontaneously without obvious limitations. Vital signs on admission to the hospital are normal. There is a nontender, boggy, fluctuant, flesh-colored, grapelike mass from his right nipple to the midaxillary line that extends to the right upper arm, with dimpling of the skin throughout the right upper extremity (Fig 1). No bruit is heard over the lesion. There is no palpable bony abnormality. Radial pulses are 2+. Capillary refill is less than 2 seconds. His lungs are clear to auscultation. The cardiovascular examination reveals a normal heart rate, rhythm, S1, and S2 and no murmurs. The abdomen is soft, nontender, and nondistended, with no palpable masses or hepatosplenomegaly.Chest radiography is normal. Complete blood cell count with differential count is normal. Ultrasonography of the right superolateral chest shows a multiloculated fluid collection with undulating borders measuring 6 × 1.7 cm. Magnetic resonance imaging (MRI) with contrast of the chest and right upper extremity reveals a multiloculated macrocystic mass in the superficial right chest wall, additional cysts in the right arm, and a partially cystic right mediastinal mass (Figs 2 and 3). MRI also shows multiple cysts in both kidneys (Fig 4). Review of the findings from MRI and genetic testing reveal the diagnoses.The differential diagnosis includes lymphatic malformation, venous malformation, vascular tumor, arteriovenous malformation, arteriovenous fistula, and capillary malformation. The patient was diagnosed as having lymphatic malformation. In addition, rapid genome sequencing revealed de novo pathogenic variant of PKD1 mutation, supporting an incidental second diagnosis of autosomal dominant polycystic kidney disease (ADPKD).Lymphatic malformations are a type of vascular anomaly. The International Society for the Study of Vascular Anomalies stratifies vascular anomalies into vascular tumors (benign, locally aggressive or borderline, and malignant) and vascular malformations (simple, combined, anomalies of major named vessels, and vascular malformations associated with other anomalies). (1)(2) Lymphatic malformations are low-flow, nonmalignant vascular malformations of the lymphatic system with dilated lymphatic channels or cysts thought to occur during lymphatic development.Lymphatic malformations can affect 1 location or can be loculated and/or multifocal (eg, lymphangiomatosis). (3) Lymphatic malformation is an umbrella term that includes all subtypes of lymphatic malformations, including cystic lymphatic malformations (macrocystic, microcystic, or mixed), generalized lymphatic anomalies such as kaposiform lymphangiomatosis, channel-type lymphatic malformation, acquired progressive lymphatic anomaly (acquired progressive lymphangioma), and primary lymphedema. Lymphatic malformations can affect any area of the body but most commonly occur in the head and neck regions, followed by the extremities. (4) They are classified as macrocystic, microcystic, or mixed. Most are noted at birth or within the first 2 years after birth.Superficial lymphatic malformations or deep vascular lesions may have no skin discoloration. In contrast, superficial arterial, capillary, or venous vascular anomalies can appear red, pink, violaceous, or blue, depending on the mix of oxygenated (arterial) or deoxygenated (venous) blood. Superficial lymphatic malformations can have clear vesicles or pitting of the skin or appear bruised if bleeding occurs within the malformation. Venous malformations are often bluish, soft, and compressible papules. Capillary malformations are often pink, red, or purple flat macules or patches. High-flow malformations, such as arteriovenous malformations and arteriovenous fistulas, can have a palpable bruit or thrill. Vascular anomalies can cause overgrowth and swelling in the affected area, which could cause pain.Lymphatic malformations can be associated with other anomalies. Gorham-Stout syndrome, also known as vanishing bone disease, is a rare condition characterized by proliferation of lymphatic vessels adjacent to single or multiple bones, leading to osteolysis and resorption of bone, oftentimes the ribs, spine, pelvis, skull, clavicle, or jaw. (5) Several PIK3CA-related overgrowth spectrum conditions also have lymphatic malformations, such as Klippel-Trenaunay syndrome, a rare congenital syndrome characterized by cutaneous capillary malformations (port-wine stain), vascular or lymphatic malformations, and limb overgrowth. (1)(6) Many patients with lymphatic malformations have an activating somatic PIK3CA gene mutation. (7) This was not the case for our patient.Diagnosis of vascular malformation or neoplasm is often made clinically and confirmed by imaging. For initial imaging, the 2019 American College of Radiology Appropriateness Criteria for Clinically Suspected Vascular Malformation of the Extremities deems magnetic resonance angiography with and without contrast, MRI with and without contrast, computed tomographic (CT) angiography with contrast, and duplex Doppler ultrasonography as appropriate for suspected vascular malformation of the extremity presenting with physical deformity. (8) However, because our patient also had a suspected abnormality in the chest wall, MRI or magnetic resonance angiography with and without contrast would be the best initial study to better evaluate deeper lesions than ultrasonography and better evaluate soft tissue contrast than CT angiography.The presence of renal cysts initially raised concern for underlying lymphangiomatosis. Lymphangiomatosis is the term used to describe lymphatic malformations in multiple organs. (3) It can affect any region of the body, although it is most common in the neck, axilla, retroperitoneum, and mediastinum. Renal lymphangiomatosis in pediatric patients is rare but should be included in the differential diagnosis for conditions such as ADPKD, nephroblastomatosis, lymphoma, and hydronephrosis with perinephric urinoma. (9) Several case reports describe initial misdiagnosis of renal lymphangiomatosis as ADPKD. Imaging and genetic testing can help differentiate between renal lymphangiomatosis and ADPKD. In renal lymphangiomatosis, renal cysts are central in the renal sinus, whereas in ADPKD, renal cysts are peripheral and parenchymal, as was seen with this patient. (9) In addition, the patient’s rapid genome sequencing reveals de novo pathogenic variant of PKD1 mutation, which supports a diagnosis of ADPKD being a separate etiology for renal cysts from that underlying the lymphatic malformations in the chest and right upper extremity. Differentiation between renal lymphangiomatosis and ADPKD can affect the treatment regimen and prognosis. A case report describing an infant with biopsy-proven bilateral renal lymphangiomatosis with 1-year follow-up suggests a self-limiting course in some patients, although it can expand before regression. (10) Successful treatment for renal lymphangiomatosis with sclerotherapy has been described. (3)(9)A case report describing an adult with comorbid lymphangiomatosis and ADPKD hypothesized a link between ADPKD and lymphangiomas as cystic pathologies sharing common genetic and congenital processes; however, no genetic mechanism has been identified. (11)ADPKD is the most common hereditary kidney disease, with a prevalence of 1:1,000 to 1:2,500. Patients with ADPKD develop cysts in the kidney parenchyma, which often leads to end-stage kidney disease by age 50 to 60 years. Our patient’s incidental diagnosis of ADPKD is atypical for several reasons. There was no family history, he developed cysts in the neonatal period, and his presenting complaint was lymphatic malformations. Our patient had a de novo PKD1 mutation, the most common mutation seen in ADPKD. Patients with PKD1 mutations have a less favorable kidney prognosis than patients with PKD2 mutations, who have end-stage kidney disease in their 70s and 80s. The Predicting Renal Outcomes in Polycystic Kidney Disease score combines predictive genetic factors with clinical information to predict risk of progression to end-stage kidney disease for patients with ADPKD in patients older than 35 years. (12) ADPKD is typically diagnosed using renal ultrasonography in patients with an affected first-degree relative. Genetic analysis can be useful in very young patients without a family history of ADPKD, as in our patient, who was found to have a de novo PKD1 mutation.Symptoms from lymphatic malformations vary depending on location of involvement and extent of invasion. Management varies depending on location, size and symptoms (including compression or obstruction of adjacent structures), infection, and interference with quality of life, including cosmetic concerns. Generally, microcystic lymphatic malformations are more challenging to treat than are macrocystic lymphatic malformations because they are less accessible for aspiration or sclerosing. (1)Observation for potential spontaneous regression can be appropriate for small lymphatic malformations without compromise of other systems. (13) Compression dressing is a conservative, first-line option for symptomatic treatment of lymphatic malformations limited to the extremities to prevent pain or growth of the malformation. (4) Treatment options for large or symptomatic lymphatic malformations include sclerotherapy, endovenous laser ablation, radiofrequency ablation, and surgical resection. Drug therapy with sirolimus, sildenafil, or propranolol has been described in case reports. Antibiotics should be used to treat infected lymphatic malformations.Clinical trials in adults with ADPKD show that angiotensin-converting enzyme inhibitors and possibly vasopressin antagonists decrease renal cyst growth. (14) A randomized controlled trial with tolvaptan, a selective vasopressin antagonist, for pediatric ADPKD is underway for children aged 12 to 17 years; results are not yet available. (15) Schaefer et al suggest angiotensin-converting enzyme inhibitors and angiotensin receptor blockers for management of hypertension and proteinuria in the setting of pediatric ADPKD. (15) In addition, there is limited evidence that statin therapy slows the progression of structural kidney disease in children and young adults with ADPKD. (16)The patient was evaluated by a multidisciplinary team including surgery, hematology/oncology, nephrology, genetics, and interventional radiology; he was referred for sclerotherapy but was lost to follow-up.Five months later he presented with cough and was diagnosed as having a parainfluenza infection. Chest radiography revealed airway compromise; CT showed that the intrathoracic extent had dramatically increased, resulting in mediastinal shift and tracheal narrowing (Fig 5). Dark, sanguineous fluid was drained from the lesion, and sclerotherapy was performed using bleomycin. The postsclerotherapy radiograph showed mass reduction and improved lung expansion.Persistent hypertension was treated with enalapril. Repeated renal ultrasonography, compared with postnatal imaging, showed an enlarging right cyst and a new left cyst. Intrathoracic sclerotherapy was repeated 40 days later. Further treatment will be required.

Lymphatic malformation (LM) is a congenital lymphatic dysplasia associated with the p110α subunit of PI3K (PIK3CA) mutation. A two-year-old boy presented with a history of noisy breathing from the age of two months, which was progressively worsening. Inspiratory stridor was audible with subcostal recession. Flexible nasopharyngolaryngoscopy (FNPLS) revealed an enlarged right arytenoid. Other supraglottic structures were normal, and bilateral vocal cords were mobile. Direct laryngoscopy showed that the right arytenoid was enlarged with a smooth surface. On the subsequent visit, there was a painless soft lateral neck swelling, 4 cm x 4 cm in size, with normal skin. MRI confirmed LM with the predominantly macro-cystic component, involving primarily the right neck and upper mediastinum, causing airway compression. Sirolimus therapy was initiated, and at one month of follow-up after the treatment, his stridor had improved. The incidence of stridor secondary to head and neck tumors such as teratomas, hemangiomas, and LM accounts for less than 3%. The typical manifestation of LM often involves a painless, soft, and compressible mass that progressively increases in size. Features of macrocystic LM on MRI are multilocular and hyperintense cystic mass on T2-weighted imaging. The treatment methods for LM include surgical and non-surgical options. Despite being an off-label application, the response rate of sirolimus therapy in children with LM is reported to be 91%, and the first clinical response was observed in less than three weeks. Stridor is frequently encountered in children but rarely due to head and neck tumors. However, as in our case, a large LM may cause recurrent airway obstruction, and the neck swelling may appear later. Atypical airway findings, especially endoscopic examination, in a child with stridor should be complemented with imaging to examine the possibility of extra-laryngeal mass or external compression.

Multidisciplinary management of congenital giant head and neck masses: Our experience and review of the literature

Pattern of congenital neck masses in a Kenyan paediatric population

Considering the anatomy and associated pathology, the lump may represent: • Artery: carotid artery aneurysm, subclavian artery aneurysm, carotid body tumour (i.e. chemodectoma or paraganglioma of the carotid body) • Nerves: neurofibroma, schwannoma • Lymphatics: lymphatic malformations • Lymph nodes: infective, neoplastic (primary or metastatic), granulomatous • Salivary glands: infective, autoimmune, neoplastic • Larynx: laryngocele • Pharynx: pharyngeal pouch • Branchial arch remnant: branchial cyst/sinus/fistula • Skin/superficial subcutaneous: lipoma, epidermal cyst, abscess, dermoid cyst • Muscle/cartilage/bone: sarcomas (e.g. rhabdomyosarcoma, fibrosarcoma, osteosarcoma), cervical rib, torticollis The age of the patient has an enormous bearing upon the pathology you should expect to encounter: • In children, about 75% of neck lumps are benign. Congenital and inflammatory lumps are most common. Thus the differential diagnosis will be weighted in favour of branchial cleft cysts, lymphatic malformations, and lymphadenitis. If malignancy is diagnosed in paediatric neck lumps, it is usually a lymphoma or sarcoma, or sometimes a papillary thyroid carcinoma. • In adults over 40, as many as 75% of lateral neck lumps are malignant. Of the malignant neck lumps, about 80% are metastases and the rest are mostly lymphomas. In fact, ▲ in the absence of signs of infection, a lateral neck mass in an adult is lymphadenopathy due to metastatic carcinoma (usually squamous cell) until proven otherwise. • How long has the lump been there? ■ Less than a few weeks: most likely infective or inflammatory lymphadenopathy, although some patients will present with malignant neck lumps that have only been noticed within the last few days. ■ More than a few weeks: must exclude malignancy. ■ Years, with little change: most likely benign. ■ Note that congenital neck lumps, despite being ‘congenital’, may only ‘appear’ later in life as they may fluctuate in size (e.g. following an infection). • Has the lump got bigger, smaller, or stayed the same size? A lump that is gradually increasing in size must be regarded as a malignancy until proven otherwise. Remember that a progressive increase in size of a malignant neck lump may be reported as a sudden appearance by the patient.

To describe and report the outcomes of doxycycline sclerotherapy in patients with periorbital lymphatic malformations(LMs). A retrospective review of consecutive patients diagnosed with periorbital LMs and who received doxycycline sclerotherapy at Hong Kong Eye Hospital and Queen Elizabeth Hospital, Hong Kong between January 2016 and June 2022. Doxycycline was prepared with a concentration of 100 mg diluted in 10 mL water for injection. A 23-gauge needle aiming at the center of the macrocyst was used to aspirate fluid from the lesion; this was then followed by an intralesional injection of 0.5 to 2 ml of doxycycline depending on the size of the cavity. A total of eight patients(six females) were included in this study. All of them received doxycycline sclerotherapy for periorbital LMs(five extraconal, three intraconal). The median age for receiving sclerotherapy was 29 years old. Seven patients had macrocystic LMs, and one had mixed macro- and microcystic LM. Two of the LMs had venous components radiologically. The average number of sclerotherapy treatment in one patient was 1.4 ± 0.7times. Seven of the eight patients had excellent response radiologically or clinically. One patient showed a satisfactory response after three cycles of sclerotherapy. No recurrence was experienced at median follow-up of 14 months. None of the patients experienced visual threatening or systemic complication. Our preliminary experience with doxycycline sclerotherapy has shown encouraging results for the treatment of macrocystic or mixed-type periorbital LMs, with a favourable safety profile. Further clinical trials with longer follow-ups are warranted on this topic.

Background: Neck masses whether benign or malignant are abnormal growths or lumps that develop in the neck area, and are a common clinical concern. Organized and accurate diagnostic methods are essential for their proper evaluation and management. Aim: This study was conducted to determine the types of neck masses and their association with multiple neck-related diseases using various diagnostic tools among patients belonging to District Lower Dir, Pakistan. Methodology: A comprehensive evaluation of neck masses was conducted in 242 patients including males and females of different ages by using physical examination, ultrasonography, fine needle aspiration cytology (FNAC), gene Xpert, and ultrasound-guided FNAC (USG-FNAC) analyses. Results: Among total patients, 50.41% were males while 49.58% were females. Furthermore, acute, sub-acute, and chronic neck masses were observed in patients 10-70 years old. The ages of 30.5% patients were 10-20 years old, 48.3% were 21-40 years and 21% were 41-70 years old, reported with neck masses. Abscesses and benign thyroid diseases were more common in the 21-40 years age group. However, metastatic squamous carcinoma was predominantly detected in patients from 41-70 years. Furthermore, malignancies were more frequent in patients over 50 years, whereas neck masses in younger patients were typically non-malignant. The patients diagnosed with neck mass through physical examination, ultrasonography, FNAC, Gene Xpert and USG-FNAC were 24.79, 28.09, 22.31, 14.87, and 9.92%, respectively. Among physically diagnosed patients, further neck mass-related diseases were detected as a dermoid cyst (25%), preauricular sinus (11.66%), cervical lymphadenitis (25%), hematoma pinna ear (11.66%), seroma pinna ear (5%), thyroiditis (10%) and lipoma (11.66%). In addition, diseases like thyroglossal duct cysts (14.70%), abscesses (70.58%), pharyngeal pouch (1.47%), bronchial cysts (10.29%) and Ludwig angina (2.94%) were identified with ultrasonography. The patients diagnosed with FNAC have benign thyroid diseases (42.22%), pleomorphic adenoma (16.66%), cystic hygroma (1.11%) and cervical tuberculosis (40%). Similarly, the patients diagnosed with USG-FNAC have medullary thyroid carcinoma (25%), metastatic squamous carcinoma (33.33%), papillary thyroid carcinoma (8.33%), lymphoma (29.16%) and adenoid cystic carcinoma (4.16%). Conclusion: Our findings highlight the age-related incidence of malignancies in neck masses in the local population of the Dir district. Additionally, ultrasound-guided FNAC emerged as the most sensitive diagnostic method for evaluating neck masses.

Background: Facial and neck swellings are frequently encountered in pediatric medicine, and can present a diagnostic dilemma for the clinicians involved. Neck imaging has always been a diagnostic challenge. Multi-Detector row Computed Tomography is an important imaging modality for characterization and presurgical evaluation of neck masses. The aim of the current study was to evaluate the Multi Detector Computed Tomography (MDCT) in diagnosis and interventional management of facial and neck swellings in children. Patients and methods: This is a prospective study included 18 patients (7 males and 11 females) their age range from 8 months to up to 16 years, who were referred to radio diagnosis department from clinical departments at Zagazig University hospitals for assessment of facial and neck swellings by ultrasound (US) and computed tomography (CT) during the period from January 2019 to July 2019. Results: the CT diagnosis of this study was 16.6% hemangioma, venous malformation and lymphatic malformation same percentage 11.11%, benign soft tissue tumor and facial bone tumor due to thalassemia same percentage 5.55%, congenital swelling 16.6% and infectious facial and neck swellings 22.22%.Sixty percentage of cases after sclerotherapy had complete lesion obliteration and 40 % of them had partial lesion obliteration. Sensitivity of MDCT 87.5%, specificity 100%, PPV 100%, NPV 50% and accuracy 90%. Conclusions: MDCT imaging is useful for quick and accurate assessment of facial and neck swelling and the possible improvement of any vascular territory in facial and neck swellings by minimal invasive technique of interventional radiology.

A series of parapharyngeal glial heterotopia mimicking lymphatic malformation

Neck masses are frequently encountered in pediatric medicine, and can present a diagnostic dilemma for the clinicians involved. There are several means by which neck masses in children can be subdivided, for example by age at presentation, anatomical location including compartments and fascia of the neck, their classical appearance when imaged, or by etiology. When imaging children the clinicians must be mindful of radiation exposure and as such ultrasound (US) is often attempted first. Cross sectional imaging can be helpful for problem solving with CT being particularly useful for assessing the patient in more acute scenarios, for example when there is airway compromise. Nuclear medicine scintigraphy has a role in specific circumstances and can aid in staging in the presence of malignancy. If required, additional acquisition by means of magnetic resonance imaging (MRI) and computed tomography (CT) can be considered. This pictorial review describe the diagnostic imaging of (I) congenital and Developmental Pathologies, including thyroglossal duct cyst, branchial cleft cyst, cystic hygroma, dermoid cyst, thymic cyst and ectopic thymus; (II) neoplastic lesions, including hemangiomas and vascular malformations, pilomatrixoma, neurofibroma, neuroblastoma, rhabdomyosarcoma, papillary thyroid cancer, lymphoma & leukemia; (III) neck masses of Infective causes, including lymphadenitis, retropharyngeal and peritonsilar abscess, salivary gland inflammation; and (IV) other miscellaneous lesions, including ranula, sternocleidomastoid fibromatosis coli, and goiter. Neck masses are common in the pediatric population with a broad and varied differential; malignant etiologies are less frequently encountered when compared with adults but an awareness of its potential is important when reviewing imaging.