CC BY-NC-ND 4.0 · Indian J Plast Surg 2017; 50(02): 193-200
DOI: 10.4103/ijps.IJPS_245_15
Original Article
Association of Plastic Surgeons of India

Management of vascular anomalies: Review of institutional management algorithm

Lalit K. Makhija
Department of Plastic Surgery, PGIMER, Dr. RML Hospital, New Delhi, India
,
Sameek Bhattacharya
Department of Plastic Surgery, PGIMER, Dr. RML Hospital, New Delhi, India
› Author Affiliations
Further Information

Address for correspondence:

Dr. Sameek Bhattacharya
Department of Plastic Surgery, PGIMER, Dr. RML Hospital
New Delhi
India   

Publication History

Publication Date:
09 July 2019 (online)

 

ABSTRACT

Introduction: Vascular anomalies are congenital lesions broadly categorised into vascular tumour (haemangiomas) and vascular dysmorphogenesis (vascular malformation). The management of these difficult problems has lately been simplified by the biological classification and multidisciplinary approach. To standardise the treatment protocol, an algorithm has been devised. The study aims to validate the algorithm in terms of its utility and presents our experience in managing vascular anomalies. Materials and Methods: The biological classification of Mulliken and Glowacki was followed. A detailed algorithm for management of vascular anomalies has been devised in the department. The protocol is being practiced by us since the past two decades. The data regarding the types of lesions and treatment modality used were maintained. Results and Conclusion: This study was conducted from 2002 to 2012. A total of 784 cases of vascular anomalies were included in the study of which 196 were haemangiomas and 588 were vascular malformations. The algorithmic approach has brought an element of much-needed objectivity in the management of vascular anomalies. This has helped us to define the management of particular lesion considering its pathology, extent and aesthetic and functional consequences of ablation to a certain extent.


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INTRODUCTION

Vascular anomalies are congenital lesions of vascular origin, which have been both confusing and challenging to manage. Most of the confusions pertaining to them have largely been put to rest with the advent of biological classification.[1] The classification based on the correlation of physical features, natural history and histology categorises vascular anomalies into vascular tumours featuring hyperplasia and vascular malformation which results from localised maldevelopment of vascular morphogenesis. This taxonomy has removed the confusing terminologies, which led to improper diagnosis and treatment earlier. However, the challenge involved in the treatment still remains. Although multidisciplinary approach in management is largely established, we still find patients shuttling between specialities as ‘nomads’. Most of the times, these patients are managed by reconstructive surgeons who play a central role in their management, but still there is a lack of a standard and universally acceptable management protocol for these cases. We have been following an algorithmic approach in the management of vascular anomalies. In this study, we present our data of vascular anomaly patients of over a decade.


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MATERIALS AND METHODS

This study includes a retrospective review of patients of vascular anomalies treated at our department from 2002 to 2012. The biological classification of Mulliken and Glowacki was used to categorise patients.[1] The imaging modalities used were plain radiographs, Doppler study, magnetic resonance (MR) imaging with MR angiography and contrast computed tomography for the evaluation of patients. After diagnosis and classification, the further course of management was on the basis of the protocol [Figure 1a and b].

Zoom Image
Figure 1: (a) Algorithm for vascular tumours and haemangiomas. (b) Algorithm for vascular malformation

In cases of haemangiomas, by default, we exercised masterly inaction keeping the patient under regular observation during the proliferative phase. The indications of intervention during this phase were rapidly growing hemangiomas which ulcerate or bleed, encroach upon vital ares like eyes, nose & mouth, compromise oral intake or causing airway obstruction.

  • Visual obstruction

  • High-output cardiac failure.

If any of the above-mentioned indications was there at presentation or during any time in the proliferative phase, pharmacotherapy was prescribed. The most common indications were rapid growth and ulcerations. From 2002 to 2008, the pharmacological intervention was either systemic prednisolone or intralesional triamcinolone. Intralesional triamcinolone (25 mg/mL) was administered for small localised haemangiomas at a dosage of 3–5 mg/kg every 4–6 weeks. Systemic prednisolone was prescribed for large lesions at a dosage of 2–3 mg/kg/day till the child was 10–12 months of age. The dosage was tailored as the child gained weight. The dosage was tapered slowly every 2–4 weeks before discontinuing prednisolone. In cases where there was rebound growth after discontinuation of corticosteroid, another course of 4–6 weeks was instituted. Since 2009, oral propranolol was the mainstay pharmacotherapeutic agent. It was decided to switch over to propranolol as there was faster response and fewer side effects. It was prescribed at a dose of 2–3 mg/kg/day in three divided dosages. The dose was gradually tapered every 4 weeks and discontinued by about 10–12 weeks of age. In case a rebound growth was noticed after stoppage of propranolol, a 4-week course was repeated. Cases which presented with post-involution residual lesion were addressed surgically.

The protocol for vascular malformation was separate for low? and high-flow varieties. Localised venous, lymphatic and lymphatico-venous malformations (LVMs) in areas where there were no aesthetic and functional consideration were excised. Extensive lesions where significant post-excision functional and/or aesthetic deficit were foreseen, excision was not done initially to avoid post-excision functional loss and disfigurement, for example, in face and hand. Instead sclerotherapy was done with Sodium tetradecyl sulphate (0.5-2 mL of 1% solution intra-lesionally) or Bleomycin (1 mg/kg body weight, intralesionally) in venous malformation (VM) and lymphatic malformation (LM), respectively. The number of sclerotherapy sessions was guided by the size of the lesion and the response to the treatment. The endpoint of the therapy was either complete resolution of the lesion or no further reduction in size. In latter cases, the residual malformation was surgically excised. Capillary malformations (CMs) were categorised into flat and nodular lesions. In former cases, pulse dye laser therapy was recommended, and in the latter cases, surgical excision was done in localised and excisable lesions. Camouflage was advised in the rest. Small high-flow vascular malformations were excised after encircling the lesion with haemostatic sutures. Larger lesions were also excised where proximal control was possible with tourniquet. In cases where proximal control was not possible, like in head and neck malformations with intra-abdominal components, preliminary embolisation was done followed by excision or debulking 24 h later.

The data of the patients were maintained in terms of diagnosis, age, sex, site, tissue involved, treatment given and final outcome. The data were compiled and analysed in Microsoft Excel®.


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RESULTS

A total of 784 cases of vascular anomalies were included in the study who presented to this hospital from 2002 to 2012. Out of these, 196 were vascular tumours and 588 were vascular malformations. In the vascular tumour category, 192 were haemangiomas and 4 were haemangioendotheliomas. The distribution of the haemangioma patients in terms of gender and site is shown in [Table 1]. The nature of intervention in relation to haemangioma is shown in [Table 2]. In majority of the patients (110/196), masterly inaction was followed so that the lesions could involute spontaneously by an age ranging from 5 to 7 years. Thirty-seven cases were operated for residual lesions after involution, out of which 22 were in face and neck area, 9 in extremities and 6 in trunk. Eight patients with facial lesions needed tissue expansion. Rest of the residual lesions were excised and primarily closed. Forty patients needed pharmacological intervention during proliferative phase. The indications for pharmacotherapy are shown in [Table 3]. The most common indication being rapidly growing tumour leading to ulceration and repeated bleeding. Nineteen patients required systemic prednisolone. Intralesional triamcinolone was given to nine patients. Twelve patients were treated with propranolol [Figure 2]. Only nine patients required surgery.

Zoom Image
Figure 2: Haemangioma of the face, treated by propranolol
Table 1

Distribution of hemangiomas according to site

Distribution

Hemagioma

Hemagioendothelioma

Congenital

Infantile

5

187

4

Location

Male

Female

Total

Cervicofacial

27

91

118

Trunk

12

24

36

Extremities

23

19

42

62

134

196

Table 2

Interventions in hemangioma patients

Interventions

Number

Pharmacotherapy

40

Systemic Prednisolone

19

Intralesional Triamcinalone

9

Propranolol

12

Surgical

9

Intervention for residual lesion

37

None

110

Table 3

Pharmacotherapy in hemangioma patients

Indications for Pharmacotherapy

Number

Bleeding

13

Visual obstruction

4

Nostril obstruction

2

Oral cavity obstruction

6

Bleeding diathesis

5

Rapid growth with Necrosis

10

Total

40

A total of 588 cases of vascular malformation were included in the study. On the whole, 87.24% (513/588) of cases were low-flow and 12.76% (75/588) were high-flow lesions. The distribution of types of vascular malformations as per gender and site is shown in [Tables 4] [5], respectively. The most common malformations were venous and lympho-venous accounting for 53.74% followed by LMs (22.1%), arterial/arterio VM (AVM) (12.76%) and the least common being CMs (11.39%). The overall gender distributions of the lesions were almost similar in both sexes with a slight male preponderance. Male predominance was evident in VM/LVM, LM and arterial malformation (AM)/AVM, but females significantly outnumbered the CM cases. Majority of the CM (47.74%) cases were in the cervico-facial region followed by 33.83% in the extremities. All the CMs were intradermal in location. LM and AM/AVM were distributed equally in cervico-facial area and extremities, but in case of VM/LVM, 56.12% were in extremities and 28.48% were in cervico-facial region. In all types of malformations, trunk was least affected. Most of the LM cases were either subcutaneous (46.15%) or both subcutaneous and intramuscular (51.54%) involvement and only three had pure muscular involvement. Most of the VM/LVMs (76.58%) were in the subcutaneous plane and 20.25% were in both subcutaneous and muscular planes. However, significantly ten (3.16%) VM/LVM lesions were intramuscular and all of them were in extremities. In cases of AM/AVM, 34.66% were in subcutaneous tissue and 25.33% had involvement of both subcutaneous tissue and muscle. The ablative modalities used for different types of lesions are shown in [Table 6], and the reconstructive option used for the post-excision defect is shown in [Table 7]. CM cases were either referred to the dermatology department for laser or were excised. The former option was exercised in 43.28% (29/67) of cases and 34.33% (23/67) of cases were excised. Excision was done in cases where the lesions were small and localised, and in some cases, the response of laser was suboptimal. Most of them (17) were primarily closed after excision, but seven required local flaps, three were closed by pre-expanded flaps and five defects were skin grafted. Fifteen (22.39%) patients with extensive CM either had incomplete ablation or could not be treated by any modality. Out of 130 LMs, 60 were excised and 11 were sclerosed by bleomycin and 24 patients underwent excision after one or multiple sessions of sclerotherapy. Thirty-five (26.92%) patients had either partial debulking or no excision owing to the extensive nature of the lesion.

Table 4

Gender distribution of vascular malformations

Lesions

Male

Female

Total

CM

22

45

67

LM

72

58

130

VM and LVM

170

146

316

AM, AVM, AVF

42

33

75

306

282

588

Table 5

Distribution vascular malformations according to site

Lesion

Location

Total

Cervicofacial

Total

Trunk

Total

Extremities

Total

Multiple sites

ID

SC

IM

SC + IM

ID

SC

IM

SC + IM

ID

SC

IM

SC + IM

ID

SC

IM

SC + IM

CM

32

0

0

0

32

8

0

0

0

8

22

0

0

0

22

5

0

0

0

67

LM

0

31

0

22

53

0

12

0

6

18

0

13

3

38

54

0

4

0

1

130

VM and LVM

0

69

21

90

0

35

0

8

43

0

135

10

32

177

3

3

316

AM, AVM, AVF

0

27

0

5

32

0

3

0

1

4

0

26

0

13

39

0

0

0

0

75

Total

32

127

0

48

207

8

50

0

15

73

22

174

13

83

292

5

7

0

4

588

Table 6

Interventions in vascular malformations

Intervention

Lesion

Laser

Excision

Sclerotherapy

Sclerotherapy +Excision

Pre-op embolisation +Excision

No or incomplete treatment

Total

CM

29

23

0

0

0

15

67

LM

0

60

11

24

0

35

130

VM and LVM

0

109

78

108

0

21

316

AM, AVM, AVF

0

37

1

0

29

8

75

Total

29

229

90

132

29

79

588

Table 7

Surgical intervention in vascular malformations

Surgery

Lesion

Pry Closure

Local Flap

Regional Flap

Free Flap

Tissue Expander

Skin grafting

Total

CM

17

7

0

0

3

5

32

LM

83

9

4

0

0

15

111

VM and LVM

133

33

5

4

0

42

217

AM, AVM, AVF

61

3

3

3

0

2

72

Total

294

52

12

7

3

64

434

In 83 patients, the post-excision defect could be closed primarily whereas nine and four cases required local and regional flaps, respectively, and 15 defects were skin grafted. Venous and lympho-VMs were managed by only excision, only sclerotherapy sclerotherapy followed by excision. Seventy-eight patients were treated by sclerosant injection only [Figure 3]. Two hundred and seventeen cases were operated upon, and out of that, 109 cases were excised [Figures 4] [5] and 108 were excised after sclerotherapy. In 21 patients with extensive lesion, partial excision or no ablation was done [Figure 6]. After excision, primary closure was possible in 133 cases, 33 needed local flaps, 5 needed regional flaps and 4 defects were reconstructed by free tissue transfer and 42 defects were skin grafted. Arterial and AVMs were either excised after securing control of the feeding artery or excised following embolisation [Figures 7] [8]. The option of securing proximal control during operation was tourniquet, clamping or ligation of feeding vessel, encircling haemostatic sutures and occlusion with intestinal non-crushing clamps. Thirty-seven cases could be excised with pre-operative proximal control and 29 were removed after pre-operative embolisation. One patient of multiple arteriovenous fistulae of foot was managed with sclerotherapy under tourniquet. The patient had only temporary relief. In eight patients, ablation was not attempted owing to the extensive nature of the lesion or due to involvement of vital structures. Out of 66 cases of high-flow lesions which were operated upon, the post-excision defect could be primarily closed in 61, local, regional and free flaps were used in three cases each and 2 were skin grafted. In vascular malformations managed by sclerotherapy, the most common complication was overlying skin necrosis. The most common complication of excision in the cases of vascular malformation was haematoma.

Zoom Image
Figure 3: Venous malformation of the lower lip managed by sclerotherapy only
Zoom Image
Figure 4: Localised lymphatic malformation of the neck, excised
Zoom Image
Figure 5: Excision of intramuscular venous malformation
Zoom Image
Figure 6: Extensive lymphovenous malformation of the face. Multiple sclerotherapy followed by partial debulking
Zoom Image
Figure 7: Intramuscular arterial malformation with feeding vessel from internal iliac artery. Preoperative embolisation and per-abdominal ligation of internal iliac artery followed by complete excision
Zoom Image
Figure 8: Arterial malformation temporal region with intractable bleeding. Ligation of external carotid artery followed by excision and skin grafting

#

DISCUSSION

The vascular anomalies were first classified by Virchow in 1876.[2] Although the classification stood the test of time for nearly a century, it did not allow standardisation of treatment of vascular anomalies mainly because of lack of understanding of the natural behaviour of the lesions and erroneous terminologies. It was in 1982 Mulliken and Glowacki proposed a biological classification based on endothelial characteristics integrating physical findings, natural history and histology.[1] This system divided vascular anomalies into vascular tumours and vascular malformations.[1] [3] The fundamental difference between the two is presence of endothelial proliferation in the former and vascular architectural aberration in the latter. This classification is now accepted worldwide, has brought a lot of clarity in the understanding of these lesions and has paved the way for standardised treatment protocol. The treatment protocol used in the present study is based on this classification.

In this study, haemangiomas account for 25% and vascular malformations account for 75% of all vascular anomalies. Haemangioma is the most common infantile tumour in Western population where it occurs in 4%–10% of the population and 3–5 times more common in females. Haemangiomas are not as common in our country as the population is racially different. Sachin et al. reported that haemangiomas were only 15.56% of the vascular anomalies in their study[4] and 31.59% in a study by Ye et al.[5] The male-to-female ratio among haemangiomas in our study was 1:2.16 which is less than what is seen in European population.[6] Lesser female predominance of 1:1.49 was also reported by Ye et al.[5] Regarding regional predilection, majority (60.2%) of the lesions in the present study were cervico-facial followed by extremities and trunk which is reflected in other studies[4] [5] as well.

In the present study, 43.88% (86/196) of patients of haemangiomas required some form of interventions, which is in consonance with studies from rest of the world.[7] [8] [9] [10] [11] Following the advent of use of propranolol, a pharmacotherapeutic agent for haemangioma, propranolol replaced prednisolone in our protocol from 2009 onwards, as it had a faster response and fewer side effects. Although there is a controversy regarding admission for propranolol administration,[12] all patients in our study were admitted for propranolol administration. The mechanism of action of propranolol remains vague, but it is believed to be due to regulation of vascular growth factors and haemodynamic cytokines.[13] In most studies, the majority of the cases were low flow but the proportion of high flow varied. In the study by Ye et al., high flow accounted for 23.3%.[5] Although CMs are the most common malformations reported in literature, in this study, the venous and lympho VMs accounted for majority of cases (53.74%). In the literature, the reported prevalence of CM was 0.3% in children,[13] LM was 1: 2000–4000 live births[14] and VM was 1: 10000.[15] The treatment protocol for vascular malformation was fundamentally governed by three aspects, namely, its type, site and tissues involved. CMs are ideal for laser ablation. The Pulse dye laser is reported to be most efficacious in these although argon, potassium titanyl phosphate and 755 nm laser have also been used in advanced cases.[16] [17] The laser treatment was done by dermatology department, and only cases with long-standing CM with tissue hypertrophy were managed by us. Excision was the preferred modality in these cases. No treatment could be offered to six cases of extensive CMs who had presented in adult age and in whom lesions were thick precluding laser therapy, and in nine cases, incomplete removal was only possible. Such situations have been reported in literature as well.[18] Lymphatic malformations were mostly excised after sclerotherapy. Since many of the lesions had concomitant skin lesions, most of the extirpation left significant skin defects warranting either skin grafting or flap cover. This aspect of LM warranting complex reconstruction is reported in literature.[19] Several sclerotherapy options are available for sclerotherapy of LMs, namely, ethanol, bleomycin, OK-432 and doxycycline.[20] [21] [22] In our series, we have used bleomycin only. There was no sclerosant-related complications in LMs. Carbon dioxide laser has also been reported to be used in intra-oral LMs.[23] The management of VMs is also a multimodality approach which includes surgery, neodymium-doped yttrium aluminium garnet (Nd:Yag) laser and sclerotherapy.[24] Nd:Yag laser is reported to be very effective as it causes shrinkage and thrombosis of the aberrant venous channels.[24] Sclerotherapy is also an effective modality for VMs, and the sclerosants commonly used are sodium tetradecyl sulphate, ethanol, bleomycin and OK-432.[25] [26] [27] In our series, complete ablation of most of the VMs was possible with surgical excision either primarily or after sclerotherapy. However, for VMs in superficial plane, especially in face and hand, only sclerotherapy was tried at first to avoid post-surgical scarring and deformity. The gold standard of management of high-flow or AVM is excision with or without pre-operative embolisation of feeding vessel.[28] Most of the high-flow malformations in our series were also excised.


#

CONCLUSION

The protocol has brought an element of much-needed objectivity in the management of vascular anomalies. This has helped us to define the management of particular lesion considering its pathology, extent and aesthetic and functional consequences of ablation to a certain extent. The basic premise of our management protocol is preservation of form and function vis-à-vis complete ablation. It is always wise to lean towards sclerotherapy in cases of LM and VM of face and hand. Sometimes, it is prudent to settle for a suboptimal excision to preserve aesthetic and function.

The algorithmic protocol also helps in counselling of patients regarding the course of management and possible outcome. The study reiterates the importance of seamless coordination of surgeon, reconstructive surgeon, intervention radiologist, cardiologist and laser therapist in managing these complex lesions. In a significant number of patients where no treatment could be offered underlines the fact that the final frontier in the management of vascular anomalies is yet to be reached.

Declaration of patient consent

The authors certify that they have obtained all appropriate patient consent forms. In the form the patient(s) has/have given his/her/their consent for his/her/their images and other clinical information to be reported in the journal. The patients understand that their names and initials will not be published and due efforts will be made to conceal their identity, but anonymity cannot be guaranteed.


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Financial support and sponsorship

Nil.


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Conflicts of interest

There are no conflicts of interest.

  • REFERENCES

  • 1 Mulliken JB, Glowacki J. Hemangiomas and vascular malformations in infants and children: A classification based on endothelial characteristics. Plast Reconstr Surg 1982; 69: 412-22
  • 2 Balakrishnan G. Vascular anomalies of upper limb. Ind J. Plast Surg 2011; 44: 276-82
  • 3 Finn MC, Glowacki J, Mulliken JB. Congenital vascular lesions: Clinical application of a new classification. J Pediatr Surg 1983; 18: 894-900
  • 4 Sachin K, Rashmi S, Manish S, Siddhartha W, Uday L. Haemangiomas and venous malformations of the head and neck: A retrospective analysis of endovascular management in 358 patients. Indian J Plast Surg 2013; 46: 109-16
  • 5 Ye CS, Pan LX, Huang YB, Han AJ, Ye RY, Li SQ. et al. Clinical analysis of vascular anomalies: A hospital-based retrospective study of 592 patients in Southeast China. Chin Med J (Engl) 2011; 124: 3008-12
  • 6 Hemangioma Investigator Group. Haggstrom AN, Drolet BA, Baselga E, Chamlin SL, Garzon MC. et al. Prospective study of infantile hemangiomas: Demographic, prenatal, and perinatal characteristics. J Pediatr 2007; 150: 291-4
  • 7 North PE, Waner M, Brodsky MC. Are infantile hemangiomas of placental origin?. Ophthalmology 2002; 109: 633-4
  • 8 Yu Y, Flint AF, Mulliken JB, Wu JK, Bischoff J. Endothelial progenitor cells in infantile hemangioma. Blood 2004; 103: 1373-5
  • 9 Khan ZA, Boscolo E, Picard A, Psutka S, Melero-Martin JM, Bartch TC. et al. Multipotential stem cells recapitulate human infantile hemangioma in immunodeficient mice. J Clin Invest 2008; 118: 2592-9
  • 10 Ronchese F. The spontaneous involution of cutaneous vascular tumors. Am J Surg 1953; 86: 376-86
  • 11 Metry D, Heyer G, Hess C, Garzon M, Haggstrom A, Frommelt P. et al. Consensus statement on diagnostic criteria for PHACE syndrome. Pediatrics 2009; 124: 1447-56
  • 12 Cushing SL, Boucek RJ, Manning SC, Sidbury R, Perkins JA. Initial experience with a multidisciplinary strategy for initiation of propranolol therapy for infantile hemangiomas. Otolaryngol Head Neck Surg 2011; 144: 78-84
  • 13 Richter GT, Friedman AB. Hemangiomas and vascular malformations: Current theory and management. Int J Pediatr 2012; 2012: 645678
  • 14 Perkins JA, Manning SC, Tempero RM, Cunningham MJ, Edmonds Jr. JL, Hoffer FA. et al. Lymphatic malformations: Current cellular and clinical investigations. Otolaryngol Head Neck Surg 2010; 142: 789-94
  • 15 Boon LM, Mulliken JB, Enjolras O, Vikkula M. Glomuvenous malformation (glomangioma) and venous malformation: Distinct clinicopathologic and genetic entities. Arch Dermatol 2004; 140: 971-6
  • 16 Chapas AM, Eickhorst K, Geronemus RG. Efficacy of early treatment of facial port wine stains in newborns: A review of 49 cases. Lasers Surg Med 2007; 39: 563-8
  • 17 Izikson L, Aderson RR. Treatment endpoint of resistant portwine stain with a 755 nm laser. J Cosmetic Laser Therapy 2009; 11: 52-5
  • 18 Tark KC, Lew DH, Lee DW. The fate of long-standing port-wine stain and its surgical management. Plast Reconstr Surg 2011; 127: 784-91
  • 19 Zeng RS, Liu XQ, Wang AX, Wang DW, Wang JN. Sequential treatment of giant lymphatic malformation of the tongue combined with severe oral and maxillofacial deformities. J Oral Maxillofac Surg 2008; 66: 2364-71
  • 20 Smith MC, Zimmerman MB, Burke DK, Bauman NM, Sato Y, Smith RJ. OK-Collaborative Study Group. Efficacy and safety of OK-432 immunotherapy of lymphatic malformations. Laryngoscope 2009; 119: 107-15
  • 21 Nehra D, Jacobson L, Barnes P, Mallory B, Albanese CT, Sylvester KG. Doxycycline sclerotherapy as primary treatment of head and neck lymphatic malformations in children. J Pediatr Surg 2008; 43: 451-60
  • 22 Okada A, Kubota A, Fukuzawa M, Imura K, Kamata S. Injection of bleomycin as a primary therapy of cystic lymphangioma. J Pediatr Surg 1992; 27: 440-3
  • 23 Glade RS, Buckmiller LM. CO2 laser resurfacing of intraoral lymphatic malformations: A 10-year experience. Int J Pediatr Otorhinolaryngol 2009; 73: 1358-61
  • 24 Glade RS, Richter GT, James CA, Suen JY, Buckmiller LM. Diagnosis and management of pediatric cervicofacial venous malformations: Retrospective review from a vascular anomalies center. Laryngoscope 2010; 120: 229-35
  • 25 Perkins JA, Manning SC, Tempero RM, Cunningham MJ, Edmonds Jr. JL, Hoffer FA. et al. Lymphatic malformations: Review of current treatment. Otolaryngol Head Neck Surg 2010; 142: 795-803 803.e1
  • 26 Berenguer B, Burrows PE, Zurakowski D, Mulliken JB. Sclerotherapy of craniofacial venous malformations: Complications and results. Plast Reconstr Surg 1999; 104: 1-11
  • 27 Wang YA, Zheng JW, Zhu HG, Ye WM, He Y, Zhang ZY. Sclerotherapy of voluminous venous malformation in head and neck with absolute ethanol under digital subtraction angiography guidance. Phlebology 2010; 25: 138-44
  • 28 Bradley JP, Zide BM, Berenstein A, Longaker MT. Large arteriovenous malformations of the face: Aesthetic results with recurrence control. Plast Reconstr Surg 1999; 103: 351-61

Address for correspondence:

Dr. Sameek Bhattacharya
Department of Plastic Surgery, PGIMER, Dr. RML Hospital
New Delhi
India   

  • REFERENCES

  • 1 Mulliken JB, Glowacki J. Hemangiomas and vascular malformations in infants and children: A classification based on endothelial characteristics. Plast Reconstr Surg 1982; 69: 412-22
  • 2 Balakrishnan G. Vascular anomalies of upper limb. Ind J. Plast Surg 2011; 44: 276-82
  • 3 Finn MC, Glowacki J, Mulliken JB. Congenital vascular lesions: Clinical application of a new classification. J Pediatr Surg 1983; 18: 894-900
  • 4 Sachin K, Rashmi S, Manish S, Siddhartha W, Uday L. Haemangiomas and venous malformations of the head and neck: A retrospective analysis of endovascular management in 358 patients. Indian J Plast Surg 2013; 46: 109-16
  • 5 Ye CS, Pan LX, Huang YB, Han AJ, Ye RY, Li SQ. et al. Clinical analysis of vascular anomalies: A hospital-based retrospective study of 592 patients in Southeast China. Chin Med J (Engl) 2011; 124: 3008-12
  • 6 Hemangioma Investigator Group. Haggstrom AN, Drolet BA, Baselga E, Chamlin SL, Garzon MC. et al. Prospective study of infantile hemangiomas: Demographic, prenatal, and perinatal characteristics. J Pediatr 2007; 150: 291-4
  • 7 North PE, Waner M, Brodsky MC. Are infantile hemangiomas of placental origin?. Ophthalmology 2002; 109: 633-4
  • 8 Yu Y, Flint AF, Mulliken JB, Wu JK, Bischoff J. Endothelial progenitor cells in infantile hemangioma. Blood 2004; 103: 1373-5
  • 9 Khan ZA, Boscolo E, Picard A, Psutka S, Melero-Martin JM, Bartch TC. et al. Multipotential stem cells recapitulate human infantile hemangioma in immunodeficient mice. J Clin Invest 2008; 118: 2592-9
  • 10 Ronchese F. The spontaneous involution of cutaneous vascular tumors. Am J Surg 1953; 86: 376-86
  • 11 Metry D, Heyer G, Hess C, Garzon M, Haggstrom A, Frommelt P. et al. Consensus statement on diagnostic criteria for PHACE syndrome. Pediatrics 2009; 124: 1447-56
  • 12 Cushing SL, Boucek RJ, Manning SC, Sidbury R, Perkins JA. Initial experience with a multidisciplinary strategy for initiation of propranolol therapy for infantile hemangiomas. Otolaryngol Head Neck Surg 2011; 144: 78-84
  • 13 Richter GT, Friedman AB. Hemangiomas and vascular malformations: Current theory and management. Int J Pediatr 2012; 2012: 645678
  • 14 Perkins JA, Manning SC, Tempero RM, Cunningham MJ, Edmonds Jr. JL, Hoffer FA. et al. Lymphatic malformations: Current cellular and clinical investigations. Otolaryngol Head Neck Surg 2010; 142: 789-94
  • 15 Boon LM, Mulliken JB, Enjolras O, Vikkula M. Glomuvenous malformation (glomangioma) and venous malformation: Distinct clinicopathologic and genetic entities. Arch Dermatol 2004; 140: 971-6
  • 16 Chapas AM, Eickhorst K, Geronemus RG. Efficacy of early treatment of facial port wine stains in newborns: A review of 49 cases. Lasers Surg Med 2007; 39: 563-8
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Figure 1: (a) Algorithm for vascular tumours and haemangiomas. (b) Algorithm for vascular malformation
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Figure 2: Haemangioma of the face, treated by propranolol
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Figure 3: Venous malformation of the lower lip managed by sclerotherapy only
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Figure 4: Localised lymphatic malformation of the neck, excised
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Figure 5: Excision of intramuscular venous malformation
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Figure 6: Extensive lymphovenous malformation of the face. Multiple sclerotherapy followed by partial debulking
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Figure 7: Intramuscular arterial malformation with feeding vessel from internal iliac artery. Preoperative embolisation and per-abdominal ligation of internal iliac artery followed by complete excision
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Figure 8: Arterial malformation temporal region with intractable bleeding. Ligation of external carotid artery followed by excision and skin grafting