Hypertrophic Port-wine Stains Research Articles

Sporadic hypertrophic and nodular port-wine stain: a study of 27 cases with emphasis on histological features and novel mutation type

AimsTo investigate the clinicopathological features and molecular characteristics of sporadic hypertrophic and nodular port-wine stains (PWS).MethodsWe analysed the clinicopathological and molecular characteristics of 27 sporadic hypertrophic and nodular PWS retrieved...

Application of short-pulsed CO2 laser and long-pulsed Nd:YAG laser in the treatment of severe hypertrophic port-wine stains

BackgroundThe treatment of port-wine stains (PWS) becomes extremely difficult due to age-related malformation of the vasculature. In this study, we used alternative methods to treat hypertrophic PWS. MethodsA short-pulsed CO2 laser was applied to ablate the hypertrophic vasculature of PWS. The ablation was ended when the wound was on the same plane as normal skin. The long-pulsed neodymium-doped yttrium-aluminum-garnet (lpNd:YAG) laser was primarily applied to coagulate and subsequently liquefy the hypertrophic vasculature of the PWS. The therapeutic energy used in treating different lesions should be carefully regulated to significantly affect the treatment outcomes. ResultsThe two cases presented herein demonstrated substantial improvement in hypertrophic vasculature that was largely removed. The skin was resurfaced, although some scar formation and mild hypopigmentation occurred. ConclusionWe suggest the use of short-pulsed CO2 and lpNd:YAG lasers for treating certain cases of hypertrophic PWS. When using a short-pulsed CO2 laser, it is wise to judge the treatment endpoint and take appropriate precautions to avoid intraoperative bleeding. When using an lpNd:YAG laser, the therapeutic energy should be controlled according to the thickness of the lesion to reduce scar formation.

Histological analysis of different types of port-wine stains to guide clinical decision making: A retrospective study.

Port-wine stains are defined as congenital benign vascular lesions. The treatment of port-wine stains remains a challenge, worldwide. This study aimed to analyze the histological characteristics in different types of port-wine stains and provide guidance for clinical decision-making. Biopsies were from the hospital from 2015 to 2021. H&E staining, Immunofluorescence staining, Masson's trichrome staining and Weigert staining were performed on the tissues. A total of 35 port-wine stains patients were included in the study of four distinct types, namely red port-wine stains (11 cases), purple port-wine stains (seven cases), hypertrophic port-wine stains (nine cases) and nodular port-wine stains (eight cases). The mean vessel diameter of the different types was 38.7 ± 5.9 μm, 93.5 ± 9.7 μm, 155.6 ± 21.8 μm and 155.6 ± 29.54 μm, respectively. Mean vessel depth was 396.4 ± 31 μm, 944.2 ± 105.4 μm, 2,971 ± 161.3 μm and 3,594 ± 364.6 μm, respectively. The vessels in red port-wine stains, purple port-wine stains and hypertrophic port-wine stains were mainly composed of capillary and venous malformations, whereas those in nodular port-wine stains were venous or arteriovenous malformations. The main limitation of the current study was the small number of patients. As the disease progresses, vessel diameters become larger, the vessel wall becomes thicker and vessels were found in a greater depth. A treatment plan should be scientifically formulated keeping in mind the histological characteristics of port-wine stains.

Expression of Cathepsins B, D, and G in Hypertrophic Port-wine Stain

Objectives: Cathepsins B, D, and G are expressed in vascular anomalies, fibroproliferative conditions, and malignancies. We investigated expression of these cathepsins and their localization to the embryonic stem cell (ESC)-like population in hypertrophic port-wine stain (hPWS). Methods: Immunohistochemical staining for cathepsins B, D, and G was performed on 15 hPWS tissue samples. Immunofluorescence dual staining investigated localization of the cathepsins with endothelial marker CD31, ESC markers OCT4 and SOX2, and mast cell markers chymase and tryptase on 2 hPWS tissue samples. Protein and transcript expression were investigated by western blotting and reverse-transcription quantitative polymerase chain reaction on 6 tissue samples and 3 hPWS-derived primary cell lines, respectively. Enzymatic activity assays of cathepsins B and D were performed on 6 tissue samples. Results: Immunohistochemical staining demonstrated expression of cathepsins B and D on the endothelium and media of lesional vessels and cells within the stroma. Cathepsin G was expressed in the stroma. Immunofluorescence staining showed localization of cathepsins B and D to the OCT4+/SOX2+ population, and cathepsin G to mast cells, in hPWS. Reverse-transcription quantitative polymerase chain reaction demonstrated transcript expression of all 3 cathepsins in hPWS tissues and cathepsins B and D in cell lines. Protein expression and enzymatic activity of cathepsins B and D was confirmed by western blotting and enzymatic activity assays, respectively. Conclusion: Cathepsins B and D are expressed by the ESC-like population on the endothelium and media of the lesional vessels and stroma, and cathepsin G is expressed by mast cells in hPWS. Functional investigations are needed to fully elucidate the functional role of these cathepsins in hPWS.

Embryonic Stem Cell-like Population in Hypertrophic Port-wine Stain

Objective: To identify and characterize an embryonic stem cell (ESC)-like population within hypertrophic port-wine stain (HPWS). Methods: HPWS tissue samples from 15 patients underwent immunohistochemical staining for induced pluripotent stem cell (iPSC) markers OCT4, SOX2, NANOG, KLF4, and c-MYC. Immunofluorescence staining was performed on 2 of these tissue samples to investigate colocalization of these markers. In situ hybridization and reverse transcriptase quantitative polymerase chain reaction (RT-qPCR) were performed on 6 of the HPWS samples to investigate transcript expression of these iPSC markers. Western blotting and RT-qPCR were performed on 3 HPWS-derived primary cell lines, to determine protein and transcript expression of these markers, respectively. Results: Immunohistochemical staining demonstrated expression of OCT4, SOX2, KLF4, and c-MYC but not NANOG on the endothelium and media of lesional vessels and on cells within the stroma in all 15 HPWS tissue samples. Immunofluorescence staining showed the presence of an OCT4+/SOX2+/NANOG-/KLF4+/c-MYC+ ESC-like subpopulation within the endothelium and media of the lesional vessels, and cells within the stroma of HPWS. In situ hybridization detected OCT4, SOX2, KLF4, and c-MYC transcripts in all 6 HPWS tissue samples. RT-qPCR demonstrated transcripts of all 5 iPSC markers in the HPWS tissue samples and in the HPWS-derived primary cell lines, which expressed OCT4, SOX2, KLF4, and c-MYC but not NANOG proteins by Western blotting. Conclusion: This study demonstrated an OCT4+/SOX2+/NANOG-/KLF4+/c-MYC+ ESC-like population within the endothelium and media of the lesional vessels and the cells within the stroma of HPWS.

Hypertrophic port-wine stain: a clinicopathological analysis of 24 cases

Objective: To investigate the clinical and pathologic features, diagnosis and differential diagnosis of hypertrophic port-wine stain (PWS). Methods: Cases of hypertrophic PWS, collected from Henan Provincial People's Hospital between 2012 and 2018, were retrospectively analyzed for their clinical and pathologic features, immunophenotype and histochemical data, and the relevant literature was reviewed. Results: Twenty-four cases of PWS were included in this cohort, located in the head and neck region (20 cases), limbs (2 cases), and trunk (2 cases). The clinical presentations were mainly red or purple-red plaques or slow growing, painless nodules, or thickened and raised above the skin surface. Microscopically, deformed blood vessels showed honeycomb-like, plexiform or cluster-like growth pattern, and diffusely involved the dermis, skin appendages, subcutaneous fat tissue, and deep skeletal muscles; The vascular lumen of the deformed vessels was dilated (≥100 μm in diameter), and in 18 cases the lumen was greater than 400 μm. The superficial dermis mainly contained few deformed capillaries. The deep wall showed thickening of blood vessel wall and fibrous tissue hyperplasia. Elastic fiber and Masson staining indicated abnormal venous vessel, which in some cases contained small amount of abnormal arterioid vessel,without vascular endothelial cell proliferation in all cases. In 24 cases, 19 cases had epidermal atrophy, 6 with vascular chronic inflammation or epidermal ulcer, 4 with capillary hemangioma, 4 with sebaceous gland hyperplasia, 2 with epidermal papillary hyperplasia and 2 with vascular keratomas. Conclusions: PWS is a common congenital capillary malformation. The number of histologically deformed capillaries is reduced and they usually locate in the superficial part. The deep vascular wall is increased with thick venous malformation, diffusely involving the dermis and deep skeletal muscle. Furthermore, PWS needs to be differentiated from infantile hemangioma, cavernous hemangioma and vascular keratomas.

Analysis of ultrasound images of port-wine stains

Objective To investigate ultrasound features of port-wine stains (PWS) , and to evaluate the diagnostic value of ultrasound imaging. Methods A total of 128 patients with pathologically or clinically confirmed PWS (162 lesions) , who were also subjected to ultrasound examination, were collected from Shanghai Ninth People′s Hospital affiliated to Shanghai Jiao Tong University School of Medicine between January 2015 and January 2016. According to ultrasound findings, these PWS lesions were divided into 3 types: flat type, hypertrophic type and nodular type, and the ultrasound features were retrospectively analyzed. Results For 95 patients with flat PWS (118 lesions) , the skin thickness was significantly higher in the lesion areas than in the normal areas, but most of the thickness difference was less than 0.2 mm. Of the 118 lesions, 79 (67%) showed hypoechoic areas, 75 (64%) showed no blood flow signal, and the vein spectrum was detected in 15, with a peak of (3.33 ± 1.80) cm/s. For 17 patients with hypertrophic PWS (24 lesions) , the lesion areas showed significantly increased skin thickness compared with the normal areas (1.80 ± 0.70 mm vs. 1.14 ± 0.43 mm, t = 6.834, P 0.05) . Conclusion Ultrasonography is, to a certain extent, valuable in the diagnosis of PWS. Key words: Port-wine stain; Ultrasonography; Diagnosis, differenctial

Activation of PKCα and PI3K Kinases in Hypertrophic and Nodular Port Wine Stain Lesions.

:Port wine stain (PWS) is a congenital, progressive vascular malformation. Many patients with PWS develop hypertrophy and discrete nodularity during their adult life, but the mechanism(s) remain incompletely understood. In this study, we attempted to investigate activation status of PKCα, PI3K, PDPK1 and PLC-γ and protein levels of PP2A and DAG to explore their potential roles in the formation of hypertrophic and nodular PWS lesions. We found phosphorylated levels of PKCα, PI3K, PDPK1, and PLC-γ and protein levels of PP2A and DAG showed moderate increases in the endothelial cells of hypertrophic PWS as compared to the adjacent normal skin. These increases extended throughout the entire stroma of blood vessels in PWS nodules. Many proliferating cells, such as fibroblasts, also showed strong activation of PKCα, PI3K, PDPK1 and PLC-γ and upregulations of PP2A and DAG in nodular PWS lesions. Our data showed that there is aberrant activation of PKCα, PI3K, PDPK1 and PLC-γ and upregulation of PP2A and DAG mainly in endothelial cells in hypertrophic PWS areas, but presenting in the entire vasculatures and surrounding fibroblasts in PWS nodules. Our data suggest that both PKCα and PI3K signaling pathways contribute to the development of hypertrophy and nodularity in adult PWS.

Alexandrite Laser for the Treatment of Resistant and Hypertrophic Port Wine Stains: A Clinical, Histological and Histochemical Study

BackgroundPort wine stains (PWSs) are commonly treated by the pulsed dye laser. However, treatment of hypertrophic or resistant PWSs is a major therapeutic challenge. The long-pulsed Alexandrite laser could be a safe and effective treatment for resistant PWSs, due to an increase depth of penetration of 50–75% over PDL. ObjectiveThe aim of this study was to assess the efficacy and safety of a long-pulsed Alexandrite laser in patients with hypertrophic, dark and/or resistant PWSs. Pink pale resistant PWS were excluded from the study. MethodsTwenty-one patients (age 20–75 years), phototypes I–IV on the Fitzpatrick scale, with PDL dark resistant PWSs were treated with long-pulsed Alexandrite laser. We excluded high phototypes and PDL pink resistant PWSs. All patients were treated with 3 laser sessions at settings of 3-ms pulse duration, 10-mm spot, 35–55J/cm2, with cooling (Dynamic Cooling Device 50ms with delay 30ms). Laser sessions were repeated approximately every 2 months. Three dermatologists evaluated treatment effectiveness by means of photographs of the patients before and after laser treatment (scale from 0 to 4). Adverse events were registered. Patient satisfaction was also assessed (scale from 0 to 10). ResultsMean global improvement was rated as 2.28. Long-lasting side effects included minimal scarring after blistering in 1 patient. Mean patient satisfaction was 8.5. ConclusionsOur study concludes that long-pulsed Alexandrite laser was effective for treatment of resistant PWSs, although the therapeutical window is narrow with this treatment.

Alexandrite Laser for the Treatment of Resistant and Hypertrophic Port Wine Stains: A Clinical, Histological and Histochemical Study

BackgroundPort wine stains (PWSs) are commonly treated by the pulsed dye laser. However, treatment of hypertrophic or resistant PWSs is a major therapeutic challenge. The long-pulsed Alexandrite laser could be a safe and effective treatment for resistant PWSs, due to an increase depth of penetration of 50–75% over PDL. ObjectiveThe aim of this study was to assess the efficacy and safety of a long-pulsed Alexandrite laser in patients with hypertrophic, dark and/or resistant PWSs. Pink pale resistant PWS were excluded from the study. MethodsTwenty-one patients (age 20–75 years), phototypes I–IV on the Fitzpatrick scale, with PDL dark resistant PWSs were treated with long-pulsed Alexandrite laser. We excluded high phototypes and PDL pink resistant PWSs. All patients were treated with 3 laser sessions at settings of 3-ms pulse duration, 10-mm spot, 35–55J/cm2, with cooling (Dynamic Cooling Device 50ms with delay 30ms). Laser sessions were repeated approximately every 2 months. Three dermatologists evaluated treatment effectiveness by means of photographs of the patients before and after laser treatment (scale from 0 to 4). Adverse events were registered. Patient satisfaction was also assessed (scale from 0 to 10). ResultsMean global improvement was rated as 2.28. Long-lasting side effects included minimal scarring after blistering in 1 patient. Mean patient satisfaction was 8.5. ConclusionsOur study concludes that long-pulsed Alexandrite laser was effective for treatment of resistant PWSs, although the therapeutical window is narrow with this treatment.

Assessment of Efficacy of the 595-nm Pulsed Dye Laser in the Treatment of Facial Port-Wine Stains in Indian Patients.

Pulsed dye lasers have revolutionized treatment of port-wine stains (PWS). The authors' previous study with a 585-nm/0.45-millisecond pulsed dye laser (PDL) showed 25% to 75% improvement in 60% of facial PWS. The authors analyzed data on facial PWS treated with a 595-nm tunable PDL in Indian patients. Response was assessed subjectively on a scale of -1 to 5 (Investigator Global Assessment) by comparing pretreatment and posttreatment photographs. Patients' perception of change in PWS was also noted on a visual analog scale from 0 to 10 (Patient Global Assessment). Side effects were recorded. A total of 74 flat and 24 hypertrophic PWS in skin Types IV and V with a median lesion size of 56 cm and 102 cm, respectively, and color ranging from pink to purple were treated. They underwent a mean of 7.3 and 8.5 sessions (range: 4-10 session), respectively. A mean lightening of 54% in flat and 40% in hypertrophic PWS was observed. After 10 treatments, 46.6% of flat PWS cases showed >75% lightening and an equal number had 25% to 75% improvement. A >75% improvement was observed in 12.5% of hypertrophic PWS with 75% of cases showing between 25% to 75% improvement. No significant side effects were noted. The 595-nm tunable PDL produced moderate response with no significant side effects.

Prognosis and response to laser treatment of early-onset hypertrophic port-wine stains (PWS)

There is limited information regarding early development of soft-tissue and/or bone hypertrophy with facial port-wine stains (PWS). We sought to characterize patients with hypertrophic PWS presenting during childhood. Patients with a facial PWS and underlying hypertrophy that developed before the age of 18years were included in a multicenter retrospective study. Age at onset of the hypertrophy, its location, association with odontologic problems, presence of other associated complications, and response to laser treatment were recorded. A total of 98 patients were included. The mean age at onset of hypertrophy, retrieved for 77 of 98 patients, was 5.6years. The hypertrophy was congenital in 26%. Odontologic problems were noted in 39.8% of cases. Other complications, including cataract, asymmetric development of the maxillary bone, and speech delay/disorders, were reported in 18.4%. In all, 67 patients received laser treatment. Only 3% achieved complete or nearly complete clearance of the PWS. As only cases of PWS with early-onset hypertrophy were included, we were unable to calculate the prevalence of this manifestation. PWS with early-onset hypertrophy are associated with a high rate of complications and a poor response to laser treatment. Periodic monitoring is recommended for early detection and treatment of complications.

Analysis of hypertrophy-related factors in 82 adult patients with hypertrophic port-wine stains

Objective To analyze clinical features of and hypertrophy-related factors in patients with hypertrophic port-wine stains (PWS). Methods Patients with PWS were enrolled into this study from Anhui Provincial Hospital and the First Affiliated Hospital of Anhui Medical University between January 2010 and August 2014. Clinical features of hypertrophic PWS were investigated. The factors related to hypertrophy in PWS were analyzed by univariate and multivariate unconditional logistic regression analyses. Results A total of 262 patients with PWS were enrolled, 82 (30 males and 52 females) of whom had hypertrophic PWS with a median age of 32.5 years (range, 18-54 years). Among the 82 patients, 66 (80.48%) had plaque-like hypertrophic PWS, 9 (10.98%) had papular or nodular type, and 7 (8.54%) had mixed type; 56.10% (46/82) were aged ≥ 30 years, 41.46% (34/82) varied from 11 to 30 cm2 in lesional area, and 85.36% (70/82) showed purple lesions. There was a significant difference between patients with hypertrophic PWS and those with flat PWS in the distribution of age, lesional area and color (χ2=25.559, 10.580, 90.630, respectively, all P 0.05). Multivariate unconditional logistic regression analysis revealed that an age ≥ 30 years (OR=2.889, 95% CI: 1.459-5.721) and purple lesions (OR=19.984, 95% CI: 5.704-70.023) were factors related to skin hypertrophy in PWS. Conclusion An age ≥ 30 years and purple lesions seem to be hypertrophy-related factors in PWS. Key words: Port-wine stain; Risk factors; Causality; Hypertrophy

Sustained activation of c-Jun N-terminal and extracellular signal-regulated kinases in port-wine stain blood vessels

Port-wine stain (PWS) is a congenital, progressive vascular malformation but the pathogenesis remains incompletely understood. We sought to investigate the activation status of various kinases, including extracellular signal-regulated kinase, c-Jun N-terminal kinase, AKT, phosphatidylinositol 3-kinase, P70 ribosomal S6 kinase, and phosphoinositide phospholipase C γ subunit, in PWS biopsy tissues. Immunohistochemistry was performed on 19 skin biopsy samples from 11 patients with PWS. c-Jun N-terminal kinase, extracellular signal-regulated kinase, and P70 ribosomal S6 kinase in pediatric and adult PWS blood vessels were consecutively activated. Activation of AKT and phosphatidylinositol 3-kinase was found in many adult hypertrophic PWS blood vessels but not in infants. Phosphoinositide phospholipase C γ subunit showed strong activation in nodular PWS blood vessels. Infantile PWS sample size was small. Our data suggest a subsequent activation profile of various kinases during different stages of PWS: (1) c-Jun N-terminal and extracellular signal-regulated kinases are firstly and consecutively activated in all PWS tissues, which may contribute to both the pathogenesis and progressive development of PWS; (2) AKT and phosphatidylinositol 3-kinase are subsequently activated, and are involved in the hypertrophic development of PWS blood vessels; and (3) phosphoinositide phospholipase C γ subunit is activated in themost advanced stage of PWS and may participate in nodular formation.

Lasers for Dermatology and Skin Biology

Popular media initially portrayed lasers, the brightest light sources in the known universe, as a ‘‘death ray’’. Instead, lasers became minimally destructive, precise, versatile surgical tools that also enabled a revolution in biological sciences through live-tissue microscopy. How did that happen, and what might come next? It turns out that laser capabilities—impressive optical power density, collimation, coherence, well-defined wavelength, and impressively brief pulses—are better suited for gentle precision than for wanton destruction. This trend has been going strong for 30 years and shows no signs of slowing down. The need for a better treatment of port wine stains (PWS) led us to hatch the concept of ‘‘selective photothermolysis’’ (SP) (Anderson and Parrish, 1983), which became the basis for many new therapeutic lasers. Light passes harmlessly through space and matter until it is absorbed. It stands to reason that heating (and other events caused by light) begins when and where the light is absorbed. Skin contains specific structures with a high concentration of light-absorbing molecules (chromophores), such as the abnormal blood vessels of PWS. Intense pulses of light at wavelengths preferentially absorbed in these ‘‘target’’ structures can cause selective thermal damage. We showed this for microvessels in skin using yellow light pulses and for melanin-pigmented cells using UV light pulses. For the best selectivity, heat should be confined to the target during the light pulse. In other words, pulse duration should be about equal to the time it takes for cooling the target. Thermal relaxation time turns out to vary with the square of target size. For targets ranging from subcellular particles (nm scale) to multicellular structures (mm scale), thermal relaxation time varies a million-fold, from nanoseconds to milliseconds. These simple ideas led to a burst of new applications for nonscarring, pulsed lasers over a wide range of pulse duration and wavelength, including lasers that did not previously exist. Millisecond pulsed dye lasers (PDLs) for treating microvascular malformations are the first example of any laser specifically invented for a medical need, and they remain the treatment of choice for neonatal and childhood PWS (Chapas et al., 2007). The latest generation of PDLs has variable pulse duration to match various target vessel sizes, and uses dynamic cryogen spray cooling for epidermal protection in pigmented skin. However, PWS treatment remains challenging because a residual vascular lesion almost always persists. Three reasons are hypothesized to account for persistence of PWS—(a) angiogenesis produces new PWS vessels after each laser treatment, (b) insufficient depth of PDL treatment, and (c) an intrinsic lack of sympathetic innervation. These might be overcome. The first report of combined PDL plus the angiogenesis inhibitor drug rapamycin (Nelson et al., 2011)—and for adults with hypertrophic PWS, the use of deeply penetrating nearinfrared wavelengths—is highly effective (Izikson et al., 2009). PWS being microvenous lesions, in theory a source could be made that targets de-oxyhemoglobin, sparing the arterial circulation (Rubin et al., 2012). Other indications for PDLs and their cousin technologies include rosacea, scars, ulcerated infantile hemangioma, warts, and laryngeal lesions including carcinomas. The precision with which very short (nanosecond 10 9 s, or shorter) pulses can target individual pigmented cells or organelles is impressive. In our initial investigation of SP, we found that even Langerhans cells adjacent to pigmented epidermal cells were unaffected. Ophthalmology subsequently developed this as a successful treatment for early-stage glaucoma, targeting pigmented cells in the trabecular meshwork (Latina et al., 1998). In dermatology, Q-switched red and near-infrared lasers proved to be excellent for treating some melanocytoses such as nevus of Ota, useful for cafeau-lait macules and lentigines, but generally a failure for other conditions such as Becker’s nevi. As one might expect, the biology of particular pigmented skin lesions critically affects their response to laser treatment. The pigmented, well-differentiated dermal melanocytes of nevus of Ota are easily removed by Q-switched ruby, alexandrite, or Nd:YAG laser treatment (Taylor et al., 1991). In contrast, congenital melanocytic nevi include both pigmented and nonpigmented melanocytes at various levels of differentiation. Surgical excision is the preferred treatment, and lasers offer a useful alternative only in some cases. Other fascinating aspects of laser targeting of melanocytes have never been developed. For example, sublethal fluences from these Q-switched lasers stimulate melanogenesis and tanning of the skin. Tattoos are a poorly regulated form of ancient nanotechnology. Insoluble,

Long‐pulsed 1064 nm Nd:YAG laser improves hypertrophic port‐wine stains

Hypertrophic port-wine stains (PWS) usually respond poorly to pulsed dye laser treatment. The long-pulsed 1064 nm Nd:YAG laser can target deeper situated vessels and may therefore be more effective. To evaluate the efficacy and safety of the Nd:YAG laser for the treatment of hypertrophic PWS. In a retrospective cohort study, all hypertrophic PWS patients treated with the Nd:YAG laser between 2005 and 2011 were invited for follow-up. Clinical improvement was assessed using Physician Global Assessment (PhGA) and Patient Global Assessment (PGA). Assessment was obtained in 32 of 44 eligible patients (mean age 51.4 years), after a mean of 2.8 (SD ± 2.1) Nd:YAG laser treatments. Good or excellent improvement of hypertrophy was found in a majority of patients, both by PhGA (91%) and PGA (93%). Good or excellent improvement of colour was found in 63% of patients by PhGA, and in 87% by PGA. Recurrence of hypertrophy was seen in three patients. All but two patients would recommend Nd:YAG treatment to other patients. Mild to moderate scars were seen in seven patients, hypopigmentation in 14 patients. The 1064 nm Nd:YAG laser is highly effective in the treatment of hypertrophic PWS with only a few treatments needed. Mostly mild side effects were seen in half of all patients. Hypertrophy seems to respond better than colour. To further improve colour, a combination with pulsed dye laser treatment is advisory. Observation of immediate clinical endpoints is important when using the Nd:YAG laser, to optimize outcomes and reduce side effects.

Hypertrophy in port-wine stains: Prevalence and patient characteristics in a large patient cohort

Port-wine stains (PWS) may thicken and darken with age. Little is known about the pathogenesis and epidemiology of PWS hypertrophy because of the lack of large studies. We sought to assess the prevalence and characteristics of patients with hypertrophic PWS. Medical records and clinical photographs of all patients with PWS visiting our clinic between 2005 and 2009 were examined to identify hypertrophy. Patients were sent questionnaires regarding their hypertrophic PWS. In all, 335 patients (age 0-81 years; 69% female) with PWS were included. Hypertrophy was found in 68 patients (20%; 32 male, 36 female) and classified as thickened (5%), nodular (8%), or both (7%). Color of hypertrophic PWS was mainly red (50%) or purple (44%). Patients with hypertrophy in their PWS were mostly (68%) older than 40 years, and rarely (7%) younger than 20 years. When older than 50 years, 71% of all patients had hypertrophy in their PWS. Median age of onset of PWS hypertrophy was 31 years (12 years for thickened, 39 years for nodular). This was a retrospective study in a selected population. Hypertrophy is an important feature in the development of PWS and affects a majority of patients older than 50 years. Depth of color of the PWS is associated with hypertrophy, whereas location and size appear not to be related. More attention should be drawn to therapy and prevention of hypertrophic PWS. Diffuse thickening and nodules should be distinguished, as a different age of onset may indicate different pathomechanisms.

Alexandrite Laser for the Treatment of Port Wine Stains Refractory to Pulsed Dye Laser

The 755-nm ms pulsed Alexandrite laser (MSPAL) has been reported to be successfully in the treatment of port wine stains (PWS) that are refractory to pulsed dye laser (PDL). This was a prospective pilot study to assess the degree of improvement after a series of treatments with a MSPAL for hypertrophic, nodular, and macular PWS refractory to PDL. Treatment was administered to the PWS using the 755-nm MSPAL at settings of 3-ms pulse duration, 8- to 12-mm spot, 40 to 60 J/cm(2), and dynamic cooling of 60/40. Patients received a series of two to four treatment session, given at 6- to 8-week intervals. The eight patients in this study had undergone a mean of 25.9 treatment sessions with PDL over 8.8 years. The number of MSPAL sessions required for significant improvement of PWS ranged from two to four (mean 2.6). From before treatment to 2 months after treatment, the mean score decreased from 3.2 to 1.4 for skin color (56.3% mean improvement, 95% confidence interval (CI)=53.2-59.4%), from 2.5 to 1.0 at (60.0% mean improvement, 95% CI=55.9-64.1%) for skin texture, and from 3.2 to 1.3 (59.4% mean improvement, 95% CI=56.2-62.6%) for overall cosmetic outcome (all p<.05). In this pilot study, PDL-resistant PWS responded significantly to a series of MSPAL treatments. Given the potential for adverse effects and narrow therapeutic index, treatment with conservative parameters and close observation of tissue response are essential.

Treatment of hypertrophic and resistant port wine stains with a 755 nm laser: A case series of 20 patients

Port wine stains (PWS) are heterogeneous vascular malformations that can be treated with vascular-selective pulsed dye lasers (PDL). Hypertrophic PWS, especially in adults, are consistently less responsive to PDL. Furthermore, many PWS that respond well initially to PDL treatment may reach a response plateau, becoming unresponsive to further PDL treatments, a phenomenon termed "treatment resistance." Based on the theory of selective photothermolysis, vessels in such lesions may also be specifically targeted with a 755 nm laser that has selectivity for deoxyhemoglobin as well as oxyhemoglobin and increased depth of skin penetration. Retrospective case review of 20 patients with either hypertrophic or PDL-resistant PWS treated with a 755 nm laser alone or in combination with other lasers, including PDL. Hypertrophic PWS showed significant lightening after treatment with a 755 nm laser in combination with PDL. Most PDL-resistant PWS showed moderate improvement after treatment with either a 755 nm laser alone or in combination with another laser, including PDL. Some lesions showed only mild improvement or did not respond. Serious side effects were infrequent. Most commonly encountered complications included pain, edema, bullae, crusting, and rare scarring. Alexandrite 755 nm laser can be useful for the treatment of hypertrophic and treatment-resistant PWS in adult and pediatric patients. Complications are infrequent and predictable. Careful attention to using a fluence at or near the threshold for clinical response with this deeply penetrating laser is essential to prevent serious sequelae.

Combined 595-nm and 1,064-nm Laser Irradiation of Recalcitrant and Hypertrophic Port-Wine Stains in Children and Adults

Although pulsed dye laser (PDL) treatment of port-wine stain (PWS) has long been proven safe and effective, incomplete clearance of these vascular malformations can be problematic. In addition, advanced PWS with deeper coloration and tissue hypertrophy can be particularly difficult to treat because of the superficial dermal penetration of 585- to 595-nm light. The purpose of this study was to evaluate the safety and efficacy of a novel device that delivers sequential pulses of 595- and 1,064-nm wavelengths in the treatment of recalcitrant and hypertrophic PWS. Twenty-five children and adults (skin phototypes I-III) with recalcitrant or hypertrophic PWS showing incomplete clearance after 10 prior PDL treatments were included in the study. Successive treatments using a 595-nm PDL and a 1,064-nm neodymium-doped yttrium-aluminum-garnet (Nd:YAG) laser were delivered at 6- to 8-week intervals. Two masked assessors determined clinical improvement of treatment areas using independent evaluation of comparative photographs at baseline and 3 months after treatment using a standard quartile grading scale. The use of dual 595-/1,064-nm wavelengths provided continued improvement of PWS that were previously recalcitrant to ongoing PDL therapy. Side effects were limited to transient erythema, edema, and mild purpura. Rare vesicle formation was observed, with no subsequent scarring or undesirable pigmentary changes. The novel dual 595-nm PDL and 1,064-nm Nd:YAG laser is an effective treatment for PWS that are recalcitrant to PDL therapy alone.