Skin Microvessels Research Articles

Wavelet-analysis of skin temperature oscillations during local heating for revealing endothelial dysfunction

Skin microvessels have proven to be a model to investigate the mechanisms of vascular disease; in particular, endothelial dysfunction. To analyze skin blood flow, high-resolution thermometry can be used because low-amplitude skin temperature oscillations are caused by changes in the tone of skin vessels. The aim of our study was to test the possibilities of wavelet analysis of skin temperature (WAST) for the diagnosis of impaired regulation of microvascular tone in patients with type 2 diabetes. A local heating functional test was used for the assessment of microvascular tone regulation. A control group consisted of healthy male and female volunteers (n=5 each), aged 39.1±5.3years. A group of patients with type 2 diabetes comprised thirteen people, seven men and six women, aged 36 to 51years old (43.2±3.4years). The diagnosis of diabetes was made according to the criteria of the World Health Organization (WHO). The mean disease duration was 7.36±0.88years. Skin temperature oscillations, reflecting intrinsic myogenic activity (0.05–0.14Hz), neurogenic factors (0.02–0.05Hz) and endothelial activity (0.0095–0.02Hz) increase greatly during local heating for healthy subjects. In the group of patients with type 2 diabetes, no statistically significant differences in the amplitudes in the endothelial range were observed. Relative changes in the oscillation amplitudes in patients with type 2 diabetes were markedly lower compared to the control group. The latter indicates that the WAST method enables assessment of the state of vascular tone and the effects of mechanisms responsible for regulation of blood flow in the microvasculature.

Prognostic significance of endothelial dysfunctional markers of the first stage of chronic kidney disease

Non-adaptive remodeling of cardiovascular system and progressive kidney damage at chronic kidney disease (CKD) is associated with the development of endothelial dysfunction (ED) and apoptosis. The aim of this research was to study the changes of indicators of apoptosis and ED in patients with CKD 1 stage throughout 12 months. Complex biochemical, immunoferment and tool methods were applied at patient examinations. Arterial pressure of all observed patients was resolved on target values in 12 months. However, the indicators of endothelium-dependent vasodilation (EDV) increased in 55 patients (1st group), and the peak of circulating blood volume in skin microvessels in 22 patients (2nd group) wasn't changed: 134±4 % и 136±4 %, p>0.1. The level of the annexin A5 reduced from 3.5±0.47 to 1.27±0.31 ng/ml (p 0.1 in 2nd group. Diurnal excretion of sodium chloride decreased from 6.8±0.57 g/d to 2.8±0.39 g/d (p<0.05) in patients of 1st group. Dynamics of these indicators was not marked in patients of 2nd group: accordingly from 7.39±0.63 g/d to 7.01±0.65 g/d. Diurnal excretion of sodium chloride reflected the salt intake in patients with CKD 1 stage is associated with disturbance of endothelial-dependent vasodilation and apoptosis.

Abstract 4504: Urokinase plasminogen activator-dependent tumor penetrating peptide

Abstract Activity of tumor penetrating peptides depends on C-end Rule (CendR) peptide motif (R/KXXR/K) that must be C-terminally exposed for tissue and cell penetration. We describe here a cryptic CendR peptide (uCendR; amino acid sequence: RPARSGR↓SAGGSVA) that is proteolytically activated by urokinase-type plasminogen activator (uPA), a protease overexpressed in human tumors. uPA cleavage unmasks the cryptic CendR element of uCendR peptide and triggers its binding and internalization to the neuropilin-expressing cultured cancer cells. Intradermally injected post-cleavage mimic of uCendR peptide (RPARSGR) increases permeability of skin microvessels to tracer compounds. Phage and silver nanoparticles functionalized with uCendR peptide in combination with angiogenic integrin-recruitment motif (CRGDC) home to tumor blood vessels, extravasate, and trigger vascular exit of co-injected tracer compounds. This study shows that modular tumor penetrating peptides that are specifically activated by a tumor derived protease can be developed for tumor-targeted drug delivery. Citation Format: Tambet Teesalu, Kazuki N. Sugahara, Gary B. Braun, Venkata Ramana Kotamraju, Erkki Ruoslahti. Urokinase plasminogen activator-dependent tumor penetrating peptide. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 4504. doi:10.1158/1538-7445.AM2014-4504

Functional and structural abnormalities of the skin microcirculation in hemodialysis patients

The changes that occur at the level of the skin microvessels reflect changes at other microvessels including the cardiac microvessels. Several disease states seem to alter skin microvascular function and structure such as diabetes, hypertension, and hypercholesterolemia. Many of these disease states are frequently encountered in hemodialysis (Hdx) patients. The process of Hdx itself is also associated with vascular abnormalities. It was thus the aim of our study to examine the structure and function of skin microcirculation in Hdx patients. Sixty patients were examined: 20 patients on regular Hdx, younger than 60 years old, with no diabetes, hypertension, or hypercholesterolemia, 20 patients on regular hemodialysis with coexisting hypertension (Htn-Hdx), and 20 young healthy volunteers. The skin microcirculation was assessed using the laser Doppler fluxmetry and the capillaroscope. Results showed significant differences in the laser Doppler fluxmetry measurements between the Hdx group and the Htn-Hdx group compared with the control group, with no significant differences in the capillaroscope study. The study of skin microcirculation in Hdx patients indicated the presence of functional abnormalities without significant structural changes.

Characteristics of functional state of arteriolar and venular skin microvessels in patients with essential arterial hypertension

The aim of the study was to evaluate the vasomotor activity of skin precapillary arterioles, depending on the condition of blood outflow from the capillary bed in patients with essential arterial hypertension (AH). The study included 30 normotensive subjects (NT) and 63 patients with AH, who were tested with a laser Doppler flowmetry with wavelet analysis of blood flow oscillations on the right forearm and ambulatory blood pressure monitoring (ABPM) on the left shoulder. Antihypertensive therapy was stopped for all patients 14days prior to the experiment or AH was diagnosed for the first time. The hypertensive patients were divided into 2 groups, depending on the amplitude of the respiratory blood flow oscillations in skin microvessels. The first group included 30 patients without blood outflow violations of the capillary bed (AHVN), the second group consisted of 33 patients with various intensity of functional disorders in venular sector of microvasculature (AHVS). If the value of the amplitude of blood flow oscillations can be related to the tone” definition, then AHVN patients have a significant increase in neurogenic component of vascular tone (p<0.002) and violation of microvessel vasomotor endothelial function (p=0.065) in regard to NT, and AHVS patients to NT have a significant reduction of myogenic component tone of precapillary arterioles (p<0.05). AHVN patients compared to AHVS patients have a higher precapillary arteriolar tone due to endothelial (p<0.01), neurogenic (p<0.01) and myogenic (p<0.01) components of the vascular tone. Despite the lower values of the precapillary arteriolar tone, AHVS patients have higher BP values both at daytime (p<0.0005), and in nocturnal hours (p<0.05), and the functional state of venular sector is connected with nocturnal BP reduction. Obtained results indicate that hypertensive patients can have significant differences in the functional state of microvessels. The assessment of the initial skin microvasculatory regulatory mechanism status could potentially be useful for individual choice of antihypertensive therapy.

The effect of L-arginine on microvascular reactivity in normotensive subjects with a family history of hypertension

Background : An increasing number of studies support the hypothesis that endothelial dysfunction due to reduced availability of nitric oxide plays a key role in initiation, development and progression of essential hypertension. The aim of our study was to determine whether the ingestion of L-arginine actually improves microvascular function in normotensive subjects with a family history of hypertension. Methods : 30 normotensive healthy men, aged 20–30 years, were divided into two groups according to the family history of hypertension. We measured ECG, heart rate, systolic and diastolic arterial pressure, cardiac output, stroke volume, total peripheral resistance (Task Force Monitor) and laser Doppler (LD) flux in the microvessels of the skin on the forearm at rest, before and after the administration of 0.9 g L-arginine. The endothelium-dependent vasodilation was assessed by iontophoresis of acetylcholine and the endothelium-independent vasodilation by iontophoresis of sodium nitroprusside. Results : After the ingestion of L-arginine the heart rate and the cardiac output statistically significantly decreased in both groups (paired t-test, p < 0.05). Arterial pressure did not change significantly. Stroke volume decreased and total peripheral resistance increased only in the group of subjects with a family history of hypertension (paired t-test, p < 0.05) The ingestion of L-arginine in predisposed normotensive subjects acutely improved the endothelium-dependent vasodilation (Dunnett’s test, p < 0.05), which is consistent with the assumption that endothelial dysfunction is already present in these subjects. Conclusions : In subjects with a family history of hypertension L-arginine improved endothelial function. This justifies L-arginine as a potential agent for the prevention and/or treatment of arterial hypertension.

Xanthohumol Modulates Inflammation, Oxidative Stress, and Angiogenesis in Type 1 Diabetic Rat Skin Wound Healing

Type 1 diabetes mellitus is responsible for metabolic dysfunction, accompanied by chronic inflammation, oxidative stress, and endothelium dysfunction, and is often associated with impaired wound healing. Phenol-rich food improves vascular function, contributing to diabetes prevention. This study has evaluated the effect of phenol-rich beverage consumption in diabetic rats on wound healing, through angiogenesis, inflammation, and oxidative stress modulation. A wound-healing assay was performed in streptozotocin-induced diabetic Wistar rats drinking water, 5% ethanol, and stout beer with and without 10 mg/L xanthohumol (1), for a five-week period. Wounded skin microvessel density was reduced to normal values upon consumption of 1 in diabetic rats, being accompanied by decreased serum VEGF-A and inflammatory markers (IL-1β, NO, N-acetylglucosaminidase). Systemic glutathione and kidney and liver H2O2, 3-nitrotyrosine, and protein carbonylation also decreased to healthy levels after treatment with 1, implying an improvement in oxidative stress status. These findings suggest that consumption of xanthohumol (1) by diabetic animals consistently decreases inflammation and oxidative stress, allowing neovascularization control and improving diabetic wound healing.

Is the Effect of Mobile Phone Radiofrequency Waves on Human Skin Perfusion Non‐Thermal?

To establish whether SkBF can be modified by exposure to the radiofrequency waves emitted by a mobile phone when the latter is held against the jaw and ear. Variations in SkBF and Tsk in adult volunteers were simultaneously recorded with a thermostatic laser Doppler system during a 20-minute "radiofrequency" exposure session and a 20-minute "sham" session. The skin microvessels' vasodilatory reserve was assessed with a heat challenge at the end of the protocol. During the radiofrequency exposure session, SkBF increased (vs. baseline) more than during the sham exposure session. The sessions did not differ significant in terms of the Tsk time-course response. The skin microvessels' vasodilatory ability was found to be greater during radiofrequency exposure than during sham exposure. Our results reveal the existence of a specific vasodilatory effect of mobile phone radiofrequency emission on skin perfusion.

Decreased Expression of Serum and Microvascular Vascular Endothelial Growth Factor Receptor-2 in Meningococcal Sepsis*

To determine the skin microvessel expression of vascular endothelial growth factor receptor 2 and serum-soluble vascular endothelial growth factor receptor 2 levels in children with meningococcal sepsis. Observational study. Two tertiary academic children hospital PICUs. Children with meningococcal sepsis. Skin biopsy and blood sample collection. Determination of skin microvessel vascular endothelial growth factor receptor 2 expression in skin biopsies by immunohistochemistry and measurement of serum-soluble vascular endothelial growth factor receptor 2 by enzyme-linked immunosorbent assay. Percentage of vascular endothelial growth factor receptor 2-positive skin microvessels and the staining intensity were significantly lower in children with meningococcal sepsis (n = 10) compared to controls (7.6% ± 8.8% vs 44.6% ± 39.2%; p = 0.009 and 0.7% ± 0.7% vs 1.7% ± 1.1%; p = 0.033, respectively). In addition, circulating serum levels of soluble vascular endothelial growth factor receptor 2 were decreased in sepsis (8,148 ± 1,140 pg/mL vs 13,414 ± 2,692 pg/mL; p < 0.001). Serum-soluble vascular endothelial growth factor receptor 2 levels (n = 28) were inversely correlated with Pediatric Risk of Mortality III score (r = -0.43; p = 0.023) and more decreased in nonsurvivors compared to survivors (5,640 ± 1,940 pg/mL vs 7,378 ± 2,336 pg/mL; p = 0.037). Microvascular expression of vascular endothelial growth factor receptor 2 and serum-soluble vascular endothelial growth factor receptor 2 levels are decreased in children with sepsis. Serum-soluble vascular endothelial growth factor receptor 2 levels are inversely correlated with disease severity indicated by Pediatric Risk of Mortality III score and survival. Decreased vascular endothelial growth factor receptor 2 expression may hinder natural recovery from sepsis-associated microvascular injury and the effectiveness of therapeutic strategies targeting vascular endothelial growth factor-vascular endothelial growth factor receptor 2 signaling in sepsis patients.

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,

Adaptation Capacity of Microcirculatory Bed of the Skin under Conditions of High-Frequency Rate Fractionated Automated Tibial Elongation

The status of the microcirculatory bed in the skin in the bone regenerate projection was studied under conditions of fractionated automated tibial elongation by transosteal distraction osteosynthesis at a rate of 3 mm/day in adult mongrel dogs. Histological and physiological data indicated that the distraction period was associated with changes in the functional components of the skin microcirculatory bed. Active neovasculogenesis and formation of additional arteriovenular anastomoses provided sufficient oxygenation of tissues and maintained venous outflow. This led to rapid recovery of the functional potentialities of skin microvessels as early as 1 month after the end of forced fixation.

Effects of Polymorphisms of NOS3 and GNB3 Genes on Skin Microvascular Reactivity in Normal Pregnancy

We studied the relationship between endothelial NO-synthase gene (NOS3) and G protein β3 subunit gene (GNB3) polymorphisms and reactivity of skin microvessels during physiological gestation. T-786C NOS3 polymorphism influenced the maximum blood flow rate in skin microvessels and the severity of postocclusive reactive hyperemia during the third trimester of pregnancy. The relationship between G894T NOS3 polymorphism and the duration of postocclusive reactive hyperemia was revealed. C825T GNB3 polymorphism affects the duration and severity of postocclusive reactive hyperemia during the first and third trimesters of pregnancy. Thus, NOS3 and GNB3 polymorphisms affect blood flow in the skin microvessels during physiological gestation.

Zinc-dependent contact system activation induces vascular leakage and hypotension in rodents

Contact to polyanions induces autoactivation of the serine protease factor XII that triggers the kallikrei-kinin system. Recent studies indicate that polysaccharide-induced autoactivation of factor XII has a role in allergy-related vascular leakage, and angioedema. Here, we characterize in vivo effects of the synthetic polysaccharide dextran sulfate in human plasma and in rodent models. Minute amounts of high-molecular-weight dextran sulfate-initiated factor XII-autoactivation and triggered formation of the inflammatory mediator bradykinin via plasma kallikrein-mediated cleavage of high-molecular-weight kininogen. High-molecular-weight kininogen fragments, containing the HKH20 sequence in domain D5H, blocked dextran sulfate-initiated bradykinin-generation by depleting plasma Zn2+ ions. Topical application of high molecular weight dextran sulfate increased leakage in murine skin microvessels, in a bradykinin-dependent manner. Intravital laser scanning microscopy showed a greater than two-fold elevated and accelerated fluid extravasation in C1 esterase inhibitor deficient mice that lack the major inhibitor of factor XII, compared to wild-type controls. Intra-arterial infusion of dextran sulfate induced a rapid transient drop in arterial blood pressure in rats and preinjection of kinin B2 receptor antagonists or HKH20 peptide blunted dextran sulfate-triggered hypotensive reactions. The data characterize dextran sulfate as a potent in vivo activator of factor XII with implications for bradykinin-mediated vascular permeability and blood pressure control.

Perlecan maintains microvessel integrity in vivo and modulates their formation in vitro.

Perlecan is a heparan sulfate proteoglycan assembled into the vascular basement membranes (BMs) during vasculogenesis. In the present study we have investigated vessel formation in mice, teratomas and embryoid bodies (EBs) in the absence of perlecan. We found that perlecan was dispensable for blood vessel formation and maturation until embryonic day (E) 12.5. At later stages of development 40% of mutant embryos showed dilated microvessels in brain and skin, which ruptured and led to severe bleedings. Surprisingly, teratomas derived from perlecan-null ES cells showed efficient contribution of perlecan-deficient endothelial cells to an apparently normal tumor vasculature. However, in perlecan-deficient EBs the area occupied by an endothelial network and the number of vessel branches were significantly diminished. Addition of FGF-2 but not VEGF165 rescued the in vitro deficiency of the mutant ES cells. Furthermore, in the absence of perlecan in the EB matrix lower levels of FGFs are bound, stored and available for cell surface presentation. Altogether these findings suggest that perlecan supports the maintenance of brain and skin subendothelial BMs and promotes vasculo- and angiogenesis by modulating FGF-2 function.

Imaging of skin microvessels with optical coherence tomography: potential uses in port wine stains

The knowledge of vascular structures of port wine stains (PWSs) may be useful to select treatment doses and improve therapeutic efficacy. Biopsies are impractical to implement, therefore, it is necessary to develop non-invasive techniques for morphological evaluation. This study aimed to evaluate the application of a novel optical coherence tomography (OCT) system to characterize the vascular structures of PWSs. First, OCT images were obtained from the skin of healthy rabbit ears and compared with the histopathological images. Second, OCT was used to document the differences between PWS lesions and contralateral normal skin; the size and depth of the vascular structures of two clinical types of PWSs were measured and statistically analyzed. The dermal blood vessels of healthy rabbit ears were clearly distinguished from other tissue. There was no statistical difference between the vascular diameter or depth measured by OCT images and histopathological sections (P>0.05). The OCT images of the PWSs could be distinguished from normal skin. There was no statistical difference in the depth of vessels between the purple-type and the proliferative-type PWSs (P>0.05), while there was statistical difference in the diameter of vessels between them (P<0.01). Therefore, OCT is a promising, real-time, in vivo and non-invasive tool with which to characterize the vascular structures of PWSs.

Noninvasive estimation of human tissue respiration with wavelet-analysis of oxygen saturation and blood flow oscillations in skin microvessels

Laser Doppler flowmetry, laser spectrophotometry of oxygen saturation and fluorescence determination of NAD-H/FAD ratio were carried out at 30 humans in the upper extremity skin zones with and without arteriole-venule anastomoses (AVA). For the first time it was shown that wavelet-analysis of oxygen saturation and microvascular blood flow oscillations was an effective approach to noninvasive estimation of skin oxygen extraction (OE) and oxygen consumption rate (OC). OE = (SaO2--SvO2)/SaO2, where SaO2 (%) and SvO2(%) are the oxygen saturation of arterial and venular blood, correspondingly. If the ratio between amplitudes of cardiac rhythm (Ac, p.u.) and respiratory rhythm (Ar, p.u.) Ac/Ar < or = 1, SvO2 = SO2. In the case of Ac/Ar >1, SvO2 = SO2/(Ac/Ar). OC = Mnutr x (SaO2-SvO2) in p.u. x %O2, where Mnutr--value of nutritive perfusion (p.u.). Mnutr = M/SI, where SI--shunting index of blood flow in microvessels. The values of perfusion, OE and OC were higher in the skin with AVA than in the skin without AVA. The values of perfusion and oxygen saturation were more variable in the skin with AVA. The greatest significance for tissue metabolism have the oxygen diffused from the smallest arterioles and capillaries. The contribution increased to tissue metabolism of total perfusion and of oxygen diffused from arterioles in the conditions of tissue ischemia.

Assessment of Skin Microvascular Function and Dysfunction With Laser Speckle Contrast Imaging

In recent years, skin microcirculation has been considered an easily accessible and potentially representative vascular bed to evaluate and understand the mechanisms of microvascular function and dysfunction.1–3 Vascular dysfunction (including impaired endothelium-dependent vasodilation) induced by different pathologies is evident in the cutaneous circulation.4–7 It has been suggested that the skin microcirculation may mirror generalized systemic vascular dysfunction in magnitude and underlying mechanisms.1 Furthermore, minimally invasive skin-specific methodologies using laser systems make the cutaneous circulation a useful translational model for investigating mechanisms of skin physiology and skin pathophysiology induced either by skin disease itself or by other diseases such as vascular, rheumatologic, and pneumologic. To date, the skin has been used as a circulation model to investigate vascular mechanisms in a variety of diseased states, including hypercholesterolemia,8 Alzheimer disease,9 carpal tunnel syndrome,10 schizophrenia,11 hypertension,6 renal disease,12 type 2 diabetes,13 peripheral vascular disease,14 atherosclerotic coronary artery disease,2 heart failure,15 systemic sclerosis,16 obesity,17 primary aging,18,19 and sleep apnea.20 Assessment of skin microvascular function can be done by both invasive and noninvasive techniques. Among noninvasive techniques, laser systems are mainly used.21 The recent development of the laser speckle contrast imaging (LSCI) technique for monitoring skin microvascular function enables its use as a surrogate end point in clinical trials. LSCI allows for noncontact, real-time, and noninvasive monitoring of cutaneous blood flow changes.22,23 Recent evidence has shown that the LSCI technique dramatically reduces the variability of clinical measurements compared with laser Doppler flowmetry (LDF), making the technique a fascinating tool to facilitate microvascular studies in clinical routine.23,24 In this review, we describe …

Phosphodiesterase 4 inhibition attenuates plasma volume loss and transvascular exchange in volume expanded mice

Phosphodiesterase 4 inhibition attenuates plasma volume loss and transvascular exchange in volume expanded mice

Evaluation of the Effects of Urotensin II and Soluble Epoxide Hydrolase Inhibitor on Skin Microvessel Tone in Healthy Controls and Heart Failure Patients

Urotensin II (UII) is a potent vasoactive peptide that exerts differential effects on heart failure (HF) patients compared to health controls. However, the mechanism of action remains unclear. The role of soluble epoxide hydrolase (sEH) as a mediator of UII in the vasculature has not been explored. The aim of this study was to examine the effect of UII in the presence and absence of sEH inhibitor AUDA on skin microvessel tone in HF patients and healthy controls using iontophoresis and laser Doppler velocimetry. UII (10(-7) M) and AUDA (10(-10), 10(-7), and 10(-5) M) were administered to the forearm of participants by iontophoresis for 30 seconds. Laser Doppler velocimetry was performed for 5 minutes to measure flux through the subcutaneous blood vessels. Response (flux) was measured for 5 minutes per concentration with 25 continuous scans. UII increased flux in healthy controls by 39% (P < 0.05) and increased flux in HF patients by 6% (ns). AUDA (10(-10) and 10(-7) M) administration further decreased flux by 115% (P < 0.05) and 255% (P < 0.0001), respectively in healthy controls. In HF patients, AUDA (10(-10), 10(-7), and 10(-5) M) further increased flux by 77% (P < 0.05), 67% (P < 0.01), and 100% (P < 0.05), respectively. AUDA alone at 10(-7) M increased flux in both groups by 31% (healthy controls, P < 0.05) and 36% (HF, P < 0.01). Taken together, the presence of HF appeared to abrogate the vasodilator responsiveness of sEH inhibitor. These results suggest an important role for both UII and sEH in vascular regulation and that sEH may be involved in mediating UII effects. Furthermore, the study highlights the therapeutic potential of sEH inhibitors for the treatment of HF.

Endothelial Damage in All Types of T-Lymphocyte–Mediated Drug-Induced Eruptions

In severe drug-induced eruptions, bullous lesions can be associated with immune complex-mediated vasculitis and/or with T-lymphocyte-mediated keratinocyte apoptosis. We have recently identified endothelial cell apoptosis in severe bullous T-lymphocyte-mediated drug-induced eruptions. We assessed microvessel involvement in the whole spectrum of T-lymphocyte-mediated drug-induced eruptions. Thirty-two patients with T-lymphocyte-mediated drug-induced eruptions in 4 groups (8 cases of toxic epidermal necrolysis/Stevens-Johnson syndrome, 8 cases of drug rash with eosinophilia and systemic symptoms, 8 cases of acute generalized exanthematous pustulosis, 8 cases of drug maculopapular exanthema) and 8 healthy controls were included. On skin biopsy specimens, we performed a systematic ultrastructural study of endothelial cells, vascular walls, and inflammatory cells; a quantification of apoptotic cells, inflammatory infiltrate, and immune complex deposits; and we assessed granzyme-B, tumor necrosis factor, and Fas ligand expression. Correlations of apoptosis with clinical data of skin lesions and systemic involvement in liver, kidney, lung, and lymph nodes were then assessed. Findings from ultrastructural study showed that endothelial cell apoptosis was present in all 32 drug-induced eruptions. No leukocytoclastic vasculitis was associated. Granzyme-B and tumor necrosis factor were expressed around microvessels. In toxic epidermal necrolysis/Stevens-Johnson syndrome and drug rash with eosinophilia and systemic symptoms, the number of apoptotic endothelial cells was related to the extension of skin lesions and the presence of purpura. It was also related to liver and kidney involvement. Endothelial apoptosis occurs in skin microvessels of all types of T-lymphocyte-mediated drug-induced eruptions. This skin endothelial cell damage is related to the severity of skin lesions and systemic involvement.