In vivo study of human skin using pulsed terahertz radiation

Elevated YAP and Its Downstream Targets CCN1 and CCN2 in Basal Cell Carcinoma: Impact on Keratinocyte Proliferation and Stromal Cell Activation

Studies in terahertz (THz) imaging have revealed a significant difference between skin cancer (basal cell carcinoma) and healthy tissue. Since water has strong absorptions at THz frequencies and tumor affects the water content of tissue, a likely contrast mechanism is variation in water content. Modeling the propagation of a THz pulse through water is the first step toward understanding the origin of contrast in terahertz pulsed images of skin cancer. In this letter, we develop a finite-difference-time-domain simulation to model the propagation of a THz pulse and incorporate double Debye theory to model the behavior of water subject to THz radiation. Furthermore, we apply this model to skin.

Studies in terahertz (THz) imaging have revealed a difference between diseased and healthy tissue in the THz regime. Since water has strong absorptions at THz frequencies, a likely contributing factor to the contrast mechanism is variation in water content. We have previously modelled the propagation of a THz waveform through water and normal skin in the time domain. In these preliminary results, we extract the complex dielectric coefficients from THz spectroscopy measurements of diseased tissue and predict the waveform differences which have been seen in THz images of skin cancer.

We have analysed the expression and distribution of the DNA mismatch repair enzyme hMSH-2 in normal skin and basal cell carcinomas. hMSH-2 protein was investigated immunohistochemically (normal human skin: n = 10; basal cell carcinomas: n = 16) on frozen sections using a highly sensitive streptavidin-peroxidase technique and a specific mouse monoclonal antibody (clone FE11). In normal human skin, we found nuclear immunoreactivity for hMSH-2 in epidermal keratinocytes of the basal and first 1-3 suprabasal cell layers. All basal cell carcinomas analysed revealed strong nuclear imunoreactivity that was pronounced in peripheral tumour cells and cells of the palisade. Expression of hMSH-2 protein was consistently and strongly upregulated in tumour cells of the carcinomas as compared to adjacent unaffected epidermis or epidermis of normal human skin. Twelve of the sixteen carcinomas analysed revealed no visual correlation in comparing the labelling patterns for hMSH-2 with the labelling pattern for the proliferation marker Ki-67. Our findings indicate that (a) hMSH-2 is expressed in human epidermal keratinocytes, predominantly in lower cell layers of the viable epidermis; (b) expression of hMSH-2 protein is strongly upregulated in basal cell carcinomas as compared to unaffected epidermis; (c) the level of hMSH-2 proteins in the carcinomas is not exclusively regulated by the proliferative activity of these tumour cells; (d) inactivating mutations of the hMSH-2 gene may in the carcinomas not be involved in the carcinogenesis or microsatellite instability secondary to replication errors; (e) expression of hMSH-2 may be of importance for the genetic stability of basal cell carcinomas in vivo.

Investigations of pruritogenic substances in humans have involved intradermal injections in normal skin; itching of inflamed skin has been little studied. To develop an itch model with provocation of itch in experimentally inflamed skin as well as in normal skin, using subjects as self-controls. In 32 non-atopic volunteers aged 21-30 years, the skin of five selected test sites on one volar forearm was pretreated for 24 h with large Finn chambers containing 1% sodium lauryl sulphate (SLS) used as a standard contact irritant to induce inflammation. Twenty microlitres of different pruritogenic substances [histamine, substance P, neurokinin A, neurokinin B, trypsin, platelet-activating factor (PAF) and serotonin] and saline as control were injected intradermally into the inflamed test sites and in corresponding non-treated sites on the opposite forearm. The test individuals scored itch intensity on a visual analogue scale for 20 min, and weal area was then measured. : Histamine and substance P induced itch in both normal and inflamed skin compared with a saline reference. Neurokinin A, trypsin, PAF and serotonin only elicited itch in normal skin, and neurokinin B neither elicited itch in normal skin nor in inflamed skin. Itch was induced in normal and SLS-inflamed skin to a similar magnitude. However, weal area after histamine was significantly (P < 0.001) larger in inflamed skin when compared with normal skin. Histamine and substance P elicited itch to the same degree in normal skin and inflamed skin pretreated with SLS despite a stronger weal response in inflamed skin. Mediators present in inflamed skin did not potentiate itch, a c-fibre-mediated neuronal response. The weal reaction is based on enhanced vascular permeability (protein extravasation). A greater skin perfusion in inflamed skin may therefore have increased the weal size. We propose an experimental model in humans for testing of itch involving both normal and inflamed skin. The model has the potential for use in evaluating new topical and systemic treatments of itch.

The basal cell adhesion molecule (B-CAM) is a 90-kD cell surface glycoprotein with a characteristic immunoglobulin domain structure. The pattern of B-CAM expression in cultured cells suggests that the molecule is associated with a substrate-adherent growth pattern in some lineages. We investigated the expression of B-CAM in normal and diseased human epidermis by means of immunohistochemistry employing a single batch of high-titer mouse monoclonal antibody G253. Snap-frozen biopsy material from normal skin (n = 8), psoriasis (n = 5), contact dermatitis (n = 6), basal cell carcinoma (n = 5) and fetal skin (n = 6) was studied. In normal human skin, B-CAM was found in varying degrees throughout the epidermis with a preference for suprabasal expression, hair follicles were regularly of a B-CAM-positive phenotype. There were no qualitative differences with regard to the B-CAM expression pattern in normal skin in comparison to psoriasis and contact dermatitis. In contrast, fetal skin (15th to 18th week of gestation) was characterized by B-CAM-positive cells in the basal layer of the epidermis as well as in the outer root sheath of hair follicles. Basal cell carcinomas also regularly expressed high levels of B-CAM. A strong B-CAM-positive phenotype can be found in the outer root sheath of hair follicles of adult and fetal human skin as well as in fetal basal keratinocytes.

Altered Immunohistochemical Expression of Small Proteoglycans in the Tumor Tissue and Stroma of Basal Cell Carcinoma

Aberrant expression patterns of nuclear lamins have been described in various types of cancer depending on the subtype of cancer, its aggressiveness, proliferative capacity and degree of differentiation. In general, the expression of A-type lamins (lamins A and C) has been correlated with a non-proliferating, differentiated state of cells and tissues. To establish and compare the expression patterns of lamins in normal human skin, actinic keratosis (AK), squamous cell carcinoma (SCC) and basal cell carcinoma (BCC). Expression patterns of the individual lamin subtypes were studied immunohistochemically. The proliferation capacity of the tumour cells was detected using a specific antibody to Ki-67, and was related to the A-type lamin expression patterns. In normal skin, lamin A was expressed in the suprabasal cell compartment of the epidermis, whereas the basal cells were mostly unstained. BCCs and SCCs stained positive in most cells, while the epidermis overlying BCC and SCC and the epidermis in AK stained homogeneously and strongly in the basal cells in addition to the suprabasal cells. Lamin C was expressed in some basal cells of normal epidermis while the suprabasal cells stained strongly positive. Both BCCs and SCCs stained strongly positive for lamin C, with the difference that in BCC the staining was predominantly present in nucleolar structures with occasional staining of the nuclear envelope. The epidermis overlying SCC showed strong positivity in the lamina of virtually all cells. The expression of lamin C in the basal cells of AK resembled the expression pattern seen in the epidermis overlying BCC, i.e. a nucleolar staining next to nuclear envelope staining. Lamin B1 and B2 were found in virtually all cells in normal epidermis, AK, BCC, SCC and the epidermis overlying cancer. The percentage of Ki-67-expressing cells was highest in BCC (45%), and gradually decreased via epidermis overlying BCC, AK, SCC, and epidermis overlying SCC, to normal skin (11%). Simultaneous expression of A-type lamins and Ki-67 occurred in approximately 50% of the proliferating (Ki-67 positive) cells in BCC and SCC. Significant changes occur in the expression patterns of A-type lamins in both premalignant and malignant lesions of the skin. The profound overlap of lamin A and Ki-67 staining patterns indicates that the proliferating tumour cells may obtain a certain degree of differentiation. Finally, lamin A expression in the basal cell layer of the apparently normal epidermis overlying BCC may suggest its involvement in the primary process.

Plasmon like excitation is observed at the interface between one-dimensional periodic array of air holes in silicon (Si) with ferroelectric polyvinylidene fluoride (PVDF) as a substrate to obtain subwavelength confinement of surface Plasmon modes at terahertz (THz) frequencies. A truly Plasmonic TM mode is obtained confined at the interface of PVDF layer and the 1D perforated dielectric slab and the mode field distribution of the structure is demonstrated using three dimensional (3D) Finite Difference Time domain Method (FDTD) method. It is shown that PVDF are promising materials for strongly confined THz wave propagation in Surface Plasmon photonic crystal. The transmission, confinement and hence the propagation length of the plasmonpolariton like terahertz surface modes sustained by the structure are studied using Finite difference time domain (FDTD) method. Further, the propagation characteristics of surface Plasmon polariton (SPP) which can be controlled by the structure geometry is discussed.

The double-pulse labeling technique for DNA fiber autoradiography was applied to epidermal cells from normal human skin and from human basal cell carcinoma (BCC). We aimed to measure the size and replication rate of the replication unit (RU) for both types of cell and to account, from these results, for our previous observation of a near doubling of S-phase duration in BCC, compared with normal skin. The mean RU size was 76 +/- 4 micron in BCC, not significantly different from the 68 +/- 6 micron value found in normal skin, so the mean of those two values (i.e., 72 micron), was used in further calculations. The rate of replication fork progression was 0.59 +/- 0.005 micron/min in the normal epidermis and 0.33 +/- 0.03 micron/min in BCC, corresponding to a replication time of the average RU equal to 61 min and 109 min, respectively. Thus, with an unchanged RU size in BCC, the observed 1.8-fold decrease in the rate of fork progression in the tumor can account entirely for our previous observation of a 1.8-fold increase in S-phase duration in this tumor, without requiring the assumption of any change in the temporal organization of DNA synthesis in the malignant cells. Considering S phase as an ordered process in which a major part, if not all, of the genome replicates at genetically determined times, we suggest that the clusters of replication units are, in turn, organized into temporally defined "sets". These sets are composed of all the clusters (whatever their chromosomal location) that are programmed to initiate replication during the same fraction of the S period. This hypothesis implies that DNA synthesis in a given set is triggered by some event coupled to progression of replication in the immediately preceding set. Based on a S-phase duration of 10.2 hours in normal skin and of 19.2 hours in BCC (our previous data), and assuming perfect synchrony and homogeneity of the clusters within each set and of each cluster's constitutive RUs, the minimum number of sequentially replicating sets, in both instances, can be estimated as roughly equal to 10.

ERBIN is a binding partner of Erb-B2, an orphan receptor within the Erb-B family critically involved in the regulation of cell growth and differentiation. Although its function remains unclear, ERBIN is thought to affect the polarity of epithelial cells and cell growth via the Ras signalling pathway. To examine and compare the tissue distribution and the expression levels of ERBIN and Erb-B2 in normal skin and in cutaneous carcinomas. Fifteen cases of basal cell carcinoma (BCC), 12 cases of squamous cell carcinoma (SCC) and five cases of keratoacanthoma (KA) were analysed by immunohistochemistry on paraffin-embedded sections using anti-ERBIN and anti-Erb-B2 antibodies. ERBIN and Erb-B2 had a similar distribution in normal human skin. They were primarily localized at the plasma membrane in differentiated keratinocytes and in duct cells from eccrine glands, whereas they were localized diffusely in the cytoplasma of basal keratinocytes. In both SCC and KA the subcellular distribution of ERBIN and Erb-B2 remained unchanged, whereas both proteins were redistributed from the plasma membrane into cytosolic aggregates in BCC. The subcellular localization of ERBIN in normal human skin is similar to that of Erb-B2 and varies with cell differentiation. Based on our findings and on the biological activities of Erb-B2, it is conceivable that disturbed expression or functioning of ERBIN and Erb-B2 is implicated in the development of the malignant phenotype of BCC.

Haptoglobin (Hp) is an acute-phase reactant, known to be produced mainly in the liver. Haptoglobin can also be detected in the cytoplasm of normal epidermal Langerhans cells (LCs), and can prevent their functional maturation. The synthesis of Hp in skin cells has not been well studied. We examined Hp expression at mRNA and protein levels by in situ hybridization and immunohistochemistry, respectively, in normal human skin and in the skin of patients with psoriasis, lichen planus, erythroderma, seborrheic keratosis, verruca vulgaris, basal cell carcinoma, systemic lupus erythematosus, pemphigus and bullous pemphigoid. (1) Haptoglobin mRNA was expressed in the epidermal keratinocytes (KCs), the epithelial cells of hair follicles, sebaceous glands and eccrine glands in normal skin and all dermatoses investigated. (2) Whereas compared with normal skin, the Hp mRNA in KCs of patients with psoriasis, lichen planus, erythroderma, seborrhoea keratosis and verruca vulgaris was significantly intensified, it was weaker in patients with systemic lupus erythematosus, pemphigus and bullous pemphigoid. (3) Haptoglobin protein only stained positively in some KCs of patients with psoriasis, lichen planus and erythroderma. (4) Although some but not all epidermal LCs were positively stained with anti-Hp antibody in normal skin and in skin samples from all patients, the ratios of Hp-positive LCs/total LCs were significantly higher in those diseases with intensified Hp mRNA in KCs. Skin is another extrahepatic organ where Hp can be synthesized by KCs. The expression of Hp mRNA in KCs and the Hp protein in both LCs and KCs appears to be correlated with the amount of inflammation, which might indicate that skin itself is involved in down-regulating the local inflammatory reaction by KC-synthesized Hp.

Mutations of the patched (Ptc) gene, a developmental regulator implicated in the signalling pathway via sonic hedgehog (Shh) and smoothened (Smo), play an essential pathogenic role in the development of basal cell carcinomas (BCCs). We previously reported the upregulation of Shh signal transducers, including Ptc, Smo and hedgehog-interacting protein, in BCCs. In vertebrates, specific downstream effectors in the Shh signalling pathway include three zinc-finger transcription factors, Gli1, Gli2 and Gli3. Gli1 possesses only an activation domain, while Gli2 and Gli3 contain both activation and repression domains. It remains unclear which of these transcription factors are responsible for the development of BCCs. To examine the expression pattern of Gli2 mRNA by human BCCs in comparison with those by normal human skin and various skin tumours. We performed quantitative reverse transcriptase-polymerase chain reaction analyses with a series of samples from BCCs, other skin tumours and normal skin. We found that Gli2 mRNA expression was enhanced in the BCCs we examined, whereas there was no significant increase in other skin tumours or normal skin. Of four spliced Gli2 isoforms designated Gli2alpha, beta, gamma and delta, the expression of Gli2beta mRNA was increased the most in BCCs. As Gli2beta is an isoform spliced at the first splicing site containing a repression domain and consists of an intact activation domain, its overexpression may lead to the upregulation of the Shh signalling pathway, thereby inducing BCCs.

SnoN is a member of the ski family of proto-oncogenes. It has been revealed that SnoN plays a role in the regulation of cell growth, vertebrate development, and tumorigenesis. This study investigated the expression and significance of SnoN protein in normal human skin and in the development of seborrheic keratosis (SK), basal cell carcinoma (BCC), and squamous cell carcinoma (SCC) of the skin. Six frozen sections of normal human skin, three of SK (acanthotic type), six of BCC, six of intraepidermal SCC (actinic keratosis, AK), and six each of poorly and well-differentiated SCC were immunohistochemically stained with a polyclonal antibody against SnoN. In normal epidermis, strong positive staining was observed in the suprabasal layers, whereas the basal cell layer was entirely unstained. Expression was observed in tumor cells with a squamoid phenotype in SK, but not in BCC. In intraepidermal SCC, although a strong signal was seen in the well-differentiated keratinocytes of the superficial epidermal cell layers, no signal was seen in the poorly differentiated atypical cells situated in the lower epidermis. In invasive SCC, a few scattered cells were positive for SnoN in the well-differentiated sample, but much larger numbers of positive cells were observed in the poorly differentiated sample. On the basis of our results, it is suggested that SnoN is involved in differentiation in normal skin and benign and nonmetastatic skin tumors, but plays a proto-oncogenic role in undifferentiated SCC.

Fibroblast growth factors (FGFs) have been shown to play diverse roles in various tissues. To define their sites of action in normal human skin and during wound healing, we determined the protein expression of the four known fibroblast growth factor receptors (FGFRs) in normal and wounded human skin by immunohistochemistry. Four receptors (FGFR-1 to FGFR-4) showed distinct patterns of expression in normal skin. Expression of FGFR-1 was widespread in the epidermis, appendages, arrector pili muscles, blood vessels, and dermal fibroblasts. Intense expression of FGFR-2 and FGFR-4 was seen in the arrector pili muscles and smooth muscle cells of vessels. In the epidermis, the basal layer showed immunoreactivity for FGFR-2, whereas the suprabasal layers and the inner layers of hair follicles showed strong immunoreactivity for FGFR-3. In wounded skin, there was strong expression of FGFR-1 and FGFR-3, and moderate expression of FGFR-2 and FGFR-4 in the basal layer in newly forming epidermis. In granulation tissues, neocapillaries expressed all four FGFRs, fibroblasts/myofibroblasts expressed FGFR-1 and FGFR-3, and mononuclear inflammatory cells expressed FGFR-1 and FGFR-3. Our results suggest that the differences in the spatial patterns of FGFR expression in normal skin may generate functional diversity in response to FGFs and that in wounded skin, FGFs may function in wound healing via the induced FGFRs.