A mouse organotypic tissue culture model for autosomal recessive congenital ichthyosis.

BACKGROUND: Autosomal recessive congenital ichthyoses (ARCIs) are keratinization disorders caused by impaired skin barrier function. Mutations in the genes encoding the lipoxygenases 12R-LOX and eLOX-3 are the second most common cause of ARCIs. In recent years, human skin equivalents recapitulating the ARCI phenotype have been established. OBJECTIVES: To develop a murine organotypic tissue culture model for ARCI. METHODS: Epidermal keratinocytes were isolated from newborn 12R-LOX-deficient mice and cocultivated with mouse dermal fibroblasts embedded in a scaffold of native collagen type I. RESULTS: With this experimental set-up the keratinocytes formed a well-organized multilayered stratified epithelium resembling skin architecture in vivo. All epidermal layers were present and the keratinocytes within showed the characteristic morphological features. Markers for differentiation and maturation indicated regular epidermal morphogenesis. The major components of epidermal structures were expressed, and were obviously processed and assembled properly. In contrast to their wild-type counterparts, 12R-LOX-deficient skin equivalents showed abnormal vesicular structures in the upper epidermal layers correlating with altered lipid composition and increased transepidermal water loss, comparable with 12R-LOX-deficient mice. CONCLUSIONS: The mouse skin equivalents faithfully recapitulate the 12R-LOX-deficient phenotype observed in vivo, classifying them as appropriate in vitro models to study molecular mechanisms involved in the development of ARCI and to evaluate novel therapeutic agents. In contrast to existing human three-dimensional skin models, the generation of these murine models is not constrained by a limited supply of material and does not depend on in vitro expansion and/or genetic manipulations that could result in inadvertent genotypic and phenotypic alterations.

A new approach for calibration of laser ablation inductively coupled plasma mass spectrometry using thin layers of spiked agarose gels as references.

Calibration of analytical methods using laser ablation for sample introduction is often problematic. The availability of matrix-adapted standard materials is a crucial factor in the analysis of biological samples in particular. In this work a method for preparation of thin-film references for LA-ICP-MS is presented which is inexpensive, relatively simple and generally practicable. Aqueous solutions of agarose spiked with defined amounts of the analytes were cast on a carrier and then dried. When the thin-film references were characterized the average thickness of the films was 0.03 mm in the centre of the film and the relative standard deviation was 8%. Nebulization ICP-MS analysis after acid digestion of the agarose film was used to investigate the effectiveness of the spiking procedure. Recovery of the spiked elements was frequently in the range 90-110% (for rare earth elements 97-102%). Laser ablation ICP-MS analysis was used to investigate the distribution of the spiked elements in the film. When the laser was scanned across the gel the measured intensities were not constant, but had a peak-shaped profile with a flat top. Use of this flat-top region for analytical purposes, after its characterization by laser ablation ICP-MS, is proposed. Analysis of cell cultures was carried out by direct laser ablation-ICP-MS with the calibration method described. The results were in accordance with values previously achieved by nebulization ICP-MS.

Gain of 11q/cyclin D1 overexpression is an essential early step in skin cancer development and causes abnormal tissue organization and differentiation.

Non-melanoma skin cancers, in particular keratoacanthomas (KAs) and squamous cell carcinomas (SCCs), have become highly frequent tumor types especially in immune-suppressed transplant patients. Nevertheless, little is known about essential genetic changes. As a paradigm of 'early' changes, that is, changes still compatible with tumor regression, we studied KAs by comparative genomic hybridization and show that gain of chromosome 11q is not only one of the most frequent aberration (8/18), but in four tumors also the only aberration. Furthermore, 11q gain correlated with amplification of the cyclin D1 locus (10/14), as determined by fluorescence in situ hybridization, and overexpression of cyclin D1 protein (25/31), as detected by immunohistochemistry. For unraveling the functional consequence, we overexpressed cyclin D1 in HaCaT skin keratinocytes. These cells only gained little growth advantage in conventional and in organotypic co-cultures. However, although the control vector-transfected cells formed a well-stratified and orderly differentiated epidermis-like epithelium, they showed deregulation of tissue architecture with an altered localization of proliferation and impaired differentiation. The most severe phenotype was seen in a clone that additionally upregulated cdk4 and p21. These cells lacked terminal differentiation, exhibited a more autonomous growth in vitro and in vivo and even formed tumors in two injection sites with a growth pattern resembling that of human KAs. Thus, our results identify 11q13 gain/cyclin D1 overexpression as an important step in KA formation and point to a function that exceeds its known role in proliferation by disrupting tissue organization and thereby allowing abnormal growth.

Id proteins: novel targets of activin action, which regulate epidermal homeostasis.

Activin is a member of the transforming growth factor beta (TGF-beta) family, which plays a crucial role in skin morphogenesis and wound healing. To gain insight into the underlying mechanisms of action, we searched for activin-regulated genes in cultured keratinocytes. One of the identified target genes encodes Id1, a negative regulator of helix-loop-helix transcription factors. We show that Id1, Id2, and Id3 are strongly downregulated by activin in keratinocytes in vitro and in vivo. To determine the role of Id1 in keratinocyte biology, we generated stable HaCaT keratinocyte cell lines overexpressing this protein. Our results revealed that enhanced levels of Id1 do not affect proliferation of keratinocytes in monoculture under exponential culture conditions or in response to activin or TGF-beta1. However, in three-dimensional organotypic cultures, Id1-overexpressing HaCaT cells formed a hyperthickened and disorganized epithelium that was characterized by enhanced keratinocyte proliferation, abnormal differentiation, and an increased rate of apoptosis. These results identify an important function of Id1 in the regulation of epidermal homeostasis.

Epidermal morphogenesis and keratin expression in c-Ha-ras-transfected tumorigenic clones of the human HaCaT cell line.

Several tumorigenic (benign and malignant) clones have been raised from the human epidermal cell line HaCaT after transfection with the c-Ha-ras oncogene (val 12) (P. Boukamp et al., Cancer Res., 50: 2840-2847, 1990). In culture, these HaCaT-ras clones expressed epidermal differentiation markers, such as keratins K1 and 10, at high density or upon depletion of retinoic acid. Accordingly, as HaCaT cells, the clones formed well-differentiated stratified epithelia synthesizing K1 and 10 in surface transplants, while simple and internal epithelial keratins seen in culture were suppressed (as upon retinoic acid depletion in vitro). In transplants of HaCaT cells, in contrast to those of normal keratinocytes, K1 appeared prematurely already in basal cells, while K10 localized rather normally in the suprabasal position. Keratins 1 and 10 were also synthesized in transplants of HaCaT-ras clones (again K1 preceding K10), but both generally shifted toward upper layers. This was particularly evident in thicker transplants of malignant clones. Staining for both keratins persisted "suprabasally" in invasive tissue masses, and this corresponded to their marked expression in solid carcinomas (after s.c. injection), seen by immunofluorescence and two-dimensional gel electrophoresis. Thus, notwithstanding some variations, differentiation potential was not significantly reduced in these clones disregarding levels of ras oncogene expression and malignant properties.

Keratins 1 and 10 or homologues as regular constituents of inner root sheath and cuticle cells in the human hair follicle.

Morphological maturation of the inner root sheath (IRS) and cuticle of the human hair follicle reveals analogies to differentiation processes in other keratinizing epithelia. Detailed biochemical analysis of respective differentiation products, however, has been largely restricted by their low solubility. Herein we provide further evidence for the existence of K1 and K10-derivatives in IRS and hair cuticle based on protein analysis of isolated fractions and immunofluorescence in situ, substantiating our earlier data (Stark, H. J., et al. Differentiation 35, 236-248 (1987)). Extracts from both compartments showed on two-dimensional (2D)-polyacrylamide gels a group of presumptive K1 and K10-turnover products in a wide pI (basic to acidic) and Mr range (56,000-65,000), named IC-I to III and IC-IV, respectively. These components (also found in nail plate) reacted with specific antibodies (to K1 and K10) on Western blots. Weak but distinctive radiolabeling of presumptive precursor spots close to authentic K1 and K10, respectively, and their presence in lower follicle fractions (distant from infundibulum) largely precluded epidermal contamination. Two-dimensional tryptic peptide maps of excised 2D spots from the IC-I to III series revealed high homology to K1, and those from IC-IV components to K10. Immunodetection in frozen sections was improved by trypsin pretreatment and showed distinguished staining for K1 and K10 in IRS ranging from the lower bulbus region up to the "keratinizing zone" of the follicle. Above, the reaction was abruptly abolished which coincides with ultrastructural "melting" of distinct filaments in the intracellular matrix. Thus, our data suggest that differentiation in these follicular compartments (IRS and cuticle) might follow common principles of keratinization.

Epidermal differentiation and basement membrane formation by HaCaT cells in surface transplants.

The immortal human keratinocyte line HaCaT has been employed in many studies as paradigm for epidermal keratinocytes. In order to demonstrate its potential to form stable epidermal structures in response to connective tissue, this was challenged in surface transplants on nude mice, where normal keratinocytes rebuild a typical epidermis within two weeks. During the initial regeneration phase (day 1-4) multilayered but poorly organized epithelia formed with proliferating cells in all layers in analogy to normal keratinocytes. Similarly, with tissue consolidation (around day 7) proliferation was reduced and restricted to cells in basal position marked by keratin K14 and beta1-integrin immunostaining. The strong suprabasal reaction for K1 and K10, the appearance of the late markers K2e, filaggrin and loricrin as well as the polarized distribution of alpha2beta1 and alpha3beta1 indicated advancing tissue normalization (day 14). Keratinization further improved at around three weeks switching from the initial parakeratotic to the regular orthokeratotic type which was prominent at six weeks. Accordingly, most ultrastructural features typical for epidermis or normal keratinocyte grafts were detectable including a complete basement membrane (BM) with regular attachment structures. Matrix- and BM-components appeared sequentially with marked linear deposition of laminin-5 (day 4) followed by accumulation of collagen-IV and 'classical' BM-laminin between one and two weeks. With the general codistribution of integrin alpha6beta4 and BM-molecules (day 14) collagen-VII lining of BM became prominent, while epithelium and host connective tissue were still separated by the collagen matrix. In accordance with the delayed orthokeratinization, wound-matrix molecules (fibronectin, tenascin) persisted longer than in normal keratinocyte transplants. Finally, grafts of long-term passaged (no. 310) cells demonstrated a remarkable stability in the expression of epidermal markers. Thus, the immortalized HaCaT cells reveal a generally high competence to realize an epidermal phenotype in a natural environment and appear therefore qualified for in vitro studies on structural and regulatory aspects of keratinocyte physiology and pathology.

Keratinocyte growth regulation in defined organotypic cultures through IL-1-induced keratinocyte growth factor expression in resting fibroblasts.

Balanced keratinocyte proliferation and differentiation resulting in regular tissue organization strictly depend on dermal support. Organotypic cultures represent biologically relevant in vitro models to study the molecular mechanism of the underlying dermal-epidermal interactions. To mimic the state of resting fibroblasts in the dermis, postmitotic (irradiated) fibroblasts were incorporated in the collagen matrix, where they typically support epidermal proliferation and tissue organization. In coculture with keratinocytes, fibroblasts exhibit an enhanced expression of keratinocyte growth factor and the interleukin-1 receptor (type I), which further increase with culture time. In cocultured keratinocytes, keratinocyte growth factor receptor as well as RNA expression and protein release of interleukin-1alpha and interleukin-1beta are upregulated. We hypothesized that the modulated cytokine expression represents a basic mechanism for keratinocyte growth regulation. The functional significance of this double paracrine pathway, i.e., induction of keratinocyte growth factor expression in fibroblasts by keratinocytes via release of interleukin-1, was confirmed by interfering with both signaling elements: (i) interleukin-1-neutralizing antibodies and interleukin-1 receptor antagonist significantly inhibited keratinocyte growth factor release, keratinocyte proliferation, and tissue formation comparable to the effect produced by keratinocyte-growth-factor-blocking antibodies; (ii) addition of keratinocyte growth factor to cocultures with inactivated interleukin-1 pathway completely reverted growth inhibition; (iii) in organotypic cocultures with subthreshold fibroblast numbers both interleukin-1 and keratinocyte growth factor restored the impaired epidermal morphogenesis. Thus, epidermal tissue regeneration in organotypic cocultures is mainly regulated by keratinocyte-derived interleukin-1 signaling, which induces keratinocyte growth factor expression in cocultured fibroblasts. This demonstrates a novel role for interleukin-1 in skin homeostasis substantiating data from wound healing studies in vivo.

Organotypic keratinocyte cocultures in defined medium with regular epidermal morphogenesis and differentiation.

Skin equivalents formed by keratinocytes cocultured with fibroblasts embedded in collagen lattices represent promising tools for mechanistic studies of skin physiology, for pharmacotoxicologic testing, and for the use as skin substitutes in wound treatment. Such cultures would be superior in defined media to avoid interference with components of serum or tissue extracts. Here we demonstrate that a defined medium (supplemented keratinocyte defined medium) supports epidermal morphogenesis in organotypic cocultures equally well as serum-containing medium (mixture of Ham's F12 and Dulbecco's modified Eagle's medium), as documented by hallmarks of the epidermal phenotype studied by immunofluorescence and electron microscopy. In both cases regularly structured, orthokeratinized epithelia evolved with similar kinetics. Morphology in mixture of Ham's F12 and Dulbecco's modified Eagle's medium was slightly hyperplastic, and keratins 1 and 10 synthesis less co-ordinated than in supplemented keratinocyte defined medium, but a consistently inverted sequence of expression of keratins 1 and 10 was found in either medium. The late differentiation markers filaggrin, involucrin, keratin 2e, and transglutaminase 1 corresponded in their typical distribution in upper suprabasal layers. Keratin 16 persisted under both conditions indicating the activated epidermal state. Keratinocyte proliferation was comparable in both media, whereas fibroblast multiplication and proliferation was delayed and reduced in supplemented keratinocyte defined medium. In both media, ultrastructural features of epidermal differentiation as well as reconstitution of a basement membrane occurred similarly. Immature lamellar bodies and cytoplasmatic vacuoles, however, indicated an impaired lipid metabolism in supplemented keratinocyte defined medium. Nevertheless, these defined organotypic cocultures provide a suitable basis for in vitro skin models to study molecular mechanisms of tissue homeostasis and for use in pharmacotoxicologic testing.

Organotypic cocultures with genetically modified mouse fibroblasts as a tool to dissect molecular mechanisms regulating keratinocyte growth and differentiation.

Organotypic cocultures of keratinocytes and fibroblasts generate a normal epidermis irrespective of the species and tissue origin of fibroblasts. The use of mouse fibroblasts and human keratinocytes facilitates the identification of the origin of compounds involved in epidermal tissue reconstitution and growth regulation. Moreover, the functional significance for the keratinocyte phenotype of genetically modified fibroblasts from transgenic or knockout mice, even those exhibiting an embryonic lethal phenotype, can be studied in such heterologous in vitro tissue equivalents. Here we communicate results of such studies revealing the antagonistic function of mouse fibroblasts defective in the AP-1 constituents c-Jun and JunB, respectively, on human keratinocyte growth and differentiation. Furthermore, the hematopoietic growth factor granulocyte macrophage-colony stimulating factor has been identified as a novel regulator of keratinocyte growth and differentiation. As will be reported in detail elsewhere both granulocyte macrophage-colony stimulating factor and keratinocyte growth factor have been identified as major mediators of fibroblast-keratinocyte interactions and their expression is induced via AP-1 by interleukin-1 released by the epithelial cells. Thus, these heterologous cocultures provide a novel promising tool for elucidating molecular mechanisms of epithelial-mesenchymal interactions and their consequences on epithelial cell proliferation and differentiation.

Modulation of the differentiated phenotype of keratinocytes of the hair follicle and from epidermis.

The differentiation capacity and its modulation by cell-cell and cell-matrix interactions of epithelial cells from epidermis (NEK), hair follicle outer root sheath (ORS) and hair matrix cells (HMC) in different experimental model systems is reviewed. Reformation of structurally intact and functioning hair follicles has been achieved with isolated neonatal mouse cells in vivo when follicular epithelia and dermal fibroblasts were transplanted. This structural reorganization has not yet been feasible in vitro in either surface or matrix embedded organotypic cocultures with mesenchymal cells. While the epithelial cells isolated from epidermis or hair follicle compartments formed similar stratified and keratinizing epithelia in vitro, their degree of differentiation was significantly different, declining from NEK over ORS to HMC. Differentiation was further reduced in HMC cultures in the presence of dermal papilla cells (DPC). Differentiation was analyzed by morphologic criteria and the biochemical analysis as well as immunohistochemical localization of differentiation products such as keratins, involucrin, filaggrin, integrins, basement membrane components and membrane antigens. The results demonstrate fully maintained differentiation capacity of skin and appendage-keratinocytes to reconstitute a squamous epithelium, reflecting their common origin from embryonic epidermis. For the induction of hair follicle-specific structural and functional characteristics, different and probably more complex interactive mechanisms may be required.

Experimental modulation of the differentiated phenotype of keratinocytes from epidermis and hair follicle outer root sheath and matrix cells.

Follicles of human anagen hair were separated into morphologically distinct compartments (by sequential trypsinization and microdissection) for the biochemical and immunological analysis of keratins as differentiation markers to diagnose the type of epithelial differentiation. While outer root sheath contained throughout the "soft" (cyto)keratins K5, 6, 14, 16, and 17, and hair cortex contained exclusively a set of acidic and basic "hard" alpha-keratins (consistent up to the hair tip), in inner root sheath and hair cuticle peptides related or derived from suprabasal epidermal keratins K1 and 10 were detected. These keratin profiles served as in vivo correlates for the evaluation of type and degree of differentiation achieved by the respective isolated epithelial cells, comparing different growth or culture conditions. Cultures of ORS cells and hair matrix cells (PHS cells) as well as normal keratinocytes were initiated using postmitotic human dermal fibroblasts as efficient feeder cells. On lifted collagen gels populated with HDF ("surface" cultures), ORS and PHS cells formed stratified epithelial expressing epidermal differentiation markers such as keratins K1 and 10, involucrin, and filaggrin. Compared with NEK "surface" cultures, balance between growth and differentiation was better maintained by both follicular cell types. In contrast, epidermal tissue homeostasis was largely normalized in transplants on nude mice regardless of the epithelial cell type, apparent from orderly tissue structure, regular distribution of keratin K10, filaggrin, and involucrin, and distinct continuous deposition of basement membrane components at the epithelium-collagen interface. Embedded in Matrigel (on top of HDF collagen gels) ORS cells and NEK formed spheroids exhibiting inward-directed epidermoid differentiation, increasing with time. All epidermal maturation products found in "surface" cultures were likewise expressed, and again differentiation greatly outbalanced proliferation in spheroids of NEK but not of ORS cells. PHS cells embedded together with HDF in Matrigel produced similar spheroids as ORS cells. Size of spheroids and degree of epidermoid differentiation were dramatically reduced when HDF were replaced by follicular DP cells, demonstrating the crucial role of the mesenchymal "companion" cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Differentiation and tumor progression.

Clinical and experimental experience indicate that differentiation and malignancy are inversely correlated. However, more recent experimental studies using mouse and human keratinocyte systems have demonstrated that complete or even substantial loss in overall epithelial differentiation is not a prerequisite for malignant growth of cancer cells. Major defects in differentiation are also not a prerequisite for premalignant stages, in particular for cell immortalization, which is considered an early and essential step in the transformation process. Moreover, progressive dedifferentiation, often associated with advanced tumor stages, is also found in immortalized cell lines which are, however, nontumorigenic. On the other hand, malignant cell lines may have maintained a high degree of their normal differentiation program and sensitivity to differentiation modulators. However, to date no transformed keratinocyte cell lines with completely normal differentiation have been observed. Since epidermal keratinization is a very complex process involving many different parameters and is fully expressed only under in vivo conditions, an exact and quantitative comparison of such ill-defined phenomena (differentiation and malignancy) is still problematic. Obviously, both phenomena are under separate control and not causally linked. Nevertheless, a better understanding of factors and mechanisms regulating differentiation and of their disturbance in carcinogenesis would offer new possibilities to design novel tumor therapeutic strategies in the field of differentiation therapy.

Determination of traces of heavy metals (Mn, Cu, Zn, Cd and Pb) in microsamples of teeth material by ETV-ICP-MS.

Heavy metal levels in tooth compartments would appear to be a suitable indicator of long-term exposure. A method has been developed to assess the heavy metal levels (Mn, Cu, Zn, Cd and Pb) in tooth compartments like dentin and enamel. For the simultaneous determination of these elements in small dentin sample amounts (in some cases less than 1 mg) inductively coupled plasma mass spectrometry with electrothermal vaporization was the method of choice. Sample preparation, method development and first results of the application of the method for the analysis of tooth compartments have been described. Variation in the elemental concentrations depending on the kind of tooth and the sampling position have been observed. The method is useful for epidemiological studies of the heavy metal exposure of children.

Organotypic and epidermal-dermal co-cultures of normal human keratinocytes and dermal cells: Regulation of transforming growth factor alpha, beta1 and beta2 mRNA levels.

Epidermal-dermal cell-cell interactions are recognized to influence keratinocyte proliferation in vivo as well as in vitro. To study the underlying molecular mechanisms of epithelial-mesenchymal interactions epidermal-dermal cell co-cultures and organotypic cultures were used. Steady-state mRNA levels are described for transforming growth factors (TGF) alpha, beta1 and beta2, factors known to stimulate or inhibit the epidermal proliferation rate. In epidermal-dermal monolayer co-cultures TGF alpha hybridization signals were absent. TGF beta1 mRNA was expressed in all cell types (keratinocytes, fibroblasts and microvascular endothelial cells), yet not regulated. In contrast, TGF beta2 mRNA was significantly induced in mesenchymal cells when they were co-cultured with keratinocytes. In organotypic cultures epidermal proliferation is dependent on the presence of fibroblasts within the gel. TGF beta1 was expressed at low levels in all cell types whereas TGF beta2 transcripts were not detectable at all. TGF alpha mRNA was present in keratinocytes at high levels, independent of epidermal cell proliferation or added epidermal growth factor. These results indicate complex regulative mechanisms for TGF alpha, beta1 and beta2 at the mRNA level. However, post-transcriptional steps are involved in the activation of TGF beta1 and 2 and also have to be considered.

Immunohistochemical demonstration of the KI-67-antigen in paraffin-embedded tumor biopsies.

10 tumor specimens were processed according to a modification of the AMeX method, which allows for paraffin embedding plus immunostaining of the slices. We used this method to determine the growth fraction of tumors using the monoclonal antibody KI-67. Results were essentially the same as those obtained when studying frozen sections. The quality of the histological slices is equal to frozen sections, but greater areas of tumor can be examined. Furthermore, this method allows for compilation of a stock of tumor specimens which can be used for further immunohistochemical studies whenever needed.

Biomonitoring of airborne inorganic and organic pollutants by means of pine tree barks. I. Temporal and spatial variations.

Scots pine (Pinus sylvestris L.) bark samples were collected at two field sites (Neuglobsow, Rösa) and in different years between 1987 and 1996 in the east of Germany. The barks were analyzed with respect to the following inorganic and organic substances: Al, As, B, Ca, Cd, Ce, Cr, Cu, Fe, Hg, Mo, NH4+, Ni, NO3-, PO4(3)-, Pb, Sr, SO4(2)-, Ti, V, W, Zr, Zn, benzo[a]pyrene, fluoranthene, pyrene, alpha-hexachlorocyclohexane (alpha-HCH) and dichlorodiphenyltrichloroethane (DDT). In addition to bark samples from the site Rösa, 53 test sites were investigated in the Nature Park Dübener Heide. Here, the analysis of the barks aimed at discovering spatial patterns of the above-mentioned substances. Since 1991, most of the determined substances (e.g. sulfate, nitrate, calcium, lead, benzo[a]pyrene, alpha-HCH) show decreased concentration values in bark samples from both sites. Temporal variations reflect substantial infra-structural changes in eastern Germany, especially at Rösa and in the industrial region around the cities Leipzig, Halle, and Bitterfeld. Moreover, nitrate concentrations in barks are increasing since 1995. The trend can be explained with increased nitrogen emissions from motor traffic and livestock farms. Spatial patterns of sulphate and ammonia reflect inputs from power plants and agriculture in pine stands of the Nature Park Dübener Heide. The results show that barks of pine trees can be used as biomonitoring tools to indicate and characterize depositions of airborne organic and inorganic pollutants.

Continuous-flow fractionation of trace metals in environmental solids using rotating coiled columns. Some kinetic aspects and applicability of three-step BCR leaching schemes.

The applicability of the three-step BCR leaching scheme to the continuous-flow fractionation of trace metals (TM) using rotating coiled columns (RCC) has been investigated taking soil and sediment reference samples (SRM-2710, CRM-601, BCR-701) as examples. A particulate sample was retained in the rotating column as the stationary phase under the action of centrifugal forces while different eluents, used according to the original and optimised BCR protocols, were continuously pumped through. The whole procedure required 3-4 h instead of at least 50 h needed for the traditional sequential extraction. It has been shown that in comparison with batch sequential extraction procedures (SEP), the recoveries of Cd, Zn, Cu, and Pb at the first stage (most mobile and potentially dangerous acid soluble forms) are somewhat higher, if a dynamic extraction in RCC is used. Nevertheless, the distribution patterns for TM in the first two leachable fractions (acid soluble and reducible forms) are similar in most cases. Since no heating is used in RCC, the recoveries of TM at the third stage (when hydrogen peroxide is applied to oxidize the organic matter) may be incomplete and matrix-dependent. The effect of eluent volume and flow rate on the recovery of TM in different forms has been investigated. It has been shown that the kinetics of heavy metal leaching vary significantly with samples. Hence, investigating the elution profiles can provide additional important information for risk assessment of TM mobilization.

The effects of Aspergillus fumigatus challenge on exhaled and nasal NO levels.

Several studies have previously shown that exposure to indoor air microbes from moisture-damaged buildings can cause adverse health effects. Aspergillus fumigatus is one of the best-documented moulds causing health problems to those exposed. In this study, inhalation of a commercial A. fumigatus solution was assessed, to establish if it would have effects on fractional exhaled (FeNO) and nasal (FnNO) nitric oxide levels and on lung function. The results were compared with placebo challenge. A total of 28 subjects were divided into three study groups: group 1 had been exposed to occupational mould; group 2 consisted of atopic subjects; and group 3 was a control group. Some 3 h after A. fumigatus challenge, there was a considerable increase in FeNO, and a significant difference was observed between the A. fumigatus and placebo inhalations. The difference was seen in all study groups. No such differences were found in the levels of FnNO or nitrite in nasal lavage fluid. Subjects reported significantly more frequent respiratory tract symptoms after the A. fumigatus inhalation compared with placebo challenge. In conclusion, it was shown here that inhalation challenge of Aspergillus fumigatus elevated fractional exhaled nitric oxide levels. An increase in fractional exhaled nitric oxide may serve as an indicator of respiratory inflammation of acute mould exposure.