We discuss the translocation of inhaled asbestos fibers based on pulmonary and pleuro-pulmonary interstitial fluid dynamics. Fibers can pass the alveolar barrier and reach the lung interstitium via the paracellular route down a mass water flow due to combined osmotic (active Na + absorption) and hydraulic (interstitial pressure is subatmospheric) pressure gradient. Fibers can be dragged from the lung interstitium by pulmonary lymph flow (primary translocation) wherefrom they can reach the blood stream and subsequently distribute to the whole body (secondary translocation). Primary translocation across the visceral pleura and towards pulmonary capillaries may also occur if the asbestos-induced lung inflammation increases pulmonary interstitial pressure so as to reverse the trans-mesothelial and trans-endothelial pressure gradients. Secondary translocation to the pleural space may occur via the physiological route of pleural fluid formation across the parietal pleura; fibers accumulation in parietal pleura stomata (black spots) reflects the role of parietal lymphatics in draining pleural fluid. Asbestos fibers are found in all organs of subjects either occupationally exposed or not exposed to asbestos. Fibers concentration correlates with specific conditions of interstitial fluid dynamics, in line with the notion that in all organs microvascular filtration occurs from capillaries to the extravascular spaces. Concentration is high in the kidney (reflecting high perfusion pressure and flow) and in the liver (reflecting high microvascular permeability) while it is relatively low in the brain (due to low permeability of blood-brain barrier). Ultrafine fibers (length < 5 µm, diameter < 0.25 µm) can travel larger distances due to low steric hindrance (in mesothelioma about 90% of fibers are ultrafine). Fibers translocation is a slow process developing over decades of life: it is aided by high biopersistence, by inflammation-induced increase in permeability, by low steric hindrance and by fibers motion pattern at low Reynolds numbers; it is hindered by fibrosis that increases interstitial flow resistances.
Spontaneous contractions of the fetal airways are a well recognized but poorly characterized phenomenon. In the present study spontaneous narrowing of the airways was analyzed in freshly isolated lungs from early to late gestation in fetal pigs and rabbits and in cultured fetal mouse lungs. Propagating waves of contraction traveling proximal to distal were observed in fresh lungs throughout gestation which displaced the lung liquid along the lumen. In the pseudoglandular and canalicular stages (fetal pigs) the frequency ranged from 2.3 to 3.3 contractions/min with a 39 to 46% maximum reduction of lumen diameter. In the saccular stage (rabbit) the frequency was 10 to 12/min with a narrowing of ف 30%. In the organ cultures the waves of narrowing started at the trachea in whole lungs, or at the main bronchus in lobes (5.2 Ϯ 1.5 contractions/min, 22 Ϯ 8% reduction of lumen diameter), and as they proceeded distally along the epithelial tubes the luminal liquid was shifted toward the terminal tubules, which expanded the endbuds. Spontaneous narrowing and relaxation of the airways in the developing fetal lung has been described since the early part of the twentieth century. These spontaneous contractions are characteristic of phasic smooth muscle where regular bursts of action potentials give rise to rhythmic mechanical activity, typified by the smooth muscle of the viscera (1). Yet the contraction of mammalian airway smooth muscle in postnatal life is characterized by slow, graded contractions leading to airway narrowing and occurs without the generation of action potentials during membrane depolarization (2, 3). This is classified as tonic smooth muscle, in common with many blood vessels (1). Perhaps the rhythmic contractile activity of fetal airway smooth muscle is not so surprising since the intestine and the lung have a common embryological origin, with the lung developing as an outgrowth of the foregut in the late embryonic stage (4). Nevertheless, it indicates that airway smooth muscle would need to lose its capacity to generate spontaneous electrical activity sometime during fetal life or at birth and acquire the characteristics of tonic smooth muscle. If and when this occurs is unknown.The phenomenon of spontaneous narrowing of airways in the fetal lung was first observed in explants of lung in culture from embryos of chicken (5) and guinea pigs (6). More recently it was reported in explants of first-trimester human lung (7) and in gestation Day 11 mouse lung (8), where by 48 h in culture, spontaneous contractions began. However, much less information is available for intact fetal airways. McCray (7) noted spontaneous activity of epithelial tubules in small fragments of fresh lungs from first-trimester human fetuses and characterized their contractile responses to pharmacologic agents (discussed later). Sparrow and colleagues (9, 10) video-recorded sequences of strong spontaneous narrowing of individual airways in the isolated intact bronchial tree in the late first and early second trimesters of fetal pig l...
Pulmonary interstitium is maintained dehydrated at subatmospheric pressure (-10 cmH(2)O) through low capillary permeability, low tissue compliance, and an efficient lymphatic drainage. Enzymatic degradation of proteoglycans disrupts the endothelial basal membrane and the matrix structure, triggering the development of pulmonary edema.
Large chondroitinsulphate-containing proteoglycan (versican) isolated from rabbit lung was cleaved by purified gelatinase A (MMP-2) and gelatinase B (MMP-9), as well as by crude enzyme extract from rabbit lung with hydraulic edema. Gelatine zymography, performed after purification of gelatinases by affinity chromatography, demonstrated that the enzyme extract contained two main gelatinolytic bands at about 92 kDa and 72 kDa, identified by specific antisera as the latent proMMP-9 and proMMP-2, respectively. Moreover, enzyme extract from edematous lung showed an increased amount of the proteolytically activated forms of both gelatinases with respect to normal controls. These results suggest that MMP-2 and MMP-9 are involved in the breakdown of versican occurring in rabbit lung during the development of hydraulic edema.z 1999 Federation of European Biochemical Societies.
The present project involved a collective effort agreed by the European Society of Thoracic Surgeons, the American Association for Thoracic Surgery, the Society of Thoracic Surgeons, and the General Thoracic Surgery Club to assemble a joint panel of experts to review the available data and address ambiguous aspects of chest tube definitions and nomenclature. The task force was composed of 11 invited participants, identified for their expertise in the area of chest tube management. The subject was divided in different topics, which were in turn assigned to at least two experts. The draft reports written by the experts on each topic were distributed to the entire expert panel, and comments solicited in advance of the meetings. During the meetings, the drafts were reviewed, discussed, and agreed on by the entire panel. Standardized definitions and nomenclature were proposed for the following topics related to chest tube management: pleural and respiratory mechanics after pulmonary resection; external suction versus no external suction; fixed versus variable suction; objective air leak evaluation; objective fluid drainage evaluation; and chest drain: type, number, and size. A standardized set of definitions and nomenclature were proposed to set a scientifically based framework with which to evaluate existing studies and to more clearly formulate questions, parameters, and outcomes for future studies.
In anesthetized adult rabbits, pulmonary perivascular interstitial pressure (P(ip)), measured by micropuncture technique with intact pleural space, averaged -10.5 +/- 1.9 (SD) cmH2O in control conditions, with a wet-to-dry lung weight ratio (W/D) of 4.8 +/- 0.2. Saline infusion (120 ml i.v. over 120 min) induced interstitial edema, increasing P(ip) to 3.62 +/- 1.6 cmH2O with no significant increase in W/D (5.13 +/- 0.1). For intravenous saline infusion exceeding 140 ml, P(ip) decreased to about atmospheric pressure with development of severe edema that was characterized by an increase of W/D ( > 7) with no further change in P(ip). In a separate set of animals, pulmonary interstitial proteoglycans (PGs) were investigated after sequential extraction of the tissue with 0.4 and 4 M guanidinium chloride (GuHCl) under control conditions and with interstitial (100 ml saline load in 100 min) and severe edema ( > 200 ml total infusion). The extractability of PGs increased constantly with increasing W/D. PG content in total extracts was evaluated by determination of hexuronate content which was 195.4 +/- 1.5 micrograms/g dry tissue in control lungs, 217.9 +/- 1.6 in interstitial edema, and 316.4 +/- 2.7 in severe edema. Moreover, edema development was coupled with an increase in efficiency of PG extraction with 0.4 M GuHCl. These findings suggested a weakening of PG interactions with other components of the extracellular matrix (ECM). Electrophoretic and gel-filtration analyses showed that the relative content of PG populations of large molecular size decreased constantly in 0.4 M GuHCl extract with increasing water loading. We propose relating the inflection of P(ip) in the transition from interstitial to severe edema to PG breakdown, which might greatly affect ECM structural organization, including collagen spreading and/or rupture of epithelial layer.
Nanoparticles (NPs) are materials with overall dimensions in the nanoscale range. They have unique physicochemical properties, and have emerged as important players in current research in modern medicine. In the last few decades, several types of NPs and microparticles have been synthesized and proposed for use as contrast agents for diagnostics and imaging and for drug delivery; for example, in cancer therapy. Yet specific targeting that will improve their delivery still represents an unsolved challenge. The mechanism by which NPs enter the cell has important implications not only for their fate but also for their impact on biological systems. Several papers in the literature discuss the potential risks related to NP exposure, and more recently the concept that even sublethal doses of NPs may elicit a cell response has been proposed. In this review, we intend to present an overall view of cell mechanisms that may be perturbed by cell-NP interaction. Published data, in fact, emphasize that NPs should no longer be viewed only as simple carriers for biomedical applications, but that they can also play an active role in mediating biological effects.
Pulmonary interstitial pressure and tissue matrix structure in acute hypoxia
Pulmonary interstitial pressure was measured via micropuncture in anesthetized rabbits in normoxia and after breathing 12% O(2). In normoxia [arterial PO(2) = 88 +/- 2 (SD) mmHg], pulmonary arterial pressure and pulmonary interstitial pressure were 16 +/- 8 and -9.6 +/- 2 cmH(2)O, respectively. After 6 h of hypoxia (arterial PO(2) = 39 +/- 16 mm Hg), the corresponding values were 30+/-8 and 3.5+/-2.5 cm H(2)O (P<0.05). Pulmonary interstitial proteoglycan extractability, evaluated by hexuronate assay after 0.4 M guanidinium hydrochloride extraction, was 12.3, 32.4, and 60.6 microg/g wet tissue in normoxia and after 3 and 6 h of hypoxia, respectively, indicating a weakening of the noncovalent bonds linking proteoglycans to other extracellular matrix components. Gel filtration chromatography showed an increased fragmentation of chondroitin sulfate- and heparan sulfate-proteoglycans during hypoxic exposure, accounting for a loss of extracellular matrix native architecture and basement membrane structure. Gelatin zymography demonstrated increased amounts of the proteolytically activated form of gelatinase B (matrix metalloproteinase-9) after hypoxic exposure, providing evidence that the activation of proteinases may play a role in hypoxia-induced lung injury.
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