V. Konrádová

Acute and chronic hypoxia as well as 7-day recovery from chronic hypoxia affects the distribution of pulmonary mast cells and their MMP-13 expression in rats

Chronic hypoxia results in pulmonary hypertension due to vasoconstriction and structural remodelling of peripheral lung blood vessels. We hypothesize that vascular remodelling is initiated in the walls of prealveolar pulmonary arteries by collagenolytic metalloproteinases (MMP) released from activated mast cells. Distribution of mast cells and their expression of interstitial collagenase, MMP‐13, in lung conduit, small muscular, and prealveolar arteries was determined quantitatively in rats exposed for 4 and 20 days to hypoxia as well as after 7‐day recovery from 20‐day hypoxia (10% O2). Mast cells were identified using Toluidine Blue staining, and MMP‐13 expression was detected using monoclonal antibody. After 4, but not after 20 days of hypoxia, a significant increase in the number of mast cells and their MMP‐13 expression was found within walls of prealveolar arteries. In rats exposed for 20 days, MMP‐13 positive mast cells accumulated within the walls of conduit arteries and subpleurally. In recovered rats, MMP‐13 positive mast cells gathered at the prealveolar arterial level as well as in the walls of small muscular arteries; these mast cells stayed also in the conduit part of the pulmonary vasculature. These data support the hypothesis that perivascular pulmonary mast cells contribute to the vascular remodelling in hypoxic pulmonary hypertension in rats by releasing interstitial collagenase.

Effect of Bronchoalveolar Lavage on the Ultrastructure of the Tracheal Epithelium in Rabbits

Serious damage to the tracheal epithelium due to bronchoalveolar lavage (BAL) was recorded. Immediately after BAL 99 +/- 2% of goblet cells were exhausted and degenerated. Their regeneration began 24 h after BAL resulting in hyperplasia of goblet cells with the formation of endoepithelial mucous glands. The most pronounced injury to the ciliated cells was apparent 2 h after BAL. BAL markedly impaired the ciliary border. The mean number of cilia/microns 2 fell to 1.5 +/- 0.3/microns 2, then gradually rose to 7.5 +/- 0.5/microns 2 (controls 9.7 +/- 0.5/microns 2). The morphological signs of impairment of the self-cleaning ability of the epithelium were the most pronounced after 24 h and were still present at the end of the experiment.

Effect of Inhalation of Single Dose of Beclomethasone on Airway Epithelium

Inhaled corticosteroids are being recommended for the treatment of bronchial asthma for their anti-inflammatory properties and reduction of airway hyperreactivity. The first tissue coming to the contact with all inhaled substances is the airway epithelium. In this experiment, the immediate effect of a single MDI dose of beclomethasone on the ultrastructure of the tracheal and bronchiolar epithelium was studied. Due to the beclomethasone administration, the secretory elements were highly affected. The tracheal goblet cells were damaged, mucus release was significantly accelerated, and the mechanism of secretion was influenced. The bronchiolar Clara cells revealed signs of the pathological alteration. Their secretory granules were usually stored in the cytoplasm. Occasionally, degenerating Clara cells were found after the beclomethasone administration. The injury of ciliated cells in both locations was only mild and this fact was reflected in slight impairment of the tracheal ciliary border. As a morphological sign of impaired self-cleaning ability, inspissated secretion was discovered among cilia. According to this evaluation, the inhalation of the single dose of beclomethasone caused a moderate damage to the tracheal epithelium and a mild one to the epithelium of terminal bronchioles. The results draw attention to the adverse effects of otherwise therapeutically beneficial inhaled glucocorticosteroids.

The effects of intravenously administered methylxanthine preparations on the glycoconjugate composition of goblet cells in rabbit tracheal epithelium.

Effects of methylxanthine derivatives, which are inhibitors of phosphodiesterases I-IV used against bronchial asthma, on the composition of glycoconjugates in goblet cells were evaluated in tracheal epithelium of rabbits at 15 and 30 min after intravenous administration of aminophylline (Syntophyllin) and a mixture of etophylline and theophylline (Oxantil), respectively. Percentages of tracheal goblet cells containing neutral, total acidic, sulphated acidic, and sialylated acidic glycoconjugates were assessed using both conventional and lectin histochemistry. No significant changes were found in both experimental groups at 15 min after exposure. A significant decrease in percentage of alpha(2-3)-sialylated glycoconjugate-containing goblet cells occurred at 30 min after administration of Syntophyllin only. It is concluded that the mucus composition of tracheal goblet cells has been affected by the bronchospasmolytic drug Syntophyllin but not by the vasodilator drug Oxantil.

Local administration of 2% trimecaine affects the content of fucosylated glycoconjugates in goblet cells in rabbit tracheal epithelium

The proportion of fucosylated glycoconjugate‐containing rabbit tracheal goblet cells after intratracheal application of trimecaine was studied to evaluate its possible unfavourable effects. This lapine model is comparable with diagnostic findings in humans because airway epithelia in humans and rabbits are similar; tracheal epithelium is also practically identical to bronchial epithelium in both species. Local trimecaine anaesthesia caused a proportional decrease in percentage of the tracheal goblet cells containing both α(1–2)‐ and α(1–6)‐, α(1–3)‐ and α(1–4)‐fucosylated glycoconjugates as revealed 10 min postexposure using lectin histochemistry. In previous studies, only mild ultrastructural damage to the airways epithelium was revealed, but a conspicuous decrease in sialylated glycoconjugate‐containing tracheal goblet cells and the dominance of acidic sulphated glycoconjugates were observed as after‐effects of the same treatment. Glycoconjugate changes can influence the inner environment of airways (e.g. viscoelastic properties of the airways’ mucus and mucosal barrier functions) and thus the patients defence barriers in airways may be weakened. Concurrently, the histochemical properties of goblet cells can be altered in bronchoscopic specimens. Since trimecaine is widely used as local anaesthesia in airways in bronchoscopy, it is necessary to heed these aforementioned effects.

Reaction of The Goblet Cells to Cholinergic Stimulation

Ivanova I. Ye., T. A. Derendiayeva, G. I. Meleshko, Yeo Ya. Shepelev: Higher Plants in a Biological Life SupportSystemfor Man. Acta vet. Bmo 1996,65: 27-32. A model of human biological life support system (BLSS) was created with a photoautotrophic link including unicellular algae and higher plants having an equal oxygen production. This system model supported the vital activities of two people at the biomass regeneration of 92% from that consumed by them. The plant cultures studied were wheat grown on 11.25 m2 (of a total 15 m2) and several vegetable species. The total photosynthetic productivity of the plants was high, stable over the studied time span, and independent on the composition of the system. However, the grain productivity of wheat decreased periodically, and during certain harvests it decreased to almost zero. A detailed analysis revealed that this decrease was not caused by any of the systems adjacent links as a similar decrease in yield was also found in the control period with an autonomous growth of the plants in a closed volume of a chamber. Inclusion of bigher plants into BLSS led to a considerable improvement od food supply regeneration for man as compared to the previous model with only 26% regeneration effect. This inclusion did not exert any marked effect upon the general closure of the cycle. However, the biological value of the food for man was increased dramatically. This improvement is the main goal of designing and operating such BLSS systems. Regeneration. ecosystem. photosynthesis, photoautotroph link, unicellular algae. higher p.lants The prospect of long-teon existence of man outside the Earths biosphere (interplanetary flights, lunar and planetary bases) is connected with creating an artificial environment with the help of regenerating it from the products of vital activity. This environment must correspond to the evolutionarily conditioned biological needs of the humans and to provide their lives for generations. The fact of adaptive biology shows that the full-value environment for humans and other terrestrial organisms is the natural environment of the Earth. In order to recreate that environment artificially it is necessary to reproduce the mechanisms existing on Earth, i. e. to foon closed ecological systems including man. The lack of our knowledge about the natural environment of the humans prevents us from reproducing it by non-biological means, even if it were possible. The investigation of the problem of creating biological life-support systems (BLSS) of man began as early as in the 60ies. By the present time, experimental BLSS models have been created with different structures and different degrees of the cycle closure. , The creation of the systems was based on the ecological concept according to which strategy and tactics were worked out providing the organisms and populations were studied and then united into biocenoses, including also humans. The main method of solving the problem was the method of experimental modelling from the simple to the complex (Rashevski 1966).

Comparison of the Effect of a High and Low Dose of Atropin on the Ultrastructure of the Tracheal Epithelium

The ultrastructure of rabbit tracheal epithelium was studied 20 min after injection of 0.04 and 0.5 mg of atropin. The tracheae were lined with altered ciliated pseudostratified columnar epithelium. The degree of damage to the epithelial cells was dose dependent. The injury to the tracheal epithelium due to treatment with 0.04 mg of atropin was considered mild. The administration of the higher dose of atropin caused moderately severe epithelial damage. Both experimental groups exhibited morphological signs of impaired self-cleaning ability.

Regenration of Injury of the Rabbits (Oryctolagus cuniculus var. edulis) Tracheal Epithelium Due to the IntratrachealAdministration of an Iodinated Contrast Agent

Ivanova I. Ye., T. A. Derendiayeva, G. I. Meleshko, Yeo Ya. Shepelev: Higher Plants in a Biological Life SupportSystemfor Man. Acta vet. Bmo 1996,65: 27-32. A model of human biological life support system (BLSS) was created with a photoautotrophic link including unicellular algae and higher plants having an equal oxygen production. This system model supported the vital activities of two people at the biomass regeneration of 92% from that consumed by them. The plant cultures studied were wheat grown on 11.25 m2 (of a total 15 m2) and several vegetable species. The total photosynthetic productivity of the plants was high, stable over the studied time span, and independent on the composition of the system. However, the grain productivity of wheat decreased periodically, and during certain harvests it decreased to almost zero. A detailed analysis revealed that this decrease was not caused by any of the systems adjacent links as a similar decrease in yield was also found in the control period with an autonomous growth of the plants in a closed volume of a chamber. Inclusion of bigher plants into BLSS led to a considerable improvement od food supply regeneration for man as compared to the previous model with only 26% regeneration effect. This inclusion did not exert any marked effect upon the general closure of the cycle. However, the biological value of the food for man was increased dramatically. This improvement is the main goal of designing and operating such BLSS systems. Regeneration. ecosystem. photosynthesis, photoautotroph link, unicellular algae. higher p.lants The prospect of long-teon existence of man outside the Earths biosphere (interplanetary flights, lunar and planetary bases) is connected with creating an artificial environment with the help of regenerating it from the products of vital activity. This environment must correspond to the evolutionarily conditioned biological needs of the humans and to provide their lives for generations. The fact of adaptive biology shows that the full-value environment for humans and other terrestrial organisms is the natural environment of the Earth. In order to recreate that environment artificially it is necessary to reproduce the mechanisms existing on Earth, i. e. to foon closed ecological systems including man. The lack of our knowledge about the natural environment of the humans prevents us from reproducing it by non-biological means, even if it were possible. The investigation of the problem of creating biological life-support systems (BLSS) of man began as early as in the 60ies. By the present time, experimental BLSS models have been created with different structures and different degrees of the cycle closure. , The creation of the systems was based on the ecological concept according to which strategy and tactics were worked out providing the organisms and populations were studied and then united into biocenoses, including also humans. The main method of solving the problem was the method of experimental modelling from the simple to the complex (Rashevski 1966).