Recording Methods and the Capabilities of Modern Respiratory Rate Monitoring Devices (literature review).

Determination of respiratory rate is a necessary task in assessing the state of health in humans. This review provides a description of modern devices used for recording and monitoring respiratory rate. The advantages and disadvantages of the principles of operation of these devices are discussed.

Evaluation of the Content of Aquaporin-5 and Epithelial Sodium Channel in the Lungs of Rats during the Development of Toxic Pulmonary Edema Caused by Intoxication with Acylating Pulmonotoxicants.

We studied the content of aquaporin-5 (AQP5) and epithelial sodium channel (ENaC) in rat lungs during the development of toxic pulmonary edema (TPE) caused by intoxication with phosgene and perfluoroisobutylene (1.5 LC50). The lung body weight index (LBI) was calculated and histological examination of the lung tissues was performed. Localization and expression of AQP5 and ENaC were determined by immunohistochemistry. Intoxication led to a significant (p<0.05) increase in LBI and histological changes typical of TPE 1 and 3 h after the exposure. In 1 and 3 h after phosgene intoxication, the AQP5 and ENaC content significantly (p<0.05) increased in comparison with the control. Similar changes in the AQP5 and ENaC content were observed 1 and 3 h after exposure to perfluoroisobutylene. It was hypothesized that AQP5 plays an important role in the formation of TPE caused by intoxication with acylating pulmonotoxicants. An increase in the content of ENaC can be considered as a compensatory reaction of the body aimed at clearance of the alveolar fluid.

Ultrastructural Changes in the Air-Blood Barrier of Rats in Acute Intoxication with Furoplast Pyrolysis Products.

Rats were exposed to fluoroplast-4 pyrolysis products (sample weight 2.6 g, pyrolysis temperature 440-750°C, pyrolysis duration 4 min) containing perfluoroisobutylene over 15 min. Lung tissue samples for histological and electron microscopic examination were isolated in 3 and 30 min after intoxication and processed routinely. Histological examination revealed no structural changes in the lungs. In ultrathin sections of rat lungs, some changes in the structure of type I pneumocytes were detected in 3 min after the exposure: detachment of cytoplasmic processes and the appearance of transcytosis pores. These changes attested to impaired cell-cell interactions and their adhesion to the basement membrane, where structural disorganization and edema of the collagen matrix were observed. In 30 min following exposure, the signs of damage to type I pneumocytes became more pronounced. The increase in the equivalents of transcellular and paracellular permeability in the alveolar lining profile was observed. No changes in the pulmonary capillary endotheliocytes were detected, which suggest that type I pneumocytes are the primary target of the toxic effect of perfluoroisobutylene. The vulnerability of a particular cell population, in view of specific metabolism of these cells, can be the key to deciphering of the mechanisms of the toxic effect of pyrolysis products of fluorinated polymer materials.

Mechanisms of Pulmonary Toxicity of Perfluoro-n-Alkane Pyrolysis Products with Consideration of the Structural Features of the Blood-Air Barriers.

Perfluoroisobutylene a is pulmonotoxic chemical generated during pyrolysis of perfluoro-nalkanes (polytetrafluoroethylene). The mechanisms of acute pulmonary toxicity induced by perfluoroisobutylene have not been studied yet. The analysis of tissues of brown frogs showed that the products of polytetrafluoroethylene pyrolysis induce typical inflammatory response in the lungs (fluid accumulation, erythrocyte stasis, desquamation of the epithelium, and capillary plethora in lung septa) and oropharyngeal cavity (degeneration of ciliated epithelium, hyperemia of underlying vessels with plasmatic imbibition of the connective tissue, and margination of segmented leukocytes and monocytes). The absence of surfactant is a specific feature of the blood-air barrier of the oropharyngeal cavity in frogs compared to the lungs. It can be hypothesized that toxic effects of perfluoroisobutylene are determined by its influence on epithelial (pneumocytes and cells of nonkeratinized stratified ciliated epithelium) and endothelial cells. Even though the effects of the agent on surfactant cannot be excluded, they do not determine the probability of development of inflammatory response.

Assessment of Functional Disturbances in the Central Nervous System Caused by Severe Carbon Monoxide Poisoning in Rats.

An experimental model was developed for assessment of disturbances in CNS functions of laboratory animals caused by severe carbon monoxide poisoning. Normalization of the state of experimental rats after acute poisoning was accompanied by the development of cognitive abnormalities. Disturbances in the long-term memory were observed on days 1 and 14 after CO poisoning, while abnormalities in the short-term memory developed on days 1, 7, and 14. Learning impairment were recorded on day 8, while the training course began on day 7.

[Chemicals as fire damaging factor].

The article provides an overview of published scientific data about toxic chemical compounds formed during thermal degradation of various materials. In case of fire the complex of physical and chemical factors affect the human, along with injuries, thermal burns of the skin and respiratory tract there is a lack of oxygen in the inspired air and the impact of thermal degradation products. The greatest number of deaths in.a fire due to the inhalation by the victims smoke and toxic gases. The impact of the combination of toxic substances leads to the development of various forms of toxic process. The main causes of poisoning at the fires due to the effects of toxic substances and substances which can cause structural and functional disorders of the respiratory organ. Intoxication manifestations by some of them appear already in the fire zone, in other cases, in cases of poisoning by the compounds of the slow motion, there is the latent period of of intoxication. Knowledge of the spectrum of toxic products thermal destruction on the human during the fire, it is necessary to develop approaches to improve medical care and creation of tools of medical protection.