High-Accuracy Calibration Method of a Thermal Camera Using Two Reference Blackbodies.

Body temperature is one of the most important physiological parameters of a human being used to assess his basic vital functions. In medical practice, various types of measuring instruments are used to measure temperature, such as liquid thermometers, electronic thermometers, non-contact ear thermometers, and non-contact forehead thermometers. Such body temperature measurement techniques require the connection of appropriate sensors to a person, and non-contact thermometers operate over short distances and force a specific position of the person during the measurement.

Towards More Precise Targeting of Inhaled Aerosols to Different Areas of the Respiratory System.

Pharmaceutical aerosols play a key role in the treatment of lung disorders, but also systemic diseases, due to their ability to target specific areas of the respiratory system (RS). This article focuses on identifying and clarifying the influence of various factors involved in the generation of aerosol micro- and nanoparticles on their regional distribution and deposition in the RS. Attention is given to the importance of process parameters during the aerosolization of liquids or powders and the role of aerosol flow dynamics in the RS.

Influence of Physicochemical Properties of Budesonide Micro-Suspensions on Their Expected Lung Delivery Using a Vibrating Mesh Nebulizer.

The efficiency of lung drug delivery of nebulized drugs is governed by aerosol quality, which depends both on the aerosolization process itself but also on the properties of aerosol precursors. This paper determines physicochemical properties of four analogous micro-suspensions of a micronized steroid (budesonide, BUD) and seeks relationships between these properties and the quality of the aerosol emitted from a vibrating mesh nebulizer (VMN). Despite the same BUD content in all tested pharmaceutical products, their physicochemical characteristics (liquid surface tension, viscosity, electric conductivity, BUD crystal size, suspension stability, etc.

Impact of Natural-Based Viscosity Modifiers of Inhalation Drugs on the Dynamic Surface Properties of the Pulmonary Surfactant.

The effectiveness of inhalation therapy depends on aerosol size distribution, which determines the penetration and regional deposition of drug in the lungs. As the size of droplets inhaled from medical nebulizers varies depending on the physicochemical properties of the nebulized liquid, it can be adjusted by adding some compounds as viscosity modifiers (VMs) of a liquid drug. Natural polysaccharides have been recently proposed for this purpose and while they are biocompatible and generally recognized as safe (GRAS), their direct influence of the pulmonary structures is unknown.

Interactions between O Nanobubbles and the Pulmonary Surfactant in the Presence of Inhalation Medicines.

A dispersion of oxygen nanobubbles (O-NBs) is an extraordinary gas-liquid colloidal system where spherical gas elements can be considered oxygen transport agents. Its conversion into inhalation aerosol by atomization with the use of nebulizers, while maintaining the properties of the dispersion, gives new opportunities for its applications and may be attractive as a new concept in treating lung diseases. The screening of O-NBs interactions with lung fluids is particularly needed in view of an O-NBs application as a promising aerosol drug carrier with the additional function of oxygen supplementation.

Aqueous dispersions of oxygen nanobubbles for potential application in inhalation therapy.

Inhalation is a non-invasive method of local drug delivery to the respiratory system. This study analyzed the potential use of aqueous dispersion of oxygen nanobubbles (ADON) as a drug carrier with the additional function of oxygen supplementation to diseased lungs. The suitability of the membrane-based method of ADON preparation and, next, the stability of ADON properties during storage and after aerosolization in nebulizers of various designs (jet, ultrasonic, and two vibrating mesh devices) was investigated.

In silico evaluation of particle transport and deposition in the airways of individual patients with chronic obstructive pulmonary disease.

Inhalation therapy can effectively treat chronic obstructive pulmonary disease (COPD), but the physical factors determining the appropriate aerosol delivery into the targeted airways remain unclear. The problem is nontrivial because pulmonary structures differ among individual patients with COPD and depend on the severity of the disease. In an in silico evaluation, the present study investigates the differences in particle transport and deposition in the airways of three patients with different degrees of COPD.

ThermoSteg-Covert Channel for Microbolometer Thermographic Cameras.

The article presents a new concept-steganography in thermography. Steganography is a technique of hiding information in a non-obvious way and belongs to sciences related to information security. The proposed method, called ThermoSteg, uses a modification of one of the parameters of the thermal imaging camera-integration time-to embed the signal containing hidden information.

Impact of inhalers used in the treatment of respiratory diseases on global warming.

The term "carbon footprint" describes the emission of greenhouse gases into the environment as a result of human activities. The healthcare sector is responsible for 5-8% of the value of global greenhouse gas emissions, of which medical aerosols account for only 0.03% of the total emissions.

Inhaled aerosols: Their role in COVID-19 transmission, including biophysical interactions in the lungs.

The high rate of spreading of COVID-19 is attributed to airborne particles exhaled by infected but often asymptomatic individuals. In this review, the role of aerosols in SARS-CoV-2 coronavirus transmission is discussed from the biophysical perspective. The essential properties of the coronavirus virus transported inside aerosol droplets, their successive inhalation, and size-dependent deposition in the respiratory system are highlighted.

Bioactive Betulin and PEG Based Polyanhydrides for Use in Drug Delivery Systems.

In the course of this study, a series of novel, biodegradable polyanhydrides based on betulin disuccinate and dicarboxylic derivatives of poly(ethylene glycol) were prepared by two-step polycondensation. These copolymers can be used as carriers in drug delivery systems, in the form of microspheres. Betulin and its derivatives exhibit a broad spectrum of biological activity, including cytotoxic activity, which makes them promising substances for use as therapeutic agents.

Interfacial rheology for the assessment of potential health effects of inhaled carbon nanomaterials at variable breathing conditions.

Lung surface is the first line of contact between inhaled carbon nanomaterials, CNMs, and the organism, so this is the place where pulmonary health effects begin. The paper analyzes the influence of several CNMs (single- and multi-walled nanotubes with various surface area: 90-1,280 m/g and aspect ratio: 8-3,750) on the surface-active properties of the lung surfactant, LS, model (Survanta). Effects of CNM concentration (0.

Impact of physicochemical properties of nasal spray products on drug deposition and transport in the pediatric nasal cavity model.

The study is focused on the analysis of physicochemical properties of selected nasal sprays of mometasone furoate, and the influence of these properties on aerosol quality and penetration in the pediatric nose. After the determination of drugs surface tension and viscosity, spray geometry and size distribution of aerosol droplets, the topical delivery of each drug to different parts of the pediatric model of the nose with the flexible vestibule was evaluated by colorimetric visualization. All tested drugs are pseudo-plastic liquids, showing some differences in flow consistency constant k (range 714-1422) and flow behavior index n (range 0.

Particle Size Dynamics: Toward a Better Understanding of Electronic Cigarette Aerosol Interactions With the Respiratory System.

The knowledge of possible acute and long-term health effects of aerosols inhaled from electronic cigarettes (ECs) is still limited partially due to incomplete awareness of physical phenomena related to EC-aerosol dynamics. This short review discusses the basic processes of aerosol transformation (dynamics) upon inhalation, indicating also the need for the accurate determination of the size of droplets in the inhaled EC-mist. The significance of differences in the aerosol particle size distribution for the prediction of regional deposition of inhaled mist in the respiratory system is highlighted as a decisive factor in the interactions of inhaled EC-aerosols with the organism.

Physicochemical studies of direct interactions between lung surfactant and components of electronic cigarettes liquid mixtures.

Direct physicochemical interactions between the major components of electronic cigarette liquids (e-liquids): glycerol (VG) and propylene glycol (PG), and lung surfactant (LS) were studied by determining the dynamic surface tension under a simulated breathing cycle using drop shape method. The studies were performed for a wide range of concentrations based on estimated doses of e-liquid aerosols (up to 2500 × the expected nominal concentrations) and for various VG/PG ratios. The results are discussed as relationships among mean surface tension, surface tension amplitude, and surface rheological properties (dilatational elasticity and viscosity) versus concentration and composition of e-liquid.

Inhalation devices: from basic science to practical use, innovative vs generic products.

Inhalation therapy is a convenient method of treating respiratory diseases. The key factors required for inhalation are the preparation of drug carriers (aerosol particles) allowing reproducible dosing during administration. These technical challenges are accomplished with a variety of inhalation devices (inhalers) and medicinal formulations, which are optimized to be easily converted into inhalable aerosols.

Predicted Deposition of E-Cigarette Aerosol in the Human Lungs.

Background: Health effects of inhaling aerosol produced by electronic cigarettes (ECs) are still uncertain. This work analyzes ECs as specific inhalation devices, which can be characterized by aerodynamic resistance, size distribution of released droplets, and predicted regional and total lung deposition as a function of inhalation maneuver.

Methods: The internal resistance of two types of EC and a conventional cigarette was evaluated by measuring ΔP-Q curves.

Deposition of intranasal glucocorticoids--preliminary study.

Introduction: Intranasal glucocorticoids are the treatment of choice in the therapy of rhinitis. The differences in efficiency of particular medications proven by therapeutic index may result from differences in composition of particular formulations as well as from diverse deposition in nasal cavities. Intranasal formulations of glucocorticoids differ in volume of a single dose in addition to variety in density, viscosity and dispenser nozzle structure.

Selected Engineering and Physicochemical Aspects of Systemic Drug Delivery by Inhalation.

Inhalation of aerosolized pharmaceuticals is a non-invasive and convenient method of drug delivery typically used for local treatment of lung diseases. Large absorption area of the pulmonary region opens up the possibility of fast and effective transfer of inhaled medicines to the circulation in order to obtain systemic effects. This review is devoted to selected albeit essential challenges of targeting aerosolized drugs to the blood via the pulmonary part of the respiratory system.

Effect of clay nanoparticles on model lung surfactant: a potential marker of hazard from nanoaerosol inhalation.

This work investigates influence of different aluminosillicate nanoparticles (NPs) which are found in air in selected workplaces on the properties of the phospholipid (DPPC) monolayer at air-saline interface considered as ex vivo model of the lung surfactant (LS). The measurements were done under physiological-like conditions (deformable liquid interface at 37 °C) for NP concentrations matching the calculated lung doses after exposure in the working environment. Measured surface pressure-area (π-A) isotherms and compressibility curves demonstrated NP-induced changes in the structure and mechanical properties of the lipid monolayer.

Nanosized and Nanostructured Particles in Pulmonary Drug Delivery.

Nanosized objects can be used as the drug carriers with specific functionalities which are introduced to the body via the respiratory system, i.e., by inhalation.

Aerosolized albuterol sulfate delivery under neonatal ventilatory conditions: in vitro evaluation of a novel ventilator circuit patient interface connector.

Background: Aerosolized medications that have been used in infants receiving ventilatory support have not been shown to be effective clinically among the smallest patients. The aim of this study was to characterize the delivery of aerosolized albuterol sulfate in vitro under simulated neonatal ventilatory conditions using a novel ventilator circuit/patient interface connector.

Methods: A Babylog(®) ventilator (VN500(®); Draeger), a novel ventilator circuit/patient interface (VC) connector (Afectair(®); Discovery Laboratories, Inc.

Alteration of biophysical activity of pulmonary surfactant by aluminosilicate nanoparticles.

The influence of five different types of aluminosilicate nanoparticles (NPs) on the dynamic surface activity of model pulmonary surfactant (PS) (Survanta) was studied experimentally using oscillating bubble tensiometry. Bentonite, halloysite and montmorillonite (MM) NPs, which are used as fillers of polymer composites, were characterized regarding the size distribution, morphology and surface area. Particle doses applied in the studies were estimated based on the inhalation rate and duration, taking into account the expected aerosol concentration and deposition efficiency after penetration of NPs into the alveolar region.

Alteration of surface properties of dipalmitoyl phosphatidylcholine by benzo[a]pyrene: a model of pulmonary effects of diesel exhaust inhalation.

Effects of benzo[a]pyrene (BaP) on the surface properties of dipalmitoyl phosphatidylcholine (DPPC) being the basic component of pulmonary surfactant and lipid membranes were studied experimentally and analyzed by molecular dynamics simulations. Isotherms and surface compressibility of mixed BaP/DPPC monolayers on water were determined using Langmuir-Wilhelmy film balance. It was demonstrated that BaP induced concentration-dependent deviations from the initial surface activity of the phospholipid film and a noticeable decrease of its fluidity.

Conception, preparation and properties of functional carrier particles for pulmonary drug delivery.

Background: The effectiveness of aerosol therapy is significantly reduced by the mucus layer covering the airways of the tracheobronchial tree. According to the present concept, drug particles are delivered to the lung together with the functional carrier particle that facilitates both the drug transport into the lungs and the penetration of deposited particles through the mucus. The approach of manufacturing multi-component powders with mucoactive compounds and anti-asthmatic medicines (DSCG) bound together in a single particle is additionally considered.