Your search keyword '"Farkas, Árpád"' showing total 112 results

101. In Vitro Study of the Effect of Particle Characteristics and Flow Rate on Regional Deposition in Human Airways

Author

Jedelský, Jan, Adamec, Vladimír, Farkas, Árpád, Jedelský, Jan, Adamec, Vladimír, and Farkas, Árpád

Abstract

Dlouhodobé vdechování částic může přispívat ke vzniku nebo zhoršení nejrůznějších plicních onemocnění. Na druhou stranu, vdechování léčiv je často používanou metodou podávání léků proti astmatu a jiným nemocem dýchacího ústrojí. V obou případech je důležité dobře porozumět mechanismům, na jejichž základě funguje pohyb částic a jejich usazování v dýchacích cestách. Cílem této disertační práce bylo získat nová experimentální data depozice částic a analyzovat vliv tvaru částic a průtoku vzduchu na depozici. Byla studována depozice porézních a vláknitých částic v realistickém modelu dýchacích cest. Porézní částice byly vyrobeny různými metodami, např. sprejovým sušením nebo metodou krystalizace. Takto vyrobené částice byly použity při depozičních experimentech. Detekce částic byla provedena pomocí UV/VIS spektrofotometrie. Vláknitý aerosol byl vytvořen rozdrcením skelné vaty. Takto vzniklé vláknité částice byly několikrát prosety přes řadu sít a dále roztříděny podle délky pomocí klasifikátoru pracujícím na principu dielektroforézy. Následná depozice byla vyhodnocena použitím mikroskopie s fázovým kontrastem. Ke zrychlení analýzy byl vyvinut program, který dokáže na základě analýzy obrazu najít a spočítat vlákna. Výsledky experimentu byly použity k určení depozičních charakteristik. S jejich pomocí pak byl kvantifikován vliv tvaru částic a průtoku na míru usazování. Depoziční účinnost částic rostla v závislosti na Stokesově čísle, což poukazuje na vliv setrvačnosti při usazování částic. Bylo prokázáno, že depoziční účinnost porézních částic je podobná té u částic kulových při stejném Stokesově čísle. Vláknité částice se usazovali méně efektivně v porovnání s kulovými částicemi majícími stejné Stokesovo číslo. Jelikož byly okrajové podmínky dostatečně popsány a model plic je k dispozici i v digitální podobě, je možné data použít k validaci výsledků numerických simulací., Inhalation of airborne particulate matter can trigger or exacerbate pre–existing lung conditions. On the other hand, inhalation of aerosolized medicaments can be used for treatment of various respiratory or systemic diseases. In both cases, it is essential to comprehend the particle transport and subsequent deposition. The aim of this PhD thesis is to obtain new experimental data on particle deposition and elucidate the effect of particle shape and flow rate on deposition. The deposition of porous and fibrous particles in the realistic replica of human respiratory airways was studied. The porous particles were produced by various methods, such as spray–drying or liquid–liquid interface crystallization. The produced particles were introduced into the replica and the subsequent deposition was detected using spectrophotometry. The fibrous particles were produced by crushing glass wool material. To narrow the fiber size distribution, the resulting fibers were sieved and then classified according to their length using a dielectrophoretic classifier. The fiber deposition inside the replica was detected using phase–contrast microscopy. To speed–up this analysis, an in–house software based on image processing was developed. The results were utilized to calculate deposition characteristics. The deposition efficiency of both particle types increased with increasing Stokes number indicating a significant role of impaction. Comparing their deposition efficiency to that of spherical particles, porous particles exhibited similar deposition efficiencies, however, fibers deposited less efficiently than spherical particles having the same Stokes number. As the boundary conditions were sufficiently described and the replica is available in a digital format, the data can be also employed in validation of numerical simulations.

102. In Vitro Study of the Effect of Particle Characteristics and Flow Rate on Regional Deposition in Human Airways

Author

Jedelský, Jan, Adamec, Vladimír, Farkas, Árpád, Bělka, Miloslav, Jedelský, Jan, Adamec, Vladimír, Farkas, Árpád, and Bělka, Miloslav

Abstract

Dlouhodobé vdechování částic může přispívat ke vzniku nebo zhoršení nejrůznějších plicních onemocnění. Na druhou stranu, vdechování léčiv je často používanou metodou podávání léků proti astmatu a jiným nemocem dýchacího ústrojí. V obou případech je důležité dobře porozumět mechanismům, na jejichž základě funguje pohyb částic a jejich usazování v dýchacích cestách. Cílem této disertační práce bylo získat nová experimentální data depozice částic a analyzovat vliv tvaru částic a průtoku vzduchu na depozici. Byla studována depozice porézních a vláknitých částic v realistickém modelu dýchacích cest. Porézní částice byly vyrobeny různými metodami, např. sprejovým sušením nebo metodou krystalizace. Takto vyrobené částice byly použity při depozičních experimentech. Detekce částic byla provedena pomocí UV/VIS spektrofotometrie. Vláknitý aerosol byl vytvořen rozdrcením skelné vaty. Takto vzniklé vláknité částice byly několikrát prosety přes řadu sít a dále roztříděny podle délky pomocí klasifikátoru pracujícím na principu dielektroforézy. Následná depozice byla vyhodnocena použitím mikroskopie s fázovým kontrastem. Ke zrychlení analýzy byl vyvinut program, který dokáže na základě analýzy obrazu najít a spočítat vlákna. Výsledky experimentu byly použity k určení depozičních charakteristik. S jejich pomocí pak byl kvantifikován vliv tvaru částic a průtoku na míru usazování. Depoziční účinnost částic rostla v závislosti na Stokesově čísle, což poukazuje na vliv setrvačnosti při usazování částic. Bylo prokázáno, že depoziční účinnost porézních částic je podobná té u částic kulových při stejném Stokesově čísle. Vláknité částice se usazovali méně efektivně v porovnání s kulovými částicemi majícími stejné Stokesovo číslo. Jelikož byly okrajové podmínky dostatečně popsány a model plic je k dispozici i v digitální podobě, je možné data použít k validaci výsledků numerických simulací., Inhalation of airborne particulate matter can trigger or exacerbate pre–existing lung conditions. On the other hand, inhalation of aerosolized medicaments can be used for treatment of various respiratory or systemic diseases. In both cases, it is essential to comprehend the particle transport and subsequent deposition. The aim of this PhD thesis is to obtain new experimental data on particle deposition and elucidate the effect of particle shape and flow rate on deposition. The deposition of porous and fibrous particles in the realistic replica of human respiratory airways was studied. The porous particles were produced by various methods, such as spray–drying or liquid–liquid interface crystallization. The produced particles were introduced into the replica and the subsequent deposition was detected using spectrophotometry. The fibrous particles were produced by crushing glass wool material. To narrow the fiber size distribution, the resulting fibers were sieved and then classified according to their length using a dielectrophoretic classifier. The fiber deposition inside the replica was detected using phase–contrast microscopy. To speed–up this analysis, an in–house software based on image processing was developed. The results were utilized to calculate deposition characteristics. The deposition efficiency of both particle types increased with increasing Stokes number indicating a significant role of impaction. Comparing their deposition efficiency to that of spherical particles, porous particles exhibited similar deposition efficiencies, however, fibers deposited less efficiently than spherical particles having the same Stokes number. As the boundary conditions were sufficiently described and the replica is available in a digital format, the data can be also employed in validation of numerical simulations.

103. arpad farkas, hungarian poetry in translation.

Author

FARKAS, ÁRPÁD

Subjects

LET There be No Silence (Poem), STORY (Poem), WHEN You Come (Poem), FARKAS, Arpad

Abstract

Several poems by Árpád Farkas are presented, translated by Paul Sohar. "Let There be No Silence." First Line: Let wispy little voices spring from blocks; Last Line: hold them in their shapely hand for all to see. "Story." First Line: At exactly two-forty-five; Last Line: in the snow above the Tropic of Capricorn. "When You Come." First Line: I'll spread out the train whistles before you, Last Line: and I'll tell you all about the big joys of small towns.

Published

2018

104. Stochastic Aspects of Primary Cellular Consequences of Radon Inhalation

Author

Szőke, István, Farkas, Árpád, Balásházy, Imre, and Hofmann, Werner

Published

2009

105. Contemporary Crossroads III: Studies in English Applied Linguistics

Author

Farkas, Árpád

Published

2022

106. Nyelvtanulással a boldogulásért

Author

Divéki, Rita, Farkas, Árpád, and Pereszlényi, Anna

Published

2021

107. Creating respiratory pathogen-free environments in healthcare and nursing-care settings: a comprehensive review.

Author

Nagy A, Czitrovszky A, Lehoczki A, Farkas Á, Füri P, Osán J, Groma V, Kugler S, Micsinai A, Horváth A, Ungvári Z, and Müller V

Abstract

Hospital- and nursing-care-acquired infections are a growing problem worldwide, especially during epidemics, posing a significant threat to older adults in geriatric settings. Intense research during the COVID-19 pandemic highlighted the prominent role of aerosol transmission of pathogens. Aerosol particles can easily adsorb different airborne pathogens, carrying them for a long time. Understanding the dynamics of airborne pathogen transmission is essential for controlling the spread of many well-known pathogens, like the influenza virus, and emerging ones like SARS-CoV-2. Particles smaller than 50 to 100 µm remain airborne and significantly contribute to pathogen transmission. This review explores the journey of pathogen-carrying particles from formation in the airways, through airborne travel, to deposition in the lungs. The physicochemical properties of emitted particles depend on health status and emission modes, such as breathing, speaking, singing, coughing, sneezing, playing wind instruments, and medical interventions. After emission, sedimentation and evaporation primarily determine particle fate. Lung deposition of inhaled aerosol particles can be studied through in vivo, in vitro, or in silico methods. We discuss several numerical lung models, such as the Human Respiratory Tract Model, the LUng Dose Evaluation Program software (LUDEP), the Stochastic Lung Model, and the Computational Fluid Dynamics (CFD) techniques, and real-time or post-evaluation methods for detecting and characterizing these particles. Various air purification methods, particularly filtration, are reviewed for their effectiveness in healthcare settings. In the discussion, we analyze how this knowledge can help create environments with reduced PM2.5 and pathogen levels, enhancing safety in healthcare and nursing-care settings. This is particularly crucial for protecting older adults, who are more vulnerable to infections due to weaker immune systems and the higher prevalence of chronic conditions. By implementing effective airborne pathogen control measures, we can significantly improve health outcomes in geriatric settings., (© 2024. The Author(s).)

Published

2024

108. Comparative study of the inhalation parameters of COPD patients through NEXThaler® and Ellipta® dry powder inhalers.

Author

Farkas Á, Horváth A, Réti I, Ilyés N, Havadtői B, Kovács T, Sánta B, Tomisa G, Czaun P, and Gálffy G

Subjects

Male, Female, Humans, Dry Powder Inhalers, Respiratory Aerosols and Droplets, Lung, Administration, Inhalation, Inhalation, Pulmonary Disease, Chronic Obstructive drug therapy

Abstract

The deposition of dry powder aerosol drugs depends on the inhalation parameters of the patients through the inhaler. These data are not directly measured in clinical practice. Their prediction based on the routinely measured spirometric data could help in choosing the appropriate device and optimizing the therapy. The aim of this study was to perform inhalation experiments to find correlations between inhalation parameters of COPD patients through two DPI devices and their native spirometric data, gender, age and disease severity. Another goal was to establish relationships between peak inspiratory flows through NEXThaler® and Ellipta® inhalers and their statistical determinants. Breathing parameters of 113 COPD patients were measured by normal spirometry and while inhaling through the two DPIs. Statistical analysis of the measured data was performed. The average values of peak inspiratory flow through the devices (PIF dev ) were 68.4 L/min and 78.0 L/min for NEXThaler® and Ellipta®, respectively. PIF dev values were significantly higher for males than for females, but differences upon age, BMI and disease severity group were not significant. PIF dev values correlated best with their native spirometric counterparts (PIF) and linear relationships between them were revealed. Current results may be used in the future to predict the success of inhalation of COPD patients through DPI devices, which may help in the inhaler choice. By choosing the appropriate device-drug pair for each patient the lung dose can be increased and the efficiency of the therapy improved. Further results of the clinical study will be the subject of a next publication., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Alpár Horváth, Gábor Tomisa, Balázs Sánta report a relationship with Chiesi Hungary Kft that includes: employment., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

109. The effect of lung emptying before the inhalation of aerosol drugs on drug deposition in the respiratory system.

Author

Farkas Á, Tomisa G, Szénási G, Füri P, Kugler S, Nagy A, Varga J, and Horváth A

Abstract

The amount of drug depositing in the airways depends, among others, on the inhalation manoeuvre and breathing parameters. The objective of this study was to quantify the effect of lung emptying before the inhalation of drugs on the lung doses. Thirty healthy adults were recruited. Their breathing profiles were recorded while inhaling through six different emptied DPI devices without breathe-out and after comfortable or forced exhalation. The corresponding emitted doses and aerosol size distributions were derived from the literature. The Stochastic Lung Model was used to estimate the deposited doses. In general, forceful exhalation caused increased flow rate and inhaled air volume. Increased flow rate led to the increase of the average lung dose for drugs with positive lung dose-flow rate correlation (e.g. Symbicort®: relative increase of 6.7%, Bufomix®: relative increase of 9.2%). For drugs with negative correlation of lung dose with flow rate (all the studied drugs except the above two) lung emptying caused increased (Foster® by 2.7%), almost unchanged (Seebri®, Relvar®, Bretaris®) and also decreased (Onbrez® by 6.6%) average lung dose. It is worth noting that there were significant inter-individual differences, and lung dose of each drug could be increased by a number of subjects. In conclusion, the change of lung dose depends on the degree of lung emptying, but it is also inhaler and drug specific. Forceful exhalation can help in increasing the lung dose only if the above specificities are taken into account., Competing Interests: None., (© 2023 The Authors.)

Published

2023

110. The effect of exhalation before the inhalation of dry powder aerosol drugs on the breathing parameters, emitted doses and aerosol size distributions.

Author

Farkas Á, Tomisa G, Kugler S, Nagy A, Vaskó A, Kis E, Szénási G, Gálffy G, and Horváth A

Abstract

Airway deposition of aerosol drugs is highly dependent on the breathing manoeuvre of the patients. Though incorrect exhalation before the inhalation of the drug is one of the most common mistakes, its effect on the rest of the manoeuvre and on the airway deposition distribution of aerosol drugs is not explored in the open literature. The aim of the present work was to conduct inhalation experiments using six dry powder inhalers in order to quantify the effect of the degree of lung emptying on the inhalation time, inhaled volume and peak inhalation flow. Another goal of the research was to determine the effect of the exhalation on the aerodynamic properties of the drugs emitted by the same inhalers. According to the measurements, deep exhalation before drug inhalation increased the volume of the inhaled air and the average and maximum values of the inhalation flow rate, but the extent of the increase was patient and inhaler specific. For different inhalers, the mean value of the relative increase in peak inhalation flow due to forceful exhalation was between 15.3 and 38.4% (min: Easyhaler®, max: Breezhaler®), compared to the case of normal (tidal) exhalation before the drug inhalation. The relative increase in the inhaled volume was between 36.4 and 57.1% (min: NEXThaler®, max: Turbuhaler®). By the same token, forceful exhalation resulted in higher emitted doses and smaller emitted particles, depending on the individual breathing ability of the patient, the inhalation device and the drug metered in it. The relative increase in the emitted dose varied between 0.2 and 8.0% (min: Foster® NEXThaler®, max: Bufomix® Easyhaler®), while the relative enhancement of fine particle dose ranged between 1.9 and 30.8% (min: Foster® NEXThaler®, max: Symbicort® Turbuhaler®), depending on the inhaler. All these effects and parameter values point toward higher airway doses due to forceful exhalation before the inhalation of the drug. At the same time, the present findings highlight the necessity of proper patient education on the importance of lung emptying, but also the importance of patient-specific inhaler-drug pair choice in the future., Competing Interests: The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Arpad Farkas reports financial support was provided by Centre for Energy Research. Gabor Tomisa, Alpar Horvath, Georgina Szenasi reports a relationship with Chiesi Hungary Kft that includes: employment., (© 2023 The Authors.)

Published

2023

111. Health effects of cigarettes, electronic cigarettes and waterpipes

Author

Farkas Á, Tomisa G, Kis E, and Horváth A

Subjects

Humans, SARS-CoV-2, COVID-19, Electronic Nicotine Delivery Systems, Smoking Water Pipes, Tobacco Products, Water Pipe Smoking

Abstract

Összefoglaló. A dohányzás káros hatásainak vizsgálata hosszú ideje az orvostudomány egyik legintenzívebben kutatott területe. A nagy tudományos érdeklődésnek köszönhetően ma már meggyőző evidenciák állnak rendelkezésre a hagyományos cigaretta használatának számos negatív hatásáról. Ezzel ellentétben a sokkal később bevezetett helyettesítő termékek veszélyeiről lényegesen kevesebbet tudunk. E körbe tartozik a manapság egyre népszerűbb elektromos cigaretta is, amelyre egyre több, egészségügyi kockázatot felmérő munka fókuszál. Ugyanakkor a több évszázados múltra visszatekintő és a világ bizonyos helyein sokáig népszerű vízipipa érdekes esetnek számít, mivel használóinak száma a nyugati világban az utóbbi időben megugrott, de az emberre gyakorolt hatása számos ponton még vita tárgyát képezi. A jelen munka célja, hogy a hazai és a nemzetközi szakirodalom alapján feltérképezze a hagyományos cigaretta, az elektromos cigaretta és a vízipipa fontosabb egészségügyi hatásait, és rámutasson azokra a kapcsolódó területekre, ahol további kutatások szükségesek. A szakirodalmi áttekintés során a különböző publikációs adatbázisokban fellelhető tudományos cikkeket elemeztük. A megvizsgált szakirodalom alapján a tartós dohányzásnak bizonyítottan a szív-ér rendszert és a légzőrendszert károsító hatása van, de növekvő számú bizonyíték utal a neurológiai káros hatásokra és a gasztroenterológiai hatásokra is. Ugyanakkor az elektromos cigaretta és a vízipipa esetében a bizonyított akut hatások mellett a hosszú távú hatásokat illetően további intenzív kutatásokra van szükség. Az elektromos cigaretta és a vízipipa esetében a hosszú távú hatások kapcsán a meggyőző evidencia hiánya semmiképpen nem jelenti azt, hogy ezen termékeket kockázatmentesnek kellene tekinteni, sőt a pulmonológusoknak és a döntéshozóknak mindent meg kell tenniük annak érdekében, hogy valamennyi dohánytermék törvényi szabályozása azok használatának visszaszorítását célozza. A kérdés fontosságának a COVID-19-pandémia különös aktualitást ad. Orv Hetil. 2021; 162(3): 83-90. Summary. Revealing the health effects associated with smoking has been in the focus of intense research for decades. Due to these research efforts, there is a convincing evidence regarding the negative effects of conventional cigarettes. However, much less is known about the replacement products such as electronic cigarettes. Moreover, the effects of waterpipes are also not fully explored, in spite of their long history. The scope of the present work is to survey the open literature to map the knowledge related to the health effects of conventional cigarettes, e-cigarettes and waterpipes. The analysis of the related scientific literature was performed based on papers retrieved in large publication repositories. Based on the reviewed literature, long-term smoking has demonstrated adverse effects on the respiratory as well as the heart and circulatory systems. In addition, the correlation between cigarette smoking and some gastroenterological and neurological diseases is also increasingly evident. By the same token, though the acute effects of e-cigarette and waterpipe are well documented, the protracted effects are still to be explored. The lack of pertinent information regarding the late effects of e-cigarette and hookah does not imply that there is no health risk associated with their consumption. On the contrary, in addition to the regular antismoke measures, pulmonologists and policy makers should do everything to lower the consumption of these alternative products. Orv Hetil. 2021; 162(3): 83-90.

Published

2021

112. Experimental and computational study of the effect of breath-actuated mechanism built in the NEXThaler ® dry powder inhaler.

Author

Farkas Á, Lewis D, Church T, Tweedie A, Mason F, Haddrell AE, Reid JP, Horváth A, and Balásházy I

Subjects

Adrenal Cortex Hormones administration & dosage, Adrenal Cortex Hormones chemistry, Anti-Asthmatic Agents chemistry, Asthma metabolism, Beclomethasone administration & dosage, Beclomethasone chemistry, Bronchodilator Agents administration & dosage, Bronchodilator Agents chemistry, Formoterol Fumarate administration & dosage, Formoterol Fumarate chemistry, Humans, Lung metabolism, Particle Size, Respiration, Anti-Asthmatic Agents administration & dosage, Asthma drug therapy, Dry Powder Inhalers, Models, Biological

Abstract

The breath-actuated mechanism (BAM) is a mechanical unit included in NEXThaler ® with the role of delaying the emission of the drug until the inhalation flow rate of the patient is sufficiently high to detach the drug particles from their carriers. The main objective of this work was to analyse the effect of the presence of BAM on the size distribution of the emitted drug and its airway deposition efficiency and distribution. Study of the hygroscopic growth of the emitted drug particles and its effect on the deposition was another goal of this study. Size distributions of Foster ® NEXThaler ® drug particles emitted by dry powder inhalers with and without BAM have been measured by a Next Generation Impactor. Three characteristic inhalation profiles of asthmatic patients (low, moderate and high flow rates) were used for both experimental and modelling purposes. Particle hygroscopic growth was determined by a new method, where experimental measurements are combined with simulations. Upper airway and lung deposition fractions were computed assuming 5s and 10s breath-hold times. By the inclusion of BAM the fine particle fraction of the steroid component increased from 24 to 30% to 47-51%, while that of bronchodilator from 25-34% to 52-55%. The predicted upper airway steroid and bronchodilator doses decreased from about 60% to 35-40% due to BAM. At the same time, predicted lung doses increased from about 20%-35% (steroid) and from 22% to 38% (bronchodilator) for the moderate flow profile and from about 25% to 40% (steroid) and from 29% to 47% (bronchodilator) for the high inhalation flow profile. Although BDP and FF upper airway doses decreased by a factor of about two when BAM was present, lung doses of both components were about the same in the BAM and no-BAM configurations at the weakest flow profile. However, lung dose increased by 2-3% even for this profile when hygroscopic growth was taken into account. In conclusion, the NEXThaler ® BAM mechanism is a unique feature enabling high emitted fine particle fraction and enhanced drug delivery to the lungs., (Copyright © 2017 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2017