Kinetic modeling of nicotine in mainstream cigarette smoking

Kibet, Joshua K.; Kurgat, Caren; Limo, Samuel C.; Rono, Nicholas; Bosire, Josephate

doi:10.1186/s13065-016-0206-8

Cited by 18 publications

(13 citation statements)

References 51 publications

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“…The concentration of oxygen in the oxidative pyrolysis experiments was kept low to optimize the formation of molecular products. Generally, fractional pyrolysis is applied as an experimental technique in which the same sample is continuously pyrolyzed at each pyrolysis temperature [19]. This is a selective in situ conversion of biopolymers to molecular products [6].…”

Section: Materials and Experimental Proceduresmentioning

confidence: 99%

Dioxin and dibenzofuran like molecular analogues from the pyrolysis of biomass materials—the emerging challenge in bio-oil production

et al. 2021

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Introduction The aggressive search for renewable energy resources and essential pyrosynthetic compounds has marked an exponential rise in the thermal degradation of biomass materials. Consequently, clean and sustainable transport fuels are increasingly desirable in a highly industrialized economy, for energy security and environmental protection. For this reason, biomass materials have been identified as promising alternatives to fossil fuels despite the challenges resulting from the possible formation of toxic nitrogen-based molecules during biomass degradation. In order to understand the free radical characteristic challenges facing the use of bio-oil, a brief review of the effects of free radicals in bio-oil is presented. Methodology Pyrolysis was conducted in a tubular flow quartz reactor at a residence time of 2 s at 1 atm. pressure, for a total pyrolysis time of 5 min. The thermal degradation of biomass components was investigated over the temperature range of 200 to 700 °C typically in 50 °C increments under two reaction conditions; pyrolysis in N2 and oxidative pyrolysis in 5% O2 in N2. The pyrolysate effluent was analysed using a Gas chromatograph hyphenated to a mass selective detector (MSD). Results The yield of levoglucosan in the pyrolysis of cellulose in the entire pyrolysis temperature range was 68.2 wt % under inert conditions and 28.8 wt % under oxidative conditions. On the other hand, formaldehyde from pyrolysis of cellulose yielded 4 wt % while that from oxidative pyrolysis was 7 wt % translating to ⁓ 1.8 times higher than the yield from pyrolysis. Accordingly, we present for the first time dioxin-like and dibenzofuran-like nitrogenated analogues from an equimassic pyrolysis of cellulose and tyrosine. Levoglucosan and formaldehyde were completely inhibited during the equimassic pyrolysis of cellulose and tyrosine. Conclusion Clearly, any small amounts of N-biomass components such as amino acids in cellulosic biomass materials can inhibit the formation of levoglucosan–a major constituent of bio-oil. Overall, a judicious balance between the production of bio-oil and side products resulting from amino acids present in plant matter should be taken into account to minimize economic losses and mitigate against negative public health concerns.

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Section: Materials and Experimental Proceduresmentioning

confidence: 99%

Dioxin and dibenzofuran like molecular analogues from the pyrolysis of biomass materials—the emerging challenge in bio-oil production

et al. 2021

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“…In order to investigate the nature of molecular products for optimization for clean energy combustion, different binary mixtures in the ratio of 1:1, 3:2 and 2:3 volume were separately introduced into a pyrolysis reactor. Croton megalocarpus biodiesel and fossil diesel were mixed and placed in a quartz reactor of volume 7.56 cm 3 housed in a furnace (Thermo-Scientific Inc., USA) [21,35]. Pyrolysis was conducted at an optimum temperature of 500 °C under a flow of nitrogen at a residence time of 5 s at 1 atmosphere, as model pyrolysis conditions in the reactor ideally representative of the conditions inside a combustion engine.…”

Section: Co-pyrolysis Of Croton Megalocarpus Biodiesel and Petroleum mentioning

confidence: 99%

“…1 The reactor assembly [21] siloxane (30 m × 250 µm × 0.25 µm). The port injector temperature was set at 250 °C to vaporize organic components to be amenable for GCMS analysis [35]. The carrier gas was ultra-high pure (UHP) helium (99.999%) and the flow rate was 3.3 mL min −1 .…”

Section: Gcms Identification Of Molecular Productsmentioning

confidence: 99%

Optimization of Binary Mixtures of Biodiesel and Fossil Diesel for Clean Energy Combustion

2019

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There is an urgent interest initiated to develop clean energy resources with the aim of reducing exposure to environmental pollutants and explore model fuels that can hasten the achievement of clean energy combustion. This work investigates various ratios of biodiesel and commercial diesel in order to propose model binary fuels for clean energy combustion. Accordingly, diesel blends of ratios 1:1, 3:2 and 2:3 were each pyrolyzed at a contact time of 5 s in a quartz reactor at 1 atmosphere pressure. A model temperature of 500 °C was explored in these experiments. The charcoal content for pure fossil diesel was compared with the binary diesel residue. Gas-phase molecular components were determined using Gas chromatography (GC) coupled to a mass selective detector (MSD). Elemental composition of thermal char was determined using Smart Elemental Analyzer. Radical intensities for the three types of char (biochar, bio-fossil char, and fossil char) were measured using an X-band electron paramagnetic resonance spectrometer. It was noted that at a ratio of 2:3 (Biodiesel: Fossil diesel), harmful molecular products reduced significantly, 76-99%. Elemental analysis data indicated that the carbon content from commercial diesel was very high (≈ 70.61%) as compared to approximately 53% for biodiesel-fossil diesel mixture in the same ratio 2:3. Interestingly, the free radical content was reduced by nearly 50% in favour of the biodiesel/fossil diesel mixture. These results are encouraging and suggest that a better optimized fuel mixture has been found for better clean energy combustion.

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“…Formation of smoke from a burning cigarette depends on a series of mechanisms, including generation of products by pyrolysis and combustion, aerosol formation, and physical mass transfer processes [ 10 ]. Tobacco smoke is a very complex cocktail consisting of over 6000 compounds representative of a chemical reactor where several intricate chemical processes take place during pyrolysis [ 11 – 15 ]. The mainstream smoke emitted from the mouth end of a burning cigarette is mainly produced by combustion and pyrolysis reactions as well as distillation processes in the burning tip of the cigarette when the cigarette is puffed out [ 16 ].…”

Section: Introductionmentioning

confidence: 99%

“…Although there are many complex parameters at play during cigarette smoking such as the gas-phase/liquid interface, we believe this study may simulate the characteristic behaviour of the average particulate size deposited in the lung tissues of cigarette smokers. Additionally, this contribution is part our sister articles on tobacco research aimed at providing an important piece of knowledge towards understanding tobacco [ 15 , 5 ]. Ultimately, tobacco smoke particulates and radicals are well established xenobiotics and eco-toxicants.…”

Section: Introductionmentioning

confidence: 99%

Surface bound radicals, char yield and particulate size from the burning of tobacco cigarette

Jebet

Kibet

Ombaka

et al. 2017

Chemistry Central Journal

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BackgroundTobacco smoke is a toxic gas-phase cocktail consisting of a broad range of organics, and free radical intermediates. The formation of smoke from a burning cigarette depends on a series of mechanisms, including generation of products by pyrolysis and combustion, aerosol formation, and physical mass transfer processes.MethodsThe current study simulates the deposition of particulate matter on the human lung surface by trapping the tobacco smoke particulates in situ on silica gel. To mimic this phenomenon, the cigarette was smoked directly on siliga gel. The surface morphology of smoke condensate trapped on silica gel, and pure silica gel (control) was investigated using a scanning electron microscope (SEM). Electron paramagnetic resonance (EPR) was used to explore the presence of free radicals on the particulate matter trapped on silica. Standard procedures for cigarette smoking (ISO 3402:1999) were adopted. The char yields of tobacco cigarette in the temperature range 200–700 °C was also investigated in an inert atmosphere using a quartz reactor.ResultsSEM images showed the surface morphology of pure silica gel was smooth while silica gel on which cigarette smoke was smoked on contained particulates of various sizes. Generally, the particulate size of cigarette smoke adsorbed on silica was found to be 2.47 ± 0.0043 µm (~PM2.5). Electron paramagnetic resonance (EPR) results showed a g-value of 2.0037 typically that of a carbon-centred radical.ConclusionsIt is therefore evident from this investigation that cigarette smoke contains surface bound radicals considered harmful to the health of cigarette smokers. The particulate size of tobacco smoke (PM2.5) can impact severely on the lives of the cigarette smoking community because of its near ultrafine nature. This significantly small particulate size in cigarette smoke can be inhaled deeper into the lungs thus causing serious cell injury and possible tumour growth in addition to other grave diseases.Graphical abstractCigarette smoking and analytical techniques employed in this study

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Kinetic modeling of nicotine in mainstream cigarette smoking

Cited by 18 publications

References 51 publications

Dioxin and dibenzofuran like molecular analogues from the pyrolysis of biomass materials—the emerging challenge in bio-oil production

Dioxin and dibenzofuran like molecular analogues from the pyrolysis of biomass materials—the emerging challenge in bio-oil production

Optimization of Binary Mixtures of Biodiesel and Fossil Diesel for Clean Energy Combustion

Surface bound radicals, char yield and particulate size from the burning of tobacco cigarette

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