Your search keyword '"Chahan Yeretzian"' showing total 42 results

1. The role of fines in espresso extraction dynamics

Author

Samo Smrke, André Eiermann, and Chahan Yeretzian

Subjects

Coffee, Grinding, Extraction, Espresso, Medicine, Science

Abstract

Abstract The impact of particle size distribution of coffee grounds on espresso extraction was explored. Finely ground coffee for espresso has a characteristically bimodal particle size distribution. For a given median grind size, different grinding technologies can yield a different share of fines (particles

Published

2024

2. Antioxidant Generation during Coffee Roasting: A Comparison and Interpretation from Three Complementary Assays

Author

Sebastian E. W. Opitz, Samo Smrke, Bernard A. Goodman, Marco Keller, Stefan Schenker, and Chahan Yeretzian

Subjects

coffee, antioxidant assays, Folin-Ciocalteu, ABTS, ORAC, flow injection analysis, Chemical technology, TP1-1185

Abstract

Coffee is a major source of dietary antioxidants; some are present in the green bean, whereas others are generated during roasting. However, there is no single accepted analytical method for their routine determination. This paper describes the adaption of three complementary assays (Folin-Ciocalteu (FC), ABTS and ORAC) for the routine assessment of antioxidant capacity of beverages, their validation, and use for determining the antioxidant capacities of extracts from coffee beans at different stages in the roasting process. All assays showed a progressive increase in antioxidant capacity during roasting to a light roast state, consistent with the production of melanoidins having a higher antioxidant effect than the degradation of CGAs. However, the three assays gave different numbers for the total antioxidant capacity of green beans relative to gallic acid (GA), although the range of values was much smaller when chlorogenic acid (CGA) was used as reference. Therefore, although all three assays indicated that there was an increase in antioxidant activity during coffee roasting, and the large differences in responses to GA and CGA illustrate their different sensitivities to different types of antioxidant molecule.

Published

2014

3. Freshness Indices of Roasted Coffee: Monitoring the Loss of Freshness for Single Serve Capsules and Roasted Whole Beans in Different Packaging

Author

Alexia N. Glöss, Barbara Schönbächler, Markus Rast, Louis Deuber, and Chahan Yeretzian

Subjects

Coffee, Freshness, Gas chromatography, Single serve capsule systems, Chemistry, QD1-999

Abstract

With the growing demand for high-quality coffee, it is becoming increasingly important to establish quantitative measures of the freshness of coffee, or the loss thereof, over time. Indeed, freshness has become a critical quality criterion in the specialty coffee scene, where the aim is to deliver the most pleasant flavor in the cup, from highest quality beans. A series of intensity ratios of selected volatile organic compounds (VOC) in the headspace of coffee (by gas chromatography–mass spectrometry) were revisited, with the aim to establish robust indicators of freshness of coffee – called freshness indices. Roasted whole beans in four different packaging materials and four commercial capsule systems from the Swiss market were investigated over a period of up to one year of storage time. These measurements revealed three types of insight. First, a clear link between barrier properties of the packaging material and the evolution of selected freshness indices was observed. Packaging materials that contain an aluminum layer offer better protection. Second, processing steps prior to packaging are reflected in the absolute values of freshness indices. Third, differences in the standard deviations of freshness-indices for single serve coffee capsule systems are indicative of differences in the consistency among systems, consistency being an important quality attribute of capsules.

Published

2014

4. On-Line Process Control of the Roast Degree of Coffee

Author

Flurin Wieland, Alexia N. Gloess, Marco Keller, Andreas Wetzel, Stefan Schenker, and Chahan Yeretzian

Subjects

Coffee, On-line process control, Principle component analysis (pca), Proton-transfer-reaction time-of-flight mass spectrometry (ptr-tof-ms), Roasting, Chemistry, QD1-999

Published

2012

5. Modulation of aroma release of instant coffees through microparticles of roasted coffee oil

Author

Rodolfo Campos Zanin, Samo Smrke, Fabio Yamashita, Louise Emy Kurozawa, and Chahan Yeretzian

Subjects

01 natural sciences, Coffee, Mass Spectrometry, Analytical Chemistry, Instant cappuccino, Ptr tof ms, 0404 agricultural biotechnology, Plant Oils, Volatile organic compound, Food science, Microencapsulation, Aroma, PTR-ToF-MS, chemistry.chemical_classification, Volatile Organic Compounds, biology, 010401 analytical chemistry, Spray drying, food and beverages, Soluble coffee, 04 agricultural and veterinary sciences, General Medicine, biology.organism_classification, 040401 food science, Plant oil, 0104 chemical sciences, Odorant, chemistry, 663: Getränketechnologie, Odorants, Burst-effect, Proton, Signal intensity, Protons, Volatilization, Volatility (chemistry), Intensity (heat transfer), Food Science, Instant

Abstract

We report, on the successful addition of spray-dried microparticles containing roasted coffee oil, to soluble coffee (SC) and instant cappuccino (IC), to increase and tailor aroma release. Using PTR-ToF-MS (Proton Transfer Reaction Time-of-Flight Mass Spectrometry), five parameters were defined from time series intensity for each VOC, to compare the performance of different products: total area under the curve (AUC), area under the curve of burst (AUC-burst), maximum signal intensity, final intensity (5 min), and ratio AUC-burst/AUC. Microparticles with higher loads of roasted coffee oil were effective in increasing aroma intensity in SC while, for IC, all loads of microparticles improved aroma intensity. Volatility drove the VOC release in SC, and volatility and polarity for IC. Most compounds reached maximum headspace concentration in < 16 s upon start of reconstitution. These results open new perspectives for the development of instant coffee products and demonstrate their unique aroma release characteristics.

Published

2020

6. Impact of consumer behavior on furan and furan-derivative exposure during coffee consumption. A comparison between brewing methods and drinking preferences

Author

Chahan Yeretzian and Anja Rahn

Subjects

Coffee consumption, Coffee, 01 natural sciences, Gas Chromatography-Mass Spectrometry, Analytical Chemistry, chemistry.chemical_compound, 0404 agricultural biotechnology, Furan, Humans, Cooking, Food science, Furans, Disposable cup, Chemistry, Dietary exposure, business.industry, 010401 analytical chemistry, Temperature, 04 agricultural and veterinary sciences, General Medicine, 040401 food science, 0104 chemical sciences, Fully automatic, Brewing, business, 664: Lebensmitteltechnologie, Food Science

Abstract

This study examined the influence of consumer behavior on furan, 2-methylfuran, 3-methylfuran, 2,5-dimethylfuran and 2,3-dimethylfuran exposure in coffee. Coffees brewed using a filter, fully automatic, capsule machine or reconstituted instant coffee were found to have a significant different cup concentrations of furan derivatives. Coffee brewed with the fully automatic machine contained the highest furan and furan derivative concentrations (99.05 µg/L furan, 263.91 µg/L 2-methylfuran, 13.15 µg/L 3-methylfuran and 8.44 µg/L 2,5-dimethylfuran) whereas soluble coffee did not contain detectable levels, thereby contributing least to a consumer’s dietary exposure. Furan and furan derivative concentrations were found to decrease significantly upon cooling, reducing consumer exposure by 8.0–17.2 % on average once the coffee reached drinking temperature 55–60 °C, in ceramic cups. Serving coffee in a ceramic or disposable cup were found to influence the cooling dynamics of the coffee but did not statistically influence the consumers exposure at a given temperature.

Published

2019

7. Quantitative assessment of specific defects in roasted ground coffee via infrared-photoacoustic spectroscopy

Author

Michael Edelmann, Chahan Yeretzian, Patrícia Valderrama, Maria Brígida dos Santos Scholz, Paulo Henrique Março, and Rafael Carlos Eloy Dias

Subjects

Quality Control, Materials science, Food Handling, Infrared, Blends of coffee, Species of coffee, Coffea, FTIR-PAS, Coffea canephora, Coffee, 01 natural sciences, Analytical Chemistry, Photoacoustic Techniques, 0404 agricultural biotechnology, Spectroscopy, Fourier Transform Infrared, Partial least squares regression, Food Quality, Least-Squares Analysis, Spectroscopy, Photoacoustic spectroscopy, Chemometric methods, Principal Component Analysis, biology, Coffea arabica, 010401 analytical chemistry, 04 agricultural and veterinary sciences, General Medicine, biology.organism_classification, Linear discriminant analysis, 040401 food science, 0104 chemical sciences, Fourier Transform Infrared, 663: Getränketechnologie, Seeds, Principal component analysis, Biological system, Coffee defects, Food Analysis, Food Science

Abstract

Chemical analyses and sensory evaluation are the most applied methods for quality control of roasted and ground coffee (RG). However, faster alternatives would be highly valuable. Here, we applied infrared-photoacoustic spectroscopy (FTIR-PAS) on RG powder. Mixtures of specific defective beans were blended with healthy (defect-free) Coffea arabica and Coffea canephora bases in specific ratios, forming different classes of blends. Principal Component Analysis allowed predicting the amount/fraction and nature of the defects in blends while partial Least Squares Discriminant Analysis revealed similarities between blends (=samples). A successful predictive model was obtained using six classes of blends. The model could classify 100% of the samples into four classes. The specificities were higher than 0.9. Application of FTIR-PAS on RG coffee to characterize and classify blends has shown to be an accurate, easy, quick and “green” alternative to current methods.

Published

2018

8. Novel experimental approach to study aroma release upon reconstitution of instant coffee products

Author

Samo Smrke, Fabio Yamashita, Louise Emy Kurozawa, Rodolfo Campos Zanin, and Chahan Yeretzian

Subjects

Vapor pressure, Kinetics, Instant coffee, Mass spectrometry, 01 natural sciences, Coffee, Mass Spectrometry, Analytical Chemistry, Burst, Fast release, 0404 agricultural biotechnology, On-line, Real time analysis, Aroma, PTR-ToF-MS, Volatile Organic Compounds, Aqueous solution, Chromatography, biology, Chemistry, 010401 analytical chemistry, Water, food and beverages, 04 agricultural and veterinary sciences, General Medicine, biology.organism_classification, 040401 food science, 0104 chemical sciences, Solubility, 663: Getränketechnologie, Odorants, Protons, Food Analysis, Food Science, Instant

Abstract

This study presents an experimental approach to study the kinetics and fast release of volatile organic compounds (VOCs) upon reconstitution of instant coffee products. A sampling setup coupled to PTR-ToF-MS (Proton Transfer Reaction Time-of-Flight Mass Spectrometry) for the automated and reproducible reconstitution of instant coffee products was developed to monitor the dynamic release of VOCs. A rapid release of aroma compounds was observed in the first seconds upon hot water addition ("aroma burst"), followed by subsequent decrease in headspace (HS) intensities over the course of analysis. Differences in time-intensity release profiles of individual VOCs were correlated to their Henry's Law constant, vapor pressure and water solubility. The setup and approach proposed here have shown to be sensitive and to respond to fast dynamic changes in aroma release. It allows studying VOCs release upon reconstitution and supports the development of novel technologies and formulations for instant products with improved aroma release properties.

Published

2020

9. Extraction kinetics of coffee aroma compounds using a semi-automatic machine: On-line analysis by PTR-ToF-MS

Author

Alexia N. Gloess, Chahan Yeretzian, Ralf Zimmermann, Jose Sanchez Lopez, and Marco Wellinger

Subjects

Kinetics, Extraction, 01 natural sciences, Coffee, Espresso, Ptr tof ms, 0404 agricultural biotechnology, On-line, Physical and Theoretical Chemistry, Instrumentation, Aroma, Spectroscopy, Chromatography, biology, Chemistry, 010401 analytical chemistry, Extraction (chemistry), 04 agricultural and veterinary sciences, biology.organism_classification, Condensed Matter Physics, 040401 food science, PTR-MS, 0104 chemical sciences, Water temperature, 663: Getränketechnologie, Coffee machine, Espresso coffee, Semi automatic

Abstract

The hot-water extraction process used to make an espresso coffee is affected by a large number of factors. A proper understanding of how these factors impact the profile of the final cup is important to the quality of an espresso coffee. This work examines the effect of water temperature and pressure on the extraction kinetics of volatile organic compounds (VOCs) in coffee. This was achieved by on-line monitoring of the volatiles directly from the coffee flow, using proton-transfer-reaction time-of-flight mass-spectrometry (PTR-ToF-MS). Using hierarchical cluster analysis (HCA), tentatively identified compounds were grouped into 5 families according to their time–intensity profiles. VOCs grouped into each family had similar physicochemical properties while polarity was found to be one of the main forces driving VOC extraction kinetics. The effect of pressure was studied by extracting espresso coffees at 7, 9 and 11 bar. A pressure of 11 bar resulted in an increased extraction of volatiles over the entire extraction time (25 s). To study the effect of temperature, espresso coffees were extracted at 82, 92 and 96 °C. An increase in temperature produced a significant increase in the extraction of VOCs, especially during the last part of the extraction. The effect of temperature on extractability was more pronounced for the less polar compounds.

Published

2016

10. Influence of lipid content and stirring behaviour on furan and furan derivative exposure in filter coffee

Author

Chahan Yeretzian, Anja Rahn, and Nina Fankhauser

Subjects

Chromatography, 010401 analytical chemistry, Temperature, 04 agricultural and veterinary sciences, General Medicine, 040401 food science, 01 natural sciences, Coffee, Lipids, Gas Chromatography-Mass Spectrometry, 0104 chemical sciences, Analytical Chemistry, chemistry.chemical_compound, 0404 agricultural biotechnology, chemistry, Filter (video), 663: Getränketechnologie, Furan, Lipid content, Furans, Derivative (chemistry), Food Science

Abstract

Coffee has been determined as the dominant source of furan within an adult’s diet. This study investigates the influence of coffee condiment use and stirring on the retention of furan. Three condiment lipid compositions were investigated, 0%, 3.5% and 35%, and kept at either 4 °C, 20 °C or 70 °C before addition to a freshly brewed cup of filter coffee which was subsequently mechanically stirred at three intensities, not stirred and moderately or heavily stirred. While five furans were monitored, furan, 2-methylfuran, 3-methylfuran, 2,5-dimethylfuran and 2,3-dimethylfuran, only two were quantifiable: furan and 2-methylfuran. Increasing condiment lipid concentration significantly increased retention of furan and 2-methylfuran, whereas stirring the coffee significantly increased furan release. A condiment temperature of 70 °C was found to significantly increase furan release.

Published

2018

11. Time-Resolved Gravimetric Method To Assess Degassing of Roasted Coffee

Author

Chahan Yeretzian, Tomonori Suzuki, Franz Balsiger, Sebastian E. W. Opitz, Marco Wellinger, and Samo Smrke

Subjects

0301 basic medicine, Gravimetry, Hot Temperature, Food Handling, Sensation, Fraction (chemistry), Coffea, Shelf life, Coffee, 03 medical and health sciences, chemistry.chemical_compound, 0404 agricultural biotechnology, Freshness, Degassing, Food Preservation, Roasting, 030109 nutrition & dietetics, Chemistry, Extraction (chemistry), Food preservation, Food Packaging, 04 agricultural and veterinary sciences, General Chemistry, Carbon Dioxide, Pulp and paper industry, 040401 food science, Food packaging, Kinetics, Environmental chemistry, Carbon dioxide, Seeds, Gravimetric analysis, General Agricultural and Biological Sciences, 664: Lebensmitteltechnologie

Abstract

During the roasting of coffee, thermally driven chemical reactions lead to the formation of gases, of which a large fraction is carbon dioxide (CO2). Part of these gases is released during roasting while part is retained inside the porous structure of the roasted beans and is steadily released during storage or more abruptly during grinding and extraction. The release of CO2 during the various phases from roasting to consumption is linked to many important properties and characteristics of coffee. It is an indicator for freshness, plays an important role in shelf life and in packaging, impacts the extraction process, is involved in crema formation, and may affect the sensory profile in the cup. Indeed, and in view of the multiple roles it plays, CO2 is a much underappreciated and little examined molecule in coffee. Here, we introduce an accurate, quantitative, and time-resolved method to measure the release kinetics of gases from whole beans and ground coffee using a gravimetric approach. Samples were placed in a container with a fitted capillary to allow gases to escape. The time-resolved release of gases was measured via the weight loss of the container filled with coffee. Long-term stability was achieved using a customized design of a semimicro balance, including periodic and automatic zero value measurements and calibration procedures. The novel gravimetric methodology was applied to a range of coffee samples: (i) whole Arabica beans and (ii) ground Arabica and Robusta, roasted to different roast degrees and at different speeds (roast air temperatures). Modeling the degassing rates allowed structural and mechanistic interpretation of the degassing process.

Published

2017

12. Evidence of different flavour formation dynamics by roasting coffee from different origins: On-line analysis with PTR-ToF-MS

Author

Samo Smrke, Chahan Yeretzian, Jose Sanchez Lopez, Flurin Wieland, Sandra Bongers, Thomas Koziorowski, Anita Vietri, Barbara Schönbächler, Sergio Petrozzi, and Alexia N. Gloess

Subjects

Flavour, Coffee roasting, Titratable acid, Coffea canephora, Coffee, Coffee variety, Food science, Physical and Theoretical Chemistry, Instrumentation, Spectroscopy, PTR-ToF-MS, Roasting, Roasting profile, Chromatography, biology, Chemistry, Coffea arabica, On-line monitoring, biology.organism_classification, Total dissolved solids, Condensed Matter Physics, 663: Getränketechnologie, Roast degree, Gas chromatography–mass spectrometry

Abstract

Coffees from different origins were roasted to different roast degrees and along varying time temperature roasting profiles. The formation of volatile organic compounds (VOCs) during roasting was analyzed on-line by proton-transfer-reaction time-of-flight mass-spectrometry (PTR-ToF-MS). Coffee samples were Coffea arabica from Colombia, Guatemala (Antigua La Ceiba), Ethiopia (Yirga Cheffe, Djimmah) and Coffea canephora var. robusta from Indonesia (Malangsari). The roasting profiles ranged from high temperature short time (HTST) to low temperature long time (LTLT) roasting, and from medium to dark roast degree. The release dynamics of the on-line monitored VOCs differed for the different coffees and showed a strong modulation with the time–temperature roasting profile. While for Guatemalan coffee the formation of VOCs started relatively early in the roasting process, the VOC formation started much later in the case of Yirga Cheffe and Malangsari. Off-line analysis of the coffee brew augmented the measurements. These included headspace solid phase micro extraction gas chromatography mass spectrometry (HS SPME GC/MS), content of total solids, chlorogenic acids, caffeine, total polyphenols (Folin Ciocalteu), organic acids (ion chromatography), titratable acidity and pH. Some general trends, irrespective of the coffee origin, were observed, such as an increase in pH when going from an HTST to an LTLT profile or from a medium to dark roast degree. Furthermore, a decrease of total headspace intensity was observed from an HTST to an LTLT roasting profile. In general, the changes of the time temperature roasting profiles and/or the roast degree influenced the intensity of the respective coffee constituents as well as their relative composition differently for different coffee origins.

Published

2014

13. Protecting the flavors : freshness as a key to quality

Author

Yves Wyser, Chahan Yeretzian, and Imre Blank

Subjects

Engineering, biology, business.industry, media_common.quotation_subject, 04 agricultural and veterinary sciences, 010402 general chemistry, biology.organism_classification, 040401 food science, 01 natural sciences, Quality, Coffee, Specialty coffee, 0104 chemical sciences, 0404 agricultural biotechnology, Freshness, 663: Getränketechnologie, Quality (business), Food science, business, Aroma profile, Aroma, media_common

Abstract

Since the early days of the specialty coffee movement, freshness has been one of its central pillars. Freshness is best defined as having original unimpaired qualities. In coffee, it is most often seen as freshly roasted, ground within a few days, immediately extracted, and consumed. But despite this pivotal role of freshness for high quality coffee, the objective and scientific measurement of freshness have often been vague and elusive. How can one measure the level of freshness of coffee? In this chapter we will outline two approaches. One is based on the degassing of the freshly roasted coffee and the other on the evolution of its aroma profile during storage. In terms of the evolution of the aroma profile, we will introduce one particular freshness index: the ratio of dimethyl disulfide to methanethiol, suited to assess the evolution of freshness of roasted coffee during storage. Although this ratio has been shown to increase during storage, the speed at which this freshness index increases depends on the packaging and storage temperature. This has opened the possibility to use this index to assess the freshness of roasted coffee and compare the quality of different packaging materials for preserving the freshness of the coffee inside.

Published

2017

14. Understanding the Effects of Roasting on Antioxidant Components of Coffee Brews by Coupling On-line ABTS Assay to High Performance Size Exclusion Chromatography

Author

Sebastian E W, Opitz, Bernard A, Goodman, Marco, Keller, Samo, Smrke, Marco, Wellinger, Stefan, Schenker, and Chahan, Yeretzian

Subjects

Special Issue Articles, Folin–Ciocalteu, coffee, Chromatography, Gel, post‐column derivatisation, food and beverages, Special Issue Article, ORAC, HPSEC, ABTS•+, Chromatography, High Pressure Liquid, Antioxidants, Mass Spectrometry

Abstract

Introduction Coffee is a widely consumed beverage containing antioxidant active compounds. During roasting the phytochemical composition of the coffee bean changes dramatically and highly polymeric substances are produced. Besides chlorogenic acids that are already present in green coffee beans, melanoidins show antioxidant capacity as well. Objective To employ post‐column derivatisation by coupling high performance size exclusion chromatography (HPSEC) to an antioxidant assay to investigate the effect of roasting on the properties of antioxidant active compounds in coffee brews. Methodology We have investigated the antioxidant capacity of Coffea arabica (Arabica) and C. canephora (Robusta) beans that were roasted over the full spectrum of roast conditions (four roasting speeds to three roast degrees) by comparing the results from HPSEC coupled on‐line to the ABTS assay with those from two batch assays, Folin Ciocalteu (FC) and oxygen radical absorbance capacity (ORAC) assay. Results The antioxidant capacity showed a general decrease towards slower and darker roasted coffee for all three assays, indicative of heat degradation of active compounds. Hence, low molecular weight (LMW) compounds such as chlorogenic acids (CGAs) decreased progressively already from relatively mild roasting conditions. In contrast, high molecular weight (HMW) compounds (e.g. melanoidins) increased from light to dark roast degrees with lowering magnitude towards slower roasting profiles. Conclusion By coupling HPSEC on‐line to the ABTS assay we were able to separately quantify the contribution of HMW and LMW compounds to the total antioxidant capacity, increasing our understanding of the roast process. © 2016 The Authors. Phytochemical Analysis Published by John Wiley & Sons Ltd., The composition of green coffee beans is complex, yet roasting adds to this complexity by producing highly polymeric melanoidins. Next to chlorogenic acids melanoidins also show antioxidant capacity, which was measured with batch assays as well as by on‐line coupling to size exclusion chromatography to investigate the roasting effect on the formation and/or degradation of high and low molecular weight compounds. Adding chromatography enabled us to separately quantify antioxidant activity of high and low molecular weight compounds to increase our understanding of the roasting process.

Published

2016

15. Online monitoring of coffee roasting by proton transfer reaction time-of-flight mass spectrometry (PTR-ToF-MS): towards a real-time process control for a consistent roast profile

Author

Alexia N. Gloess, Marco Keller, Andreas Wetzel, Chahan Yeretzian, Flurin Wieland, and Stefan Schenker

Subjects

Volatile Organic Compounds, Time Factors, Resolution (mass spectrometry), Chemistry, Analytical chemistry, Coffee roasting, Gas sensors, Mass spectrometry, Coffee, Online Systems, Biochemistry, Mass Spectrometry, Analytical Chemistry, Degree (temperature), Beverages, Foods, Process analysis, Volume (thermodynamics), 663: Getränketechnologie, Process control, Cooking, Protons, Time-of-flight mass spectrometry, Food Analysis, Roasting

Abstract

A real-time automated process control tool for coffee roasting is presented to consistently and accurately achieve a targeted roast degree. It is based on the online monitoring of volatile organic compounds (VOC) in the off-gas of a drum roaster by proton transfer reaction time-of-flight mass spectrometry at a high time (1Hz) and mass resolution (5,500m/Δm at full width at half-maximum) and high sensitivity (better than parts per billion by volume). Forty-two roasting experiments were performed with the drum roaster being operated either on a low, medium or high hot-air inlet temperature (= energy input) and the coffee (Arabica from Antigua, Guatemala) being roasted to low, medium or dark roast degrees. A principal component analysis (PCA) discriminated, for each one of the three hot-air inlet temperatures, the roast degree with a resolution of better than ±1 Colorette. The 3D space of the three first principal components was defined based on 23 mass spectral profiles of VOCs and their roast degree at the end point of roasting. This provided a very detailed picture of the evolution of the roasting process and allowed establishment of a predictive model that projects the online-monitored VOC profile of the roaster off-gas in real time onto the PCA space defined by the calibration process and, ultimately, to control the coffee roasting process so as to achieve a target roast degree and a consistent roasting. Figure Online monitoring of coffee roasting by real-time analysis of the roaster off-gas using PTR-ToF-MS. In a first phase, 42 calibration experiments were conducted at three different roasting temperatures and to three final roast degrees, to generate the 3D space defined by the three first principle components PC1, PC2 and PC3. Inverted triangles mark the dark roast degree, square medium and circle light, respectively. The hot-air inlet temperature is marked as follows: high (black), medium (grey), low (white). The different hot-air inlet temperatures and roast degrees are clearly separated. In a second phase, an online monitored PTR-ToF-MS spectrum of a roasting process was projected onto the 3D space, allowing following in real-time the roasting process and halting the roasting with a precision better that ± 1 Colorette roast degree

Published

2011

16. Proton Transfer Reaction Mass Spectrometry, a Tool for On-Line Monitoring of Acrylamide Formation in the Headspace of Maillard Reaction Systems and Processed Food

Author

Philippe Pollien, Chahan Yeretzian, Imre Blank, and Christian Lindinger

Subjects

Chromatography, Fructose, Mass spectrometry, Coffee, Quality, PTR-MS, Analytical Chemistry, chemistry.chemical_compound, Maillard reaction, symbols.namesake, chemistry, Acrylamide, symbols, Gas chromatography, Asparagine, 664: Lebensmitteltechnologie, Proton-transfer-reaction mass spectrometry, Electron ionization

Abstract

The formation of acrylamide was measured in real time during thermal treatment (120-170 degrees C) of potato as well as in Maillard model systems composed of asparagine and reducing sugars, such as fructose and glucose. This was achieved by on-line monitoring of acrylamide released into the headspace of the samples using proton transfer reaction mass spectrometry (PTR-MS). Unambiguous identification of acrylamide by PTR-MS was accomplished by gas chromatography coupled simultaneously to electron-impact MS and PTR-MS. The PTR-MS ion signal at m/z 72 was shown to be exclusively due to protonated acrylamide obtained without fragmentation. In model Maillard systems, the formation of acrylamide from asparagine was favored with increasing temperature and preferably in the presence of fructose. Maximum signal intensities in the headspace were obtained after approximately 2 min at 170 degrees C, whereas 6-7 min was required at 150 degrees C. Similarly, the level of acrylamide released into the headspace during thermal treatment of potato was positively correlated to temperature.

Published

2003

17. Differentiation of degrees of ripeness of catuai and tipica green coffee by chromatographical and statistical techniques

Author

Chahan Yeretzian, Alexia N. Gloess, Samo Smrke, and Ivana Kroslakova

Subjects

Sucrose, Fraction (chemistry), Mass spectrometry, Ripeness, Coffee, High-performance liquid chromatography, Gas Chromatography-Mass Spectrometry, Analytical Chemistry, chemistry.chemical_compound, Chlorogenic acid, Caffeine, Coffee ripeness, Chromatography, High Pressure Liquid, Green coffee, PCA, Chromatography, Hydrophilic interaction chromatography, food and beverages, General Medicine, SEC, chemistry, 663: Getränketechnologie, Gas chromatography, HPLC, HS SPME GC/MS, Food Science

Abstract

The quality of green coffee is influenced by the degree of ripeness of the fruit at harvest. The aim of this study was to identify chemical markers differentiating between degrees of ripeness. Two coffee varieties, Catuai and Tipica, from the same farm were analysed using the following parameters and methods: caffeine and chlorogenic acid content using high-performance liquid chromatography (HPLC), sucrose content using hydrophilic interaction chromatography, high-molecular weight fraction (HMW) using high-performance size-exclusion chromatography (HPSEC) and volatile compounds using headspace solid phase micro extraction gas chromatography/mass spectrometry. The best method for differentiating between degrees of ripeness was found to be principal component analysis (PCA) based on HPLC data. HPSEC showed differences in the HMW fraction for different degrees of ripeness and both coffee varieties. Volatile profiles allowed separation of both varieties; yet, except for ripe Catuai, no separation was achieved for the degree of ripeness.

Published

2015

18. Free Radical Processes in Coffee II—Liquids

Author

Bernard A. Goodman and Chahan Yeretzian

Subjects

Spin trapping, Chemistry, Radical, Extraction (chemistry), Hydrogen atom, Coffee, Antioxidants, Assays, Organic molecules, law.invention, law, 663: Getränketechnologie, Organic chemistry, Degradation (geology), Electron paramagnetic resonance, Roasting

Abstract

This chapter describes the measurement of free radical processes in liquid coffee samples, and their impact on the quality and stability of the beverage. Free radicals generated during the roasting process are relatively stable and located in the polymeric melanoidins, but their concentrations change in coffee solutions via O2-independent decay and O2-dependent formation processes. In addition, the chemistry of coffee solutions is strongly influenced by highly unstable free radicals, presumably hydroxyl radicals generated via Fenton reaction chemistry. These radicals react virtually indiscriminately with organic molecules by hydrogen atom extraction, and can thus initiate progressive degradation of coffee brews. Identification of stable markers of such reactions are discussed along with possible strategies for slowing the rate of alteration of liquid coffee products during storage.

Published

2015

19. Free radical processes in coffee I : solid samples

Author

Bernard A. Goodman and Chahan Yeretzian

Subjects

Antioxidant, medicine.medical_treatment, food and beverages, Coffee, Caramelization, Antioxidants, Assays, Lipid peroxidation, chemistry.chemical_compound, Maillard reaction, symbols.namesake, chemistry, 663: Getränketechnologie, medicine, symbols, Organic chemistry, Roasting

Abstract

This chapter briefly reviews the roles played by free radical processes during the roasting and storage of coffee beans and solid coffee products. During roasting, free radical production occurs in distinct phases, possibly related to the Maillard and caramelization reactions. At the same time there is also generation of large quantities of molecules with antioxidant properties, thus demonstrating that antioxidant production does not necessarily equate to free radical scavenging, insofar as it is measured by current assays. Furthermore, with respect to chemical components that are associated with desirable sensory properties of coffee, free radical processes may have both beneficial and detrimental effects.

Published

2015

20. Freshness Indices of Roasted Coffee: Monitoring the Loss of Freshness for Single Serve Capsules and Roasted Whole Beans in Different Packaging

Author

Markus Rast, Louis Deuber, Barbara Schönbächler, Chahan Yeretzian, and Alexia Glöss

Subjects

Gas chromatography, Hot Temperature, Food Packaging, Food storage, Coffea, General Medicine, General Chemistry, Intensity ratio, Coffee, Specialty coffee, Single serve capsule systems, Chemistry, Food Storage, Freshness, Taste, Seeds, Food science, Volatilization, QD1-999, Food Analysis, Flavor, Mathematics

Abstract

With the growing demand for high-quality coffee, it is becoming increasingly important to establish quantitative measures of the freshness of coffee, or the loss thereof, over time. Indeed, freshness has become a critical quality criterion in the specialty coffee scene, where the aim is to deliver the most pleasant flavor in the cup, from highest quality beans. A series of intensity ratios of selected volatile organic compounds (VOC) in the headspace of coffee (by gas chromatography–mass spectrometry) were revisited, with the aim to establish robust indicators of freshness of coffee – called freshness indices. Roasted whole beans in four different packaging materials and four commercial capsule systems from the Swiss market were investigated over a period of up to one year of storage time. These measurements revealed three types of insight. First, a clear link between barrier properties of the packaging material and the evolution of selected freshness indices was observed. Packaging materials that contain an aluminum layer offer better protection. Second, processing steps prior to packaging are reflected in the absolute values of freshness indices. Third, differences in the standard deviations of freshness-indices for single serve coffee capsule systems are indicative of differences in the consistency among systems, consistency being an important quality attribute of capsules.

Published

2014

21. Insight into the time-resolved extraction of aroma compounds during espresso coffee preparation : on-line monitoring by PTR-ToF-MS

Author

Chahan Yeretzian, Ralf Zimmermann, and José A. Sánchez-López

Subjects

Principal Component Analysis, Volatile Organic Compounds, Time Factors, Chromatography, biology, Chemistry, Extraction (chemistry), Analytical chemistry, Time resolution, Extraction, biology.organism_classification, Online Systems, Coffee, Mass Spectrometry, Analytical Chemistry, Espresso, Ptr tof ms, 663: Getränketechnologie, Principal component analysis, Cluster Analysis, Espresso coffee, Aroma

Abstract

Using proton-transfer-reaction time-of-flight mass-spectrometry (PTR-ToF-MS), we investigated the extraction dynamic of 95 ion traces in real time (time resolution: 1 second) during espresso coffee preparation. Fifty-two of these ions were tentatively identified. This was achieved by on-line sampling of the volatile organic compounds (VOCs) in close vicinity to the coffee flow, at the exit of the extraction hose of the espresso machine (single serve capsules). Ten replicates of six different single serve coffee types were extracted to a final volume of between 30 - 110 mL, according to the recommended cup size of the respective coffee capsule (Ristretto, Espresso and Lungo), and analyzed. The results revealed considerable differences in the extraction kinetics between compounds, which led to a fast evolution of the volatile profiles in the extract flow and consequently to an evolution of the final aroma balance in the cup. Besides exploring the time-resolved extraction dynamics of VOCs, the dynamic data also allowed the coffees types (capsules) to be distinguished from one another. Both Hierarchical Cluster Analysis (HCA) and Principal Component Analysis (PCA) showed full separation between the coffees types. The methodology developed provides a fast and simple means of studying the extraction dynamics of VOCs and differentiating between different coffee types.

Published

2014

22. Antioxidant generation during coffee roasting : a comparison and interpretation from three complementary assays

Author

Chahan Yeretzian, Samo Smrke, Marco Keller, Sebastian E. W. Opitz, Stefan Schenker, and Bernard A. Goodman

Subjects

Health (social science), Antioxidant, medicine.medical_treatment, Roast parameter, ORAC, flow injection analysis, Coffee roasting, Plant Science, lcsh:Chemical technology, Health Professions (miscellaneous), Microbiology, Coffee, chemistry.chemical_compound, Chlorogenic acid, medicine, lcsh:TP1-1185, ABTS, Gallic acid, Food science, Roasting, Communication, food and beverages, Folin-Ciocalteu, Antioxidant capacity, chemistry, Biochemistry, 663: Getränketechnologie, Food Science, Antioxidant assays

Abstract

Coffee is a major source of dietary antioxidants; some are present in the green bean, whereas others are generated during roasting. However, there is no single accepted analytical method for their routine determination. This paper describes the adaption of three complementary assays (Folin-Ciocalteu (FC), ABTS and ORAC) for the routine assessment of antioxidant capacity of beverages, their validation, and use for determining the antioxidant capacities of extracts from coffee beans at different stages in the roasting process. All assays showed a progressive increase in antioxidant capacity during roasting to a light roast state, consistent with the production of melanoidins having a higher antioxidant effect than the degradation of CGAs. However, the three assays gave different numbers for the total antioxidant capacity of green beans relative to gallic acid (GA), although the range of values was much smaller when chlorogenic acid (CGA) was used as reference. Therefore, although all three assays indicated that there was an increase in antioxidant activity during coffee roasting, and the large differences in responses to GA and CGA illustrate their different sensitivities to different types of antioxidant molecule.

Published

2014

23. Modeling and validation of heat and mass transfer in individual coffee beans during the coffee roasting process using computational fluid dynamics (CFD)

Author

Beatriz Alonso-Torres, José Alfredo Hernández-Pérez, Fernando Sierra-Espinoza, Stefan Schenker, and Chahan Yeretzian

Subjects

Hot Temperature, Food Handling, Heat and mass transfer, Modeling, Humidity, Models, Theoretical, Coffee, Roasting, Chemistry, Computational fluid dynamic, Hydrodynamics, Coffee roasting, Cfd, QD1-999, 664: Lebensmitteltechnologie

Abstract

Heat and mass transfer in individual coffee beans during roasting were simulated using computational fluid dynamics (CFD). Numerical equations for heat and mass transfer inside the coffee bean were solved using the finite volume technique in the commercial CFD code Fluent ; the software was complemented with specific user-defined functions (UDFs). To experimentally validate the numerical model, a single coffee bean was placed in a cylindrical glass tube and roasted by a hot air flow, using the identical geometrical 3D configuration and hot air flow conditions as the ones used for numerical simulations. Temperature and humidity calculations obtained with the model were compared with experimental data. The model predicts the actual process quite accurately and represents a useful approach to monitor the coffee roasting process in real time. It provides valuable information on time-resolved process variables that are otherwise difficult to obtain experimentally, but critical to a better understanding of the coffee roasting process at the individual bean level. This includes variables such as time-resolved 3D profiles of bean temperature and moisture content, and temperature profiles of the roasting air in the vicinity of the coffee bean.

Published

2013

24. How does roasting affect the antioxidants of a coffee brew? Exploring the antioxidant capacity of coffee via on-line antioxidant assays coupled with size exclusion chromatography

Author

Chahan Yeretzian, Irena Vovk, Samo Smrke, and Sebastian E. W. Opitz

Subjects

Antioxidant, Hot Temperature, Polymers, medicine.medical_treatment, Coffee roasting, Coffea, Coffee, Antioxidants, symbols.namesake, chemistry.chemical_compound, Automation, medicine, Cooking, Coffee bean, Roasting, ABTS, Chromatography, Elution, Chemistry, Melanoidin, food and beverages, General Medicine, Maillard Reaction, Maillard reaction, 663: Getränketechnologie, symbols, Chromatography, Gel, Chlorogenic Acid, Food Science

Abstract

During coffee roasting major changes occur in coffee bean composition. Among others dark coloured melanoidins are formed, which are high molecular weight Maillard reaction products. A new approach is presented here to monitor the influence of roasting conditions on the antioxidant capacity of melanoidins and chlorogenic acids (CGAs) in a coffee brew. Validated Folin–Ciocalteu (FC) and ABTS assays were used as on-line antioxidant assays coupled (post-column) with high performance size-exclusion chromatography (HPSEC). HPSEC enabled the separation of melanoidins from CGAs and the determination of the antioxidant capacity of each fraction, within a total elution time of 25 min. Besides the on-line assay measurements, both assays were also applied off-line with flow injection analysis (FIA). The maximum antioxidant capacity was determined to be at a light-to-medium roast degree, measured with both ABTS-FIA and FC-FIA assays as well as on-line ABTS assay. With FC on-line assay the maximum was found to be at a very light roast degree. Based on the peak areas obtained with the new coupled technique the roasting effects on the variability of melanoidin and CGA contents in coffee brews were studied. The majority of melanoidins are already formed in the early stage of the roasting process and the relative contribution of melanoidins to the total antioxidant capacity increases towards darker roasts, mainly because CGAs degrade during roasting. A new parameter, the ratio of melanoidin to CGA peak area, was introduced as a possible predictor of the roast degree.

Published

2013

25. Probing free radical processes during storage of extracts from whole roasted coffee beans: impact of O2 exposure during extraction and storage

Author

Chahan Yeretzian, Bernard A. Goodman, and Ederlinda C. Pascual

Subjects

Aqueous solution, Free Radicals, Chemistry, Plant Extracts, Extraction (chemistry), Analytical chemistry, Electron Spin Resonance Spectroscopy, General Chemistry, Coffee, law.invention, Oxygen, law, 663: Getränketechnologie, Degradation (geology), Food science, General Agricultural and Biological Sciences, Electron paramagnetic resonance, Flavor

Abstract

Development of liquid coffee products of good quality with extended shelf lives is hampered by their rapid quality degradation as a result of both physical and flavor instability. One approach that is being considered for extending the shelf lives of liquid coffees is that of supplementing the beverage with a very mild and slow continuous extraction from intact roasted beans that are held within an aluminum can. This paper reports the use of electron paramagnetic resonance (EPR) spectroscopy to examine the effects of key parameters that affect the stability of liquid coffee prepared from aqueous extracts from whole roasted coffee beans, namely, the O2 content of the water and headspace during extraction and the temperature during storage. It was found that the magnitude of the free radical signal was sensitive to the O2 content of the water used for extraction and storage time and temperature, whereas the intensity of the Fe(III) (g = 4.3) signal was affected only by the O2 content of the water and the Mn signal was insensitive to the experimental parameters. The most critical factor was the O2 content of the water used for extraction, and careful control of O2 exposure at the extraction stage could be a crucial factor for generating products with resistance to oxidative processes during storage.

Published

2013

26. Effect of roasting conditions and grinding on free radical contents of coffee beans stored in air

Author

Chahan Yeretzian, Bernard A. Goodman, and Ederlinda C. Pascual

Subjects

Chemistry, 663: Getränketechnologie, Arabica coffee, Free-radicals, General Medicine, Food science, Coffee, Food Science, Analytical Chemistry, Roasting, Grinding

Abstract

The influence of roasting and storage conditions on free radical contents of individual Arabica coffee beans was examined during storage of whole, half and ground beans in air over a 1-month period. Free radical contents increased with increasing roasting time (roasting degree), but the atmosphere (air vs. N 2 ) used in the roasting and cooling process had little effect. There was a progressive increase in free radical contents with storage time, but the rate was much lower in whole beans than with half and fully ground beans, for which the rate was similar. These results suggest that exposure to O 2 , rather than physical grinding is the main mechanism for storage-related free radical generation, and strongly indicate that roasted coffee is best kept as whole beans in order to minimise changes during prolonged periods of aerobic storage. Furthermore, they demonstrate that EPR measurements can contribute to understanding the process and storage related changes in coffee.

Published

2012

27. Quantification of the Robusta fraction in a coffee blend via Raman spectroscopy: proof of principle

Author

Chahan Yeretzian, Babette Klopprogge, Thomas Wermelinger, and Lucio D'Ambrosio

Subjects

Price difference, Analytical chemistry, Fraction (chemistry), Coffea, Coffea canephora, Spectrum Analysis, Raman, High-performance liquid chromatography, Coffee, chemistry.chemical_compound, symbols.namesake, Robusta, Species Specificity, Plant Oils, Kahweol, biology, Chemistry, Coffea arabica, General Chemistry, biology.organism_classification, Lipids, 663: Getränketechnologie, Seeds, symbols, Arabica, Diterpenes, General Agricultural and Biological Sciences, Raman spectroscopy

Abstract

Among the 100 different known Coffea species, Coffea arabica L. (Arabica) and Coffea canephora Pierre (Robusta) are the only two of commercial interest. They differ in a range of agronomic, genetic, and chemical properties. Due to the significant price difference between Arabica and Robusta, there is an economic incentive to illicitly replace Arabica with Robusta. Therefore, it is crucial to have accurate methods to determine the Robusta-to-Arabica-ratio in blends. This paper presents the proof of principle of a new and fast approach to determine the Robusta fraction in a blend based on Raman spectroscopy. The oils of two references (a pure Robusta and pure Arabica coffee) and six blends thereof consisting of different Robusta and Arabica fractions were extracted using a Soxhlet system. The solutes were analyzed by means of Raman spectroscopy without further workup. Using the intensity ratio between two Raman peaks, one characteristic for kahweol and one characteristic for fatty acids, allowed determinination of the Robusta content in a given mixture. The intensity ratio is linearly dependent on the Robusta content of the compound. Above a Robusta content of 75 wt %, kahweol was not detectable. The Raman data are in agreement with results obtained from the very time-consuming multistep DIN 10777 procedures based on HPLC.

Published

2011

28. Real time monitoring of free radical processes during the roasting of coffee beans, using real electron paramagnetic resonance spectroscopy

Author

Ederlinda C. Pascual, Chahan Yeretzian, and Bernard A. Goodman

Subjects

Radical, Analytical chemistry, chemistry.chemical_element, General Medicine, Radicals, Oxygen, Nitrogen, Coffee, Analytical Chemistry, Maillard reaction, symbols.namesake, chemistry, Electron spin resonance, 663: Getränketechnologie, symbols, On-line, Coffee bean, Inert gas, Free Radical Formation, Food Science, Roasting

Abstract

Because of the roles of free radicals in the formation of Maillard reaction products and as markers of oxidation processes in foods, the dynamics of free radical generation during the roasting of coffee beans have been measured, and some exploratory investigations conducted on the extent to which these are influenced by the bean type, and the atmosphere (air vs. N2), in which the beans were roasted and cooled. The intensities of the free radical signals from individual Arabica and Robusta coffee beans were measured continuously in an EPR spectrometer, whilst beans underwent heating/cooling cycles in air or N2 atmospheres. Additional EPR measurements were performed on the products of coffee beans roasted in a laboratory, convectional hot air roaster. Two sets of experiments were performed: (i) single/half bean roasting in air or N2, and real time, in situ EPR analysis of the free radical content – with a very high flow of roasting gas (convective roasting); (ii) batch roasting in air or N2, and EPR measurements of individual roasted beans – in a rather low flow of gas. Large differences in intermediate and final free radical EPR signal intensities were observed between the specimens of Arabica and Robusta beans that were investigated, irrespective of the roasting atmosphere. During the heating phase of the roasting process, only minor differences were observed between beans of the same type roasted in air or nitrogen, but the presence of oxygen in the cooling cycle resulted in major increases of free radical levels compared to those observed in an inert atmosphere, although this O2-related effect was not observed in beans from the convectional hot air roaster. Large bean to bean variations were observed with a standard blend roasted in the convectional hot air roaster, but much smaller variations were observed with beans from a single batch. Three major conclusions can be drawn from this study: (i) when roasting with a very strong flow of hot gas, the atmosphere (air vs. N2) had a very limited impact (during the heating phase) on free radical formation, but a dramatic and fast increase during the cooling phase, irrespective of the type of coffee beans. (ii) It appears that the relative masses of coffee beans and air during the roasting process are critical for oxidation and hence the free radical content of the final product. Indeed, the dramatic increase in free radicals during air-cooling was only observed if roasting was performed with a very high flow of hot air. (iii) There are wide variations in the free radical dynamics of different types of coffee bean. Arabica beans showed stronger free radical formation during roasting and higher EPR intensities at the end of the roasting cycle, than did Robusta beans. Yet, as the sampling over different Arabicas and Robustas was limited here, a more systematic study is needed to ascertain this observation.

Published

2011

29. When machine tastes coffee : an instrumental approach to predict the sensory profile of espresso coffee

Author

Chahan Yeretzian, Imre Blank, David Labbe, Philippe Pollien, Andreas Rytz, Marcel Alexandre Juillerat, and Christian Lindinger

Subjects

Normalization (statistics), Sensory, business.industry, Chemistry, Proton-transfer-reaction mass-spectrometry (ptr-ms), Pattern recognition, Sensory system, Sensory profile, Analytical, Sensory analysis, Coffee, Analytical Chemistry, Espresso, 663: Getränketechnologie, Trace analysis, Espresso coffee, Artificial intelligence, Food science, business

Abstract

A robust and reproducible model was developed to predict the sensory profile of espresso coffee from instrumental headspace data. The model is derived from 11 different espresso coffees and validated using 8 additional espressos. The input of the model consists of (i) sensory profiles from a trained panel and (ii) on-line proton-transfer reaction mass spectrometry (PTR-MS) data. The experimental PTR-MS conditions were designed to simulate those for the sensory evaluation. Sixteen characteristic ion traces in the headspace were quantified by PTR-MS, requiring only 2 min of headspace measurement per espresso. The correlation is based on a knowledge-based standardization and normalization of both datasets that selectively extracts differences in the quality of samples, while reducing the impact of variations on the overall intensity of coffees. This work represents a significant progress in terms of correlation of sensory with instrumental results exemplified on coffee.

Published

2008

30. Unambiguous identification of volatile organic compounds by proton-transfer reaction mass spectrometry coupled with GC/MS

Author

Christian Lindinger, Chahan Yeretzian, Santo Ali, Philippe Pollien, Tilmann D. Märk, and Imre Blank

Subjects

Detection limit, chemistry.chemical_classification, Chromatography, Chemistry, Analytical chemistry, Mass spectrometry, Coffee, PTR-MS, Gas Chromatography-Mass Spectrometry, Analytical Chemistry, 540: Chemie, Fragmentation (mass spectrometry), Volatile organic compound, Gas chromatography, Gas chromatography–mass spectrometry, Organic Chemicals, Volatilization, Electron ionization, Proton-transfer-reaction mass spectrometry

Abstract

Interest in on-line measurements of volatile organic compounds (VOCs) is increasing, as sensitive, compact, and affordable direct inlet mass spectrometers are becoming available. Proton-transfer reaction mass spectrometry (PTR-MS) distinguishes itself by its high sensitivity (low ppt range), high time resolution (200 ms), little ionization-induced fragmentation, and ionization efficiency independent of the compound to be analyzed. Yet, PTR-MS has a shortcoming. It is a one-dimensional technique that characterizes compounds only via their mass, which is not sufficient for positive identification. Here, we introduce a technical and analytical extension of PTR-MS, which removes this shortcoming, while preserving its salient and unique features. Combining separation of VOCs by gas chromatography (GC) with simultaneous and parallel detection of the GC effluent by PTR-MS and electron impact MS, an unambiguous interpretation of complex PTR-MS spectra becomes feasible. This novel development is discussed on the basis of characteristic performance parameters, such as resolution, linear range, and detection limit. The recently developed drift tube with a reduced reaction volume is crucial to exploit the full potential of the setup. We illustrate the performance of the novel setup by analyzing a complex food system.

Published

2005

31. Laser mass spectrometry as on-line sensor for industrial process analysis: process control of coffee roasting

Author

Ralph Dorfner, Chahan Yeretzian, and Antonius Kettrup, Ralf Zimmermann, and T. Ferge

Subjects

Quality Control, Hot Temperature, Time Factors, Analytical chemistry, Coffee roasting, Mass spectrometry, Coffee, Mass Spectrometry, Analytical Chemistry, Beverages, Ionization, Volatile organic compound, Cooking, Flavor, Aroma, Roasting, chemistry.chemical_classification, Resonance-enhanced multiphoton ionization, Principal Component Analysis, Sensory, biology, Chemistry, Lasers, Temperature, biology.organism_classification, Molecular Weight, Steel, 663: Getränketechnologie, Food Analysis

Abstract

The objective of the project is to develop on-line, real-time, and noninvasive process control tools of coffee roasting that help deliver a consistent and high-quality coffee aroma. The coffee roasting process was analyzed by direct injection of the roaster gas into a time-of-flight mass spectrometer and ionized either by resonance enhanced multiphoton ionization (REMPI) at 266 and 248 nm or vacuum ultraviolet single-photon ionization (VUV-SPI) at 118 nm. The VUV ionization scheme allows detecting mainly the most volatile and abundant compounds of molecular mass below 100 m/z, while REMPI ionizes mainly aromatic compounds of molecular mass larger than 100 m/z. Combining the compounds ionized by resonant and single-photon ionization, approximately 30 volatile organic compounds are monitored in real time. Time-intensity profiles of 10 important volatile coffee compounds were discussed in connection with their formation chemistry during roasting. Applying multivariate statistics (principle component analysis) on time-intensity traces of nine volatile coffee compounds, the roasting degree could be traced as a consistent path in the score plot of the two most significant principle components (including 68% of the total variance), for a range of roasting temperatures (200-250 degrees C).

Published

2004

32. Real-time monitoring of 4-vinylguaiacol, guaiacol, and phenol during coffee roasting by resonant laser ionization time-of-flight mass spectrometry

Author

Anthonius Kettrup, Chahan Yeretzian, Ralf Zimmermann, Ralph Dorfner, and T. Ferge

Subjects

Resonance-enhanced multiphoton ionization, Chromatography, Hot Temperature, Phenol, Inorganic chemistry, Guaiacol, Coffee roasting, Coffea, General Chemistry, Mass spectrometry, Coffee, Mass Spectrometry, Ferulic acid, chemistry.chemical_compound, chemistry, Ionization, 663: Getränketechnologie, Seeds, Rempi tof-ms, General Agricultural and Biological Sciences, Aroma, Roasting

Abstract

The formation of 4-vinylguaiacol, guaiacol, and phenol during coffee roasting was monitored in real-time, using resonance enhanced multiphoton ionization and time-of-flight mass spectrometry. A model is proposed, based on two connected reaction channels. One channel, termed the “low activation energy” channel, consists of ester hydrolysis of 5-FQA followed by decarboxylation of the ferulic acid to form 4-vinylguaiacol, and finally polymerization at the vinyl group to form partly insoluble polymers (coffee melanoidins). The second “high activation energy” channel opens up once the beans have reached higher temperatures. It leads to formation of guaiacol, via oxidation of 4-vinylguaiacol, and subsequently to phenol and other phenolic VOCs. This work aims at developing strategies to modify the composition of coffee flavor compounds based on the time−temperature history during roasting. Keywords: Coffee; aroma; roasting; real-time analysis; mass spectrometry; resonant laser ionization

Published

2003

33. Liquid-air partitioning of volatile compounds in coffee : dynamic measurements using proton-transfer-reaction mass spectrometry

Author

Alfons Jordan, Chahan Yeretzian, Philippe Pollien, and Werner Lindinger

Subjects

Chemistry, Liquid air, Environmental chemistry, 663: Getränketechnologie, Liquid food, Partition coefficients, Physical and Theoretical Chemistry, Condensed Matter Physics, Instrumentation, Coffee, Flavor, Spectroscopy, Proton-transfer-reaction mass spectrometry

Abstract

Recently we introduced a dynamic approach to determine Henry’s law constants (HLCs) of volatile organic compounds (VOCs) in water, and applied it to a series organic compounds dissolved in pure water. Here, we first discuss a further development of the original approach such that it can be applied to complex liquid food systems (coffee). Second, we examine the impact of non-volatile constituents on the HLC. More specifically, we evaluate the impact of non-volatile coffee constituents on the HLC of 2-methylpropanal, 3- and 2-methylbutanal, dimethylsulfide, dimethyldisulfide and ethyl-2-methylbutyrate. Finally, we demonstrate that the concentration on the VOC in solution does not affect the HLC, over the investigated concentration range of 10−4 to 10 ppm.

Published

2003

34. The elusiveness of coffee aroma: new insights from a non-empirical approach

Author

Chahan Yeretzian, Heribert Watzke, Alessandro Curioni, Wanda Andreoni, and Lindsey J. Munro

Subjects

biology, Free Radicals, Molecular Structure, Chemistry, Radical, Classification scheme, Computational modeling, General Chemistry, biology.organism_classification, Coffee, Molecular level, Drug Stability, Phenols, 663: Getränketechnologie, Odorants, Organic chemistry, Fenton chemistry, Radical formation, Thermodynamics, Sulfhydryl Compounds, Volatilization, General Agricultural and Biological Sciences, Flavor, Aroma

Abstract

Aroma is central to a pleasurable eating/drinking experience but is one of the most labile components of food. Coffee is an outstanding example. Attempts to avoid or control aroma degradation are often frustrated by ignorance of the microscopic mechanisms that are responsible for it. One of the processes most frequently invoked is radical formation, yet the identity of the radicals and their involvement in aroma degradation are poorly understood at the molecular level. Here a step forward in the fundamental understanding of this complex problem is taken by identifying the most relevant radicals and their products using first-principles calculations. Over 100 radicals originating from key aroma compounds found in coffee and other foods have been studied and classified according to an unambiguous criterion: their thermodynamic stability relative to common radical sources. This classification scheme predicts that most aroma molecules are resistant to both peroxidation and attack from phenolic antioxidants but are unstable with respect to radicals such as •OH. Dimers – generated from radical reactions – were also considered, and the most volatile species, which may further contribute to coffee aroma degradation, were focused on. Those – which are very few indeed – that have this potential have been identified.

Published

2003

35. Analysing the headspace of coffee by proton-transfer-reaction mass-spectrometry

Author

Chahan Yeretzian, Werner Lindinger, and Alfons Jordan

Subjects

Partition coefficient, Chromatography, Chemistry, 663: Getränketechnologie, Analytical chemistry, Physical and Theoretical Chemistry, Condensed Matter Physics, Instrumentation, Coffee, Spectroscopy, Proton-transfer-reaction mass spectrometry, PTR-MS

Abstract

An extensive analysis of the headspace (HS) of coffee brew using proton-transfer-reaction mass-spectrometry (PTR-MS) is presented. In particular, we present a set of methods that link mass spectral peaks, as observed in PTR-MS, to chemical compounds in the HS of coffee. Combining all this information, a tentative assignment and rough quantification of liquid coffee HS is presented. Coffee was chosen because it contains a large number of chemically diverse volatile organic compounds (VOCs), representing a challenging system for on-line analysis by PTR-MS.

Published

2003

36. Characterization of free radicals in soluble coffee by electron paramagnetic resonance spectroscopy

Author

Bernard A. Goodman, Chahan Yeretzian, and Ederlinda C. Pascual

Subjects

Free Radicals, Pyridines, Radical, Analytical chemistry, chemistry.chemical_element, Oxygen, Coffee, law.invention, Ion, Transition metal, law, Electron paramagnetic resonance, Dissolution, Aqueous solution, Electron Spin Resonance Spectroscopy, Temperature, Water, General Chemistry, Solutions, Unpaired electron, chemistry, Solubility, Metals, 663: Getränketechnologie, Nitrogen Oxides, Spin Labels, General Agricultural and Biological Sciences

Abstract

EPR spectra of soluble coffee display single-line free radical signals in both the solid state and aqueous solution, along with signals from the paramagnetic ions Fe(III) and Mn(II). The intensity of the free radical signal in the pure solid was estimated to be ca. 7.5 x 10(16) unpaired electrons/g, and there was no significant change on dissolution in water. In aqueous solutions, however, the free radical signal declined rapidly over ca. 10-15 min in the temperature range 20-65 degrees C, after which only slow changes were observed. This decline, which was essentially independent of atmosphere, was greatest for the lowest temperatures used, and the intensity after 1 h fitted well to an exponential curve with respect to temperature. The free radicals responsible for the single-peak EPR signal did not react with any of the spin traps tested in the present experiments, but unstable free radicals with parameters consistent with adducts of C-centered radicals were detected in coffee solutions in the presence of PBN and 4-POBN spin traps. The presence of oxygen in the solutions increased the initial rate of formation of these free radical adducts. No adducts were detected when DEPMPO was used as spin trap. However, *OH adducts of DEPMPO were shown to be unstable in the presence of coffee, a fact which illustrates the strong free radical scavenging ability of coffee solutions.

Published

2002

37. Degradation of the coffee flavor compound furfuryl mercaptan in model Fenton-type reaction systems

Author

Richard H. Stadler, Imre Blank, Ste Ä Phanie Devaud, Chahan Yeretzian, Ederlinda C. Pascual, Bernard A. Goodman, and Laurent B. Fay

Subjects

Free Radicals, Radical, Iron, Ethylenediaminetetraacetic acid, Ascorbic Acid, Coffee, law.invention, chemistry.chemical_compound, Drug Stability, law, Organic chemistry, Sulfhydryl Compounds, Hydrogen peroxide, Electron paramagnetic resonance, Furans, Flavor, Edetic Acid, Aqueous solution, Hydroxyl Radical, Electron Spin Resonance Spectroscopy, Temperature, General Chemistry, Hydrogen Peroxide, Ascorbic acid, chemistry, Reagent, Taste, Indicators and Reagents, Spin Labels, Volatilization, General Agricultural and Biological Sciences, Dimerization

Abstract

The stability of the coffee flavor compound furfuryl mercaptan has been investigated in aqueous solutions under Fenton-type reaction conditions. The impact of hydrogen peroxide, iron, ascorbic acid, and ethylenediaminetetraacetic acid was studied in various combinations of reagents and temperature. Furfuryl mercaptan reacts readily under Fenton-type reaction conditions, leading to up to 90% degradation within 1 h at 37 degrees C. The losses were lower when one or more of the reagents was omitted or the temperature decreased to 22 degrees C. Volatile reaction products identified were mainly dimers of furfuryl mercaptan, difurfuryl disulfide being the major compound. In addition, a large number of nonvolatile compounds was observed with molecular masses in the range of 92-510 Da. The formation of hydroxyl and carbon-centered radicals was indicated by electron paramagnetic resonance spectra using alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone or 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline-N-oxide as spin traps. Whereas *OH was generated by Fenton-type reactions, the C-centered radical is probably a secondary product of the reaction of *OH with various organic molecules, the reaction with furfuryl mercaptan appearing to be the most important. No evidence for S-centered radicals was seen in the spin-trapping experiments, but a sulfur-containing radical was detected when measurements were made at 77 K in the absence of spin traps.

Published

2002

38. On-line analysis of coffee roasting off-gas with laser ionisation (REMPI and SPI) mass spectrometry measurement at large scale roasting facilities and on-line determination of the roast degree

Author

Dorfner, R., Ferge, T., Chahan Yeretzian, Kettrup, A., and Zimmermann, R.

Subjects

REMPI-ToF-MS, 663: Getränketechnologie, Coffee, Flavor, Aroma

Published

2002

39. From the green bean to the cup of coffee : investigating coffee roasting by on-line monitoring of volatiles

Author

Chahan Yeretzian, Werner Lindinger, Raphael Badoud, and Alfons Jordan

Subjects

biology, Acetaldehyde, Coffee roasting, General Chemistry, Furfural, biology.organism_classification, Coffea canephora, Biochemistry, Coffee, Industrial and Manufacturing Engineering, PTR-MS, chemistry.chemical_compound, Acetic acid, chemistry, 663: Getränketechnologie, Botany, Methanol, Food science, Aroma, Food Science, Biotechnology, Roasting

Abstract

Erworben im Rahmen der Schweizer Nationallizenzen (http://www.nationallizenzen.ch), Volatile organic compounds (VOCs), emitted from green coffee beans, during coffee roasting and from a cup of coffee, were all analysed by proton-transferreaction mass spectrometry. Firstly, the headspace (HS) of green beans was investigated. Alcohols dominate the HS, but aldehydes, hydrocarbons and organic acids were also abundant. Secondly, we roasted coffee under two different conditions and monitored on-line the VOCs emitted during the process. In a first roasting series, a batch of beans was roasted. After an initial drying phase, dominated by evaporation of water and methanol, the HS concentrations of VOCs such as acetic acid, acetaldehyde, pyridine and methylbutanal rapidly increased and went through a maximum at medium roast level. In a second series, just six beans were roasted. We observed sporadic bursts of some volatiles (furans, butanal, 2,3- pentanedione), coinciding with popping sounds. Other VOCs showed smooth time-intensity profiles (pyridine, pyrazine). These experiments gave a real-time insight into the complex processes taking place during roasting. Finally, the HS of coffee extracts, prepared from beans roasted to different roast levels, were analysed. Most VOCs showed a maximum concentration at medium roast level (e.g. pentanedione, furfural, 5-methyl furfural), while others showed a gradual increase (e.g. pyrrol) or decrease (e.g. methanol).

Published

2002

40. Characterisation of the aroma of green mexican coffee and identification of mouldy/earthy defect

Author

Alejandro M. Feria-Morales, Rentato Amado, Ennio Cantergiani, Hugues Brevard, Chahan Yeretzian, and Yves Krebs

Subjects

GC, Chromatography, biology, Chemistry, Organoleptic, General Chemistry, biology.organism_classification, Biochemistry, Geosmin, Coffee, Industrial and Manufacturing Engineering, chemistry.chemical_compound, Olfactometry, 663: Getränketechnologie, Gas chromatography, Green coffee, Aroma, Food Science, Biotechnology

Abstract

Erworben im Rahmen der Schweizer Nationallizenzen (http://www.nationallizenzen.ch), The aromas of a reference green Mexican coffee (Arabica) and of a coffee from the same origin, but having a pronounced earthy/mouldy off-taint, were characterised. From comparison of the two aroma profiles, the compounds causing the defect were detected by gas chromatography olfactometry, isolated and concentrated by preparative bi-dimensional gas chromatography, and characterised by gas chromatography mass spectrometry. Six compounds participated in the off-flavour. Geosmin, 2-methylisoborneol, 2,4,6-trichloroanisole were found to be the main culprits, while three methoxy pyrazines (2-methoxy-3-isopropyl/-3-sec-butyl/-3-isobutyl pyrazine) contributed to a lesser extent to the earthy/ green undertone. The occurrence of the off-flavour could tentatively be linked to post-harvest drying.

Published

2001

41. Application of laser ionization mass spectrometry for on-line monitoring of volatiles in the headspace of food products : roasting and brewing of coffee

Author

Holger Nagel, Chahan Yeretzian, Ralf Zimmermann, Hans Jörg Heger, and Ulrich Boesl

Subjects

Chromatography, Mass spectrometry, Chemistry, business.industry, Organic Chemistry, Analytical chemistry, chemistry.chemical_element, Coffee roasting, Laser, Nitrogen, Coffee, Ion source, Analytical Chemistry, law.invention, law, Ionization, 663: Getränketechnologie, Brewing, Laser ionization, business, Spectroscopy, Roasting

Abstract

Resonance-enhanced multi-photon ionization time-of-flight mass spectrometry (REMPI/TOFMS) has been applied to the detection of volatiles in the headspace of brewed coffee and in the coffee roasting process-gas. A frequency quadrupled Nd:YAG laser (266 nm) was used for REMPI ionization (REMPI@266nm) of the volatiles in an effusive molecular beam inside the ion source of a linear TOF mass spectrometer. A special sampling system provided a time correlated sampling. Under these circumstances REMPI@266nm is highly selective for ionization of phenolic compounds. Several phenolic compounds, such as the flavour-active 4-vinylguaiacol, can be detected in the headspace of coffee brew as well as in the roast off-gas with the application of this approach. Moreover, the nitrogen heterocyclic compounds, indole and caffeine, were detected in both cases. During the roasting process the relative changes in concentration of some volatile components of coffee have been recorded by EMPI@266nm with a time resolution of 1 Hz. The different volatiles exhibit characteristic concentration profiles as a function of the roast time. These results demonstrate the applicability of REMPI-TOFMS for on-line monitoring of coffee processing technologies. Such an on-line monitoring technique is of particular interest for process-control purposes, e.g. quality-protection or feedback process control. For example, monitoring of off-gases from the coffee roast process or monitoring of certain unit operations during the instant-coffee manufacturing could be promising industrial applications.

Published

1996

42. Comparison of nine common coffee extraction methods: instrumental and sensory analysis

Author

Alexia N. Gloess, André Strittmatter, Barbara Schönbächler, Babette Klopprogge, Karin Chatelain, Chahan Yeretzian, Annette Bongartz, Markus Rast, and Lucio D`Ambrosio

Subjects

Brix, Chromatography, biology, Chemistry(all), Chemistry, Extraction (chemistry), Extraction, Titratable acid, General Chemistry, Sensory analysis, Total dissolved solids, biology.organism_classification, Coffee, Biochemistry, Industrial and Manufacturing Engineering, Headspace analysis, Espresso, 663: Getränketechnologie, Food science, Aroma, Flavor, Biotechnology, Food Science

Abstract

The preparation of a cup of coffee may vary between countries, cultures and individuals. Here, an analysis of nine different extraction methods is presented regarding analytical and sensory aspects for four espressi and five lunghi. This comprised espresso and lungo from a semi-automatic coffee machine, espresso and lungo from a fully automatic coffee machine, espresso from a single- serve capsule system, mocha made with a percolator, lungo prepared with French Press extraction, filter coffee and lungo extracted with a Bayreuth coffee machine. Analyti- cal measurements included headspace analysis with HS SPME GC/MS, acidity (pH), titratable acidity, content of fatty acids, total solids, refractive indices (expressed in � Brix), caffeine and chlorogenic acids content with HPLC. Sensory analysis included visual, aroma, flavor and textural attributes as well as aftersensation. The technical differ- ences in the extraction methods led to a higher concen- tration of the respective quantities in the espressi than in the lunghi. Regarding the contents per cup of coffee, the lunghi generally had a higher content than the espressi. The extraction efficiency of the respective compounds was mainly driven by their solubility in water. A higher amount of water, as in the extraction of a lungo, generally led to higher extraction efficiency. Comparing analytical data with sensory profiles, the following positive correlations were found total solids $ texture/body, headspace inten- sity $ aroma intensity, concentrations of caffeine/chloro- genic acids $ bitterness and astringency.