Changes

'''Alpha acids''' (also called "humulones" and abbreviated as "α-acids") in hops mostly consist of humulone, cohumulone, and adhumulone. Trace amounts of other forms of humulones are also present but are difficult to quantify and currently have limited research: posthumulone, perhumulone, adprehumulone, and adprehumulone acetohumulone <ref name="Hao_2020">[https://www.tandfonline.com/doi/full/10.1080/03610470.2020.1712641 Junguang Hao, R.A. Speers, Heliang Fan, Yang Deng & Ziru Dai (2020) A Review of Cyclic and Oxidative Bitter Derivatives of Alpha, Iso-Alpha and Beta-Hop Acids, Journal of the American Society of Brewing Chemists, 78:2, 89-102, DOI: 10.1080/03610470.2020.1712641.]</ref><ref name="Leker_2022">[https://www.tandfonline.com/doi/abs/10.1080/03610470.2022.2079944 Jeremy Leker & John Paul Maye (2022) Discovery of Acetohumulone and Acetolupulone a New Hop Alpha Acid and Beta Acid, Journal of the American Society of Brewing Chemists, DOI: 10.1080/03610470.2022.2079944 ]</ref>. The ratio of these individual acids to each other can vary based on hop variety much like total iso-α-acid percent, though generally the primary acids are humulone and cohumulone. Cohumulone has been identified by some researchers as a source of a more harsh bitterness, although similar research contradicts this statement <ref>[http://www.scielo.br/scielo.php?pid=S0100-40422000000100019&script=sci_arttext&tlng=es Fundamentals of beer and hop chemistry. Denis De Keukeleire. 1999.]</ref>. Being hydrophobic, alpha acids are mostly insoluble in wort at typical brewing pH (alpha acids become much more soluble as the pH rises towards 5.9 to 7, which is not typical for wort production <ref name="Bastgen_2019">[https://www.tandfonline.com/doi/full/10.1080/03610470.2019.1587734 Influencing Factors on Hop Isomerization Beyond the Conventional Range. Nele Bastgen, Tobias Becher & Jean Titze. 2019. DOI: https://doi.org/10.1080/03610470.2019.1587734.]</ref>). During boiling, alpha acids are isomerized into iso-alpha acids (also called isohumulones) that are soluble. Isomerization leads to roughly a 70%/30% split between diastereomeric isomers called ''cis'' and ''trans'' iso-α-acids respectively, with ''cis'' iso-α-acids being more stable over time and more bitter<ref name="Schönberger and Kostelecky, 2012"> [http://onlinelibrary.wiley.com/doi/10.1002/j.2050-0416.2011.tb00471.x/abstract Schönberger and Kostelecky, 2012]</ref>. Alpha acids themselves do not taste bitter, but isomerized alpha acids (iso-α-acids/isohumulones) contribute to the bitterness of beer and have antimicrobial properties. Isocohumulone is often cited as being more harshly bitter than the other iso-α-acids, but studies of taste perception of individual iso-α-acids have not agreed with this. However, iso-cohumolone is slightly more soluble than the other acids and therefore a hop with a higher cohumulone composition may result in a beer with higher iso-α-acid for hops of equal iso-α-acid percent and use in brewing but different iso-α-acid breakdown<ref name="Schönberger and Kostelecky, 2012"/>. Alpha acids are susceptible to oxidation and the alpha acid content of a hop will decrease with storage.

There is evidence to show that during wort boiling iso-humulone and perhaps also iso-cohumulone bind with the head forming proteins, Lipid Transfer Protein (LTP) and Protein Z, to help form foam-positive structures in beer. These iso-alpha acids bind less so with LTP than they do with Protein Z. The resulting bound structures have been described as "vesicles", which are protein "bubbles" (but with no gas in them) with thick surface layers <ref>[https://www.sciencedirect.com/science/article/pii/S0268005X19325391 Vesicular structures formed from barley wort proteins and iso-humulone. Yi Lu, Peter Osmark, Björn Bergenståhl, Lars Nilsson. 2020.]</ref>. See also [https://www.youtube.com/watch?v=5F8vmuTV5Mg Escarpment Labs presentation on the science of beer foam].

'''Beta Acids''' (lupulones) are similar in structure to alpha acids and have the analogous individual beta acids (lupulone, colupulone, adlupulone, prelupulone, postlupulone, adprelupukone, and adprelupukone acetolupulone <ref name="Dušek_2014">[http://pubs.acs.org/doi/abs/10.1021/jf501852r Qualitative Determination of β‑Acids and Their Transformation Products in Beer and Hop Using HR/AM-LC-MS/MS. Martin Dušek, Jana Olšovská, Karel Krofta, Marie Jurková, and Alexandr Mikyška. 2014.]</ref><ref name="Hao_2020" /><ref name="Leker_2022" />) to individual alpha acids. In their original form, beta acids do not contribute to the flavor of beer because they are not soluble in beer unless the pH of the boiling wort is significantly raised to around 7 pH (which is not typical in brewing conditions) and the original gravity is relatively low (2-8°P) <ref name="Bastgen_2019" />. They are also not able to isomerize during wort boiling. Beta acids do not become soluble in wort or beer unless they are chemically modified by a process such as oxidation <ref name="Algazzali_2014" />, nor are they soluble in beer when dry hopping <ref name="Maye_EBC2017">John Paul Maye. EBC 2017 Presentation. 2017.]</ref>. Oxidized beta acids are soluble and can contribute to bitterness in beer. Oxidized beta acids are discussed more under [[Hops#Acids_2|aged hops]].

The isomerization of alpha acids into iso-alpha acids is mostly dependent on alpha acid content of the hops, time (to a certain extent), temperature, original gravity, hop rate (hop weight), and IBU saturation. Other variables also affect isomerization to a lesser extent such as pH and calcium concentration <ref>[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.1964.tb06356.x CHANGES IN HOP ACIDS CONCENTRATIONS ON HEATING IN AQUEOUS SOLUTIONS AND UNHOPPED WORTS. H. O. Askew. 1964.]</ref><ref name="Malowicki_2005">[http://pubs.acs.org/doi/abs/10.1021/jf0481296 Isomerization and Degradation Kinetics of Hop (Humulus lupulus) Acids in a Model Wort-Boiling System. Mark G. Malowicki and Thomas H. Shellhammer. 2005.]</ref><ref name="justice_2018">[https://www.mbaa.com/publications/tq/tqPastIssues/2018/Pages/TQ-55-3-1205-01.aspx Tracking IBU Through the Brewing Process: The Quest for Consistency. Aaron Justus. Director of R&D and Specialty Brewing, Ballast Point Brewing. MBAA TQ 2018; vol. 55, no.3. https://doi.org/10.1094/TQ-55-3-1205-01.]</ref>. The higher the gravity of wort above 1.050 SG, the more proteins coagulate and drop iso-alpha acids out of solution (lower gravity worts are not affected by this). During fermentation, yeast cells can absorb iso-alpha acids, which results in further loss of iso-alpha acids in the finished beer <ref name="Bastgen_2019" />. Lower flocculating yeast strains tend to reduce the IBU in finished beer more than high flocculating yeast <ref name="justice_2018" />. Significant isomerization of alpha acids can occur in water without sugar at all (temperatures around boiling are still required), which is relevant in the production of [http://www.garshol.priv.no/blog/331.html "hop tea" in traditional farmhouse brewing] where hops are steeped in hot water for some time, and this is said to extract bitterness from the hops <ref name="Malowicki_2005" /><ref>[http://www.ijbbb.org/papers/161-E005.pdf Kinetic Modeling of Hop Acids during Wort Boiling. Yarong Huang, Johannes Tippmann, and Thomas Becker. 2013.]</ref><ref>[http://www.garshol.priv.no/blog/331.html Lars Marius Garshol. "Raw ale". Larsblog. 05/06/2015. Retrieved 12/17/2018.]</ref>. Aside from boiling hops in wort, [https://www.frontiersin.org/articles/10.3389/fnut.2022.843808/full Hydrodynamic Cavitation] at a 90°C temperature is another method that results in the isomerization of alpha acids into iso-alpha acids; although an additional 10 minutes of boiling at 100°C was needed to remove DMS and achieve hot break. This method reportedly had a 33% savings in energy costs in [https://www.sciencedirect.com/science/article/abs/pii/S0960308524000166 one study].

Malowicki and Shellhammer determined a calculation that predicts the isomerization rates of alpha acids into iso-alpha acids at different temperatures. Beginning at the boiling temperature of 100°C/212°F, which could be considered a rate of 100%, at 96°C/205°F the rate is 72%, and at 90°C/194°F the rate is 43%. This rate continues to drop significantly as the temperature of the wort decreases. At 82°C/180°F isomerization occurs at a rate of 17%. At a temperature of 50°C/122°F, the isomerization rate is at 1%, and finally 0% at 45°C/113°F (note that [https://www.tandfonline.com/doi/full/10.1080/03610470.2021.1878684 Kishimoto et al. (2021)] reported that isomerization begins somewhere between 60-70°C <ref name="Kishimoto_2021">[https://www.tandfonline.com/doi/full/10.1080/03610470.2021.1878684 Toru Kishimoto, Satoko Teramoto, Akiko Fujita & Osamu Yamada (2021) Evaluation of Components Contributing to the International Bitterness Unit of Wort and Beer, Journal of the American Society of Brewing Chemists, DOI: 10.1080/03610470.2021.1878684.]</ref>). This fact has several impacts on brewing processes. For example, when brewing at higher altitudes where the boiling point of wort is less than 100°C/212°F, the isomerization of alpha acids into iso-alpha acids will be reduced to whatever the rate is at that lower temperature. "Hop stands" or "whirlpool additions" where hops are left in contact with hot wort that is less than boiling temperature will continue to isomerize alpha acids <ref name="Malowicki_2005" /><ref>[https://www.mbaa.com/publications/tq/tqPastIssues/2017/Pages/TQ-54-3-0806-01.aspx A Look at Isomerization Reduction Due to Altitude. John Palmer. MBAA TQ 2017 http://dx.doi.org/10.1094/TQ-54-3-0806-01.]</ref>.

The pH of the wort can also appears to have a small no significant effect on the isomerization of alpha acids to iso-alpha acids, although this variable is less significant than other variables such as alpha acid content, time (to a certain extent), temperature, and original gravity. Aaron Justice reported a trending slight rise in the conversion of alpha acids to iso-alpha acids when the boil pH was raised from 5.05 (~40% of aa's converted to iso-aa's) to 5.35 (~50% of aa's converted to iso-aa's). However, an Eppendorf BioSpectrometer using ASBC Wort-23 and ASBC Beer-23A was used to measure IBU'S, not isomerized alpha acids specifically (chromatography must be used to measure iso-alpha acids without measuring other bittering compounds) <ref name="justice_2018" />. Bastgen et al. (2019) found that at a boil pH of 5.6, the percentage of iso-alpha acids increased by 32% by extending the boil from 60 minutes to 120 minutes. However, there was no increase at all in iso-alpha acids when the boil pH was 7, but a pH of 7 is not typical in the brewing process <ref name="Bastgen_2019" />. Time is thought to play a large role in isomerization, however, Justice reported that the majority of the IBU from iso-alpha acids in 60 minute additions and in whirlpool additions occurs within the first 10 minutes, with only a 12-30% increase after another 50 minutes of boiling/whirlpooling (higher gravity beers had more isomerization during the final 50 minutes while lower gravity beers had less isomerization during the final 50 minutes of boiling) <ref name="justice_2018" />. Blogger and "garage scientist", John Paul Hosom, who developed the so-called "[https://alchemyoverlord.wordpress.com/2021/11/10/ibus-and-the-smph-model/ SMPH Model for estimating IBU's], hypothesized that non-iso-alpha acid bittering compounds that impact spectrophotometer IBU measurements such as oxidized alpha acids are affected by wort pH, rather than the isomerization rate of alpha acids into iso-alpha acids <ref>[https://alchemyoverlord.wordpress.com/2021/11/10/ibus-and-the-smph-model/ John Paul Hosom. "The Effect of pH on Utilization and IBUs". Alchemyoverlord blog. Retrieved 01/29/2023.]</ref>.

Beer bitterness is often described in terms of International Bitterness Units (IBU), or more accurateaccurately, Bitterness Units (BU). The European Brewery Convention has adopted the [https://europeanbreweryconvention.eu/new-international-method-on-bitter-compounds-in-dry-hopped-beers/ “E.B.C. Bitterness Units,” ] determined in a similar wayand recently updated for dry hopped beers to account for humulinones, as a uniform method that best expresses the true bitter flavor value of beer <refname="asbc_ibu">[https://www.asbcnet.org/Methods/BeerMethods/Pages/default.aspx ASBC Methods of Analysis website. Retrieved 02/11/2022.]</ref>.These measurements seek to measure the amount of iso-alpha acids, which contribute the majority of bitterness to beer. There are, however, other compounds that contribute to bitterness, such as oxidized alpha and beta acids (see [[Hops#Chemistry_and_Characteristics|Aged Hops]] below). These methods include using [https://en.wikipedia.org/wiki/Spectrophotometry spectrophotometry], [https://en.wikipedia.org/wiki/High-performance_liquid_chromatography High-Performance Liquid Chromatography-Ultraviolet (HPLC-UV)], and [https://en.wikipedia.org/wiki/Liquid_chromatography%E2%80%93mass_spectrometry liquid chromatography–mass spectroscopy (LC–MS)]. The ASBC describes these methods in depth on [https://www.asbcnet.org/Methods/BeerMethods/Pages/default.aspx their website] (see method 23; requires membership to read). While many brewers argue that the IBU measurement is not that helpful for communicating bitterness to consumers, it is generally agreed upon that IBU measurements are very useful to brewers who are seeking consistency in their products <ref>[https://beerandbrewing.com/dictionary/eej03p6ZUI/ The Oxford Companion to Beer definition of International Bitterness Units (IBUs). Retrieved 02/12/2022.]</ref>. Compounds other than iso-alpha acids present several challenges to traditional methods of measuring BU's. Many hop compounds other than iso-alpha acids that have varying levels of perceived bitterness are detected at the same wavelength as iso-alpha acids using spectrophotometry. In addition, oxidized alpha acids are known to contribute to bitterness. As a result, updated methods of using High-Performance Liquid Chromatography-Ultraviolet (HPLC-UV) and liquid chromatography–mass spectroscopy (LC–MS) are generally recommended for measuring bitterness units in dry hopped beers (although models that account for bitterness contribution from compounds other than iso-alpha acids have not yet been completed). In addition to these challenges, iso-alpha acids and other hop compounds that contribute to bitterness degrade over time, thus the perceived bitterness of beer tends to become weaker as beer ages <ref>[https://www.chromatographyonline.com/view/liquid-chromatography-mass-spectrometry-analysis-of-hop-derived-humulone-and-isohumulone-constituents-in-beer-the-bitter-truth-of-hops-utilization-during-brewing Liquid Chromatography–Mass Spectrometry Analysis of Hop-Derived Humulone and Isohumulone Constituents in Beer: The Bitter Truth of Hops Utilization During Brewing. Bruce C. Hamper, Nicholas Viriyasiri, Aaron Boland, Lorna Espinosa, Hunter J. Campbell, Kurt Driesner, Michael McKeever. January 1, 2022. LCGC Europe, January 2022, Volume 35, Issue 01. Pages: 32–37.]</ref><ref name="asbc_ibu"/>. Measuring BU's directly requires costly laboratory equipment, and so researchers and enthusiasts have made some progress in creating models that attempt to estimate bitterness units. These models are generally based off of boil time, alpha acid percent of the hops used, weight of the hops used, post-boil volume of wort, and gravity of the wort. These include the [http://www.realbeer.com/hops/research.html Tinseth] model, the Garetz model, and the [http://realbeer.com/hops/FAQ.html#units Rager] model. These models are often used in brewing software, such as [https://beersmith.com/blog/2021/09/23/hop-utilization-models-for-beer-brewing-compared/ BeerSmith™] and [https://www.brewersfriend.com/ibu-calculator/ Brewer's Friend]. [https://alchemyoverlord.wordpress.com/2021/11/10/ibus-and-the-smph-model/ Another model called the 'SMPH' model] has been proposed by John Paul Hosom as potential updated model that addresses their limitations in regard to newer hopping techniques such as whirlpool hopping and dry hopping, as well as accounting for IBU's from non-iso-alpha acid compounds Other limitations include differences in brewhouse size and efficiencies. For example, the Tinseth model was developed on a homebrew system using whole leaf hops (see the Experimental Brewing podcast interview with Glenn Tinseth link below). See also:* [http://scottjanish.com/dry-hopping-effect-bitterness-ibu-testing/ "Dry Hopping Effect on Bitterness and IBU Testing" by Scott Janish.]* [https://www.experimentalbrew.com/podcast/episode-32-ibu-lie Experimental Brewing interview with Glenn Tinseth (52 minutes in).]* [https://www.craftbeer.com/craft-beer-muses/beer-ibus-fact-fiction-misconceptions "Last Call for IBUs: Fact, Fiction and Their Impact on Your Beer," by Chris McClellan.]* [http://thebrulab.libsyn.com/episode-076-a-modern-method-for-predicting-ibu-w-john-paul-hosom The Brü Lab Podcast Episode 076 | A Modern Method For Predicting IBU w/ John Paul Hosom]

Hops are known to have antimicrobial properties against Gram-positive bacteria. This includes bacteria that can be present in beer both as spoilage organisms and as intentionally added in sour and mixed fermentation beer such as ''[[Lactobacillus]]'' and ''[[Pediococcus]]''. Gram-negative bacteria found in beer, such as ''Acetobacteraciae'', and are not susceptible to the antimicrobial properties of hops <ref name="Hough_1957">[https://onlinelibrary.wiley.com/doi/pdf/10.1002/j.2050-0416.1957.tb06267.x J. S. Hough, B.Sc, Ph.D., G. A. Howard, M.Sc., Ph.D., and C. A. Slater, Ph.D. 1957.]</ref><ref name="Macrae_1964">[https://onlinelibrary.wiley.com/doi/abs/10.1002/j.2050-0416.1964.tb02001.x SIGNIFICANCE OF THE USE OF HOPS IN REGARD TO THE BIOLOGICAL STABILITY OF BEER: I. REVIEW AND PRELIMINARY STUDIES. R. M. Macrae. 1964.]</ref>. Certain Gram-positive bacteria strains that have adapted to the brewing environment, such as some strains of ''Lactobacillus brevis''and ''L. paracasei'' <ref>[https://proceedings.science/slacan-2023/papers/prospects-for-the-development-of-a-new-hopped-and-functional-sour-beer-survival?lang=en Marcos Edgar Herkenhoff; Susana Marta Isay Saad. PROSPECTS FOR THE DEVELOPMENT OF A NEW HOPPED AND FUNCTIONAL SOUR BEER: SURVIVAL OF PROBIOTIC STRAINS OF LACTICASEIBACILLUS PARACASEI SUBSP. PARACASEI IN HIGH HOPPED BEERS (HUMULUS LUPULUS L.).. In: CADERNO DE RESUMOS DO 15° SLACAN - SIMPóSIO LATINO AMERICANO DE CIêNCIA DE ALIMENTOS E NUTRIçãO, 2023, Campinas. Anais eletrônicos... Campinas, Galoá, 2023. Disponível em: <https://proceedings.science/slacan-2023/trabalhos/prospects-for-the-development-of-a-new-hopped-and-functional-sour-beer-survival?lang=en> Acesso em: 23 nov. 2023.]</ref>, are known to be more resistant to the antimicrobial effects of hops. The antimicrobial effect is characterized as inhibiting the growth and lactic acid production of lactic acid bacteria, however, this does not always also include cell death as ''Lactobacillus'' that has been inhibited by hops can later be revived <ref name="Macrae_1964" />. The effectiveness of hops to inhibit Gram-positive bacteria is also dependent on pH; at a lower pH, hops have a greater effect on inhibiting bacteria <ref name="Almaguer_2015" />. Multiple mechanisms Hop extracts have also been proposed demonstrated to explain why hops are antimicrobially activebe antimicrobial <ref>[https://www.sciencedirect.com/science/article/abs/pii/S0963996923003770 Yan Li, Sevim Dalabasmaz, Sabrina Gensberger-Reigl, Marie-Louise Heymich, Karel Krofta, Monika Pischetsrieder. Identification of colupulone and lupulone as the main contributors to the antibacterial activity of hop extracts using activity-guided fractionation and metabolome analysis. Food Research International. 2023.]</ref>.

Multiple mechanisms have been proposed to explain why hops are antimicrobially active. One mechanism of the antimicrobial activity of hops is due to the role of iso-alpha alpha acids and possibly similar hop acids (such beta acids and oxidized hop acids) as ionophores, or compounds which can transport ions across cell membranes. While their antimicrobial properties are strong, alpha and beta acids in beer and wort and their effects on brewing are generally disregarded because they do not solubilize <ref name="Fernandez and Simpson, 1993"> [http://onlinelibrary.wiley.com/doi/10.1111/j.1365-2672.1993.tb02782.x/full Fernandez and Simpson (1993)] </ref><ref name="Sakamoto and Konings, 2003"> [http://www.sciencedirect.com/science/article/pii/S0168160503001533 Sakamoto and Konings (2003)]</ref>. The protonated iso-α-acid (the form of the acid with an associated H+ ion, an H+ ion is a proton) is the antimicrobially active form. This means that for a beer with a given iso-α-acid concentration, the antimicrobial effects will be stronger at lower pH values because a greater percentage of the acid will be protonated. Protonated iso-α-acids act against bacteria by crossing into the cell and dissociating (releasing H+ ions from the iso-α-acid and decreasing the pH within the cell <ref name="zhao_1027">[https://www.frontiersin.org/articles/10.3389/fmicb.2017.00239/full#B28 Heterogeneity between and within Strains of Lactobacillus brevis Exposed to Beer Compounds. Yu Zhao, Susanne Knøchel and Henrik Siegumfeldt. 2017. DOI: https://doi.org/10.3389/fmicb.2017.00239.]</ref>), therefore disrupting the cellular proton gradient which is necessary for cells to function, before binding an equal charge in metal ions and crossing back out of the cell. Cells with resistance to hop bitter acids are better able to eject disassociated iso-α-acids from the cell and therefore preserve their proton gradients. The mechanism to expel iso-α-acids appears to be specific toward this type of compound rather than by a more general antimicrobial resistance mechanism such as multi-drug resistant bacteria possess <ref name="Sakamoto and Konings, 2003"/>. The anti-microbial power of iso-α-acids is pH dependent. At a higher pH (5.6) iso-α-acids begin to lose their anti-microbial properties, but at a typical beer pH (4.3) iso-α-acids inhibited a sample of 6 strains of ''L. brevis'' that exhibited a range of general hop tolerance in one study <ref name="zhao_1027" />. Hop resistant bacteria cultured in the absence of hop acids can lose their resistance if grown in an environment without antibacterial hop compounds<ref name="Fernandez and Simpson, 1993"/> and some hop resistant microbes need to be acclimated to hop acids by growth in sub-limiting levels of antibacterial acids before they are able to resist higher levels <ref name="Sakamoto and Konings, 2003"/>.

A "biotransformation" is any change in a chemical's structure that is initiated by a living organism <ref>[https://en.m.wikipedia.org/wiki/Biotransformation "Biotransformation". Wikipedia. Retrieved 05/10/2019.]</ref>. It has been hypothesized that biotransformations of some kind are taking place in beer during fermentation and explain changes to hop compounds during fermentation and beer storage. Some carbonyl compounds found in hops (citral, geranial, nerol, [https://en.wikipedia.org/wiki/Citronellal citronellal], and methyl ketones) can be used as a food source by yeast during fermentation. ''Cyclic ethers'' such as linalool oxides, karahana ether, hop ether, and rose oxide (aroma of roses <ref>[http://www.thegoodscentscompany.com/data/rw1035651.html "(Z)-rose oxide ". Good Scents Company. Retrieved 12/29/2016.]</ref>), increase after fermentation and have been identified as secondary metabolites produced by yeast during metabolism from hop derived precursors. ''Esters'' found in hops can be converted into ethyl esters by yeast during fermentation; for example, geranyl esters found in Cascade hops can be hydrolyzed into geraniol (flowery). The terpenoid [https://en.wikipedia.org/wiki/Citronellol citronellol] (citrus and floral <ref>[https://eic.rsc.org/magnificent-molecules/citronellol/2000020.article "There are no flies on Emma Stoye". Emma Stoye. Education in Chemistry website. 06/01/2016. Retrieved 01/10/2017.]</ref>) can be esterified by yeast fermentation into citronellyl acetate (fresh, rosy, fruity odor reminiscent of geranium oil <ref>[https://shop.perfumersapprentice.com/p-6034-citronellyl-acetate.aspx "Citronellyl acetate". Perfumers Apprentice website. Retrieved 01/10/2017.]</ref>). Yeast strains differ in their ability to convert these compounds. For example, one study found that lager yeast was able to form acetate esters of geraniol and citronellol, but ale yeast was not <ref name="Praet_2012" />.  In addition to biochemical changes to hop compounds, yeast derived flavor compounds that are independent of hops such as esters and phenols can affect the overall sensory characteristics of hop compounds in beer. Therefore, different strains of yeast can greatly impact the overall organoleptic experience of hop flavors and aromas in finished beers <ref>[https://www.mdpi.com/2304-8158/12/5/1064 Kumar, A.; Warburton, A.; Silcock, P.; Bremer, P.J.; Eyres, G.T. Yeast Strain Influences the Hop-Derived Sensory Properties and Volatile Composition of Beer. Foods 2023, 12, 1064. https://doi.org/10.3390/foods12051064.]</ref>.  ===Terpenes===

[https://onlinelibrary.wiley.com/doi/abs/10.1002/j.2050-0416.2010.tb00428.x Takoi et al. (2012)] used Citra hops with a high content of geraniol added late in the boil, and reported a steep decline on geraniol during the first three days of fermentation with a lager yeast strain. Linalool had a gradual decline but ended up at higher levels than geraniol in the finished beer. Citronellol had a sharp increase during the first three days of fermentation and then remained at a stable level until the end of fermentation. However, after storing the beer at 15°C (59°F) for 1 week, the amount of citronellol more than doubled. This indicated that active fermentation may not be required for the transformation of geraniol into citronellol (the yeast was filtered before packaging the finished beer, after a storage time of 6-8 days at 13–15°C and then at 0°C for 2–3 weeks). The enzyme NADPH dehydrogenase 2, encoded by the OYE₂ gene in some yeast strains, was proposed as the mechanism for this transformation. Interestingly, Takoi et al. (2012) also showed that coriander seeds, which also have high levels of linalool and geraniol, have a nearly exact same effect on beer, with a beer made with 0.5 g/L of coriander seed resulting in 20 ppb of citronellol and a beer made with 0.75 g/L of coriander seed resulting in 30 ppb of citronellol. The Citra beer had a citrus and "green" aroma, while the coriander beers had a very floral aroma with a slight citrus impression. They also conducted a sensory experiment with different levels of geraniol and citronellol added to linalool to see if small amounts of these would affect the flavor of a large dosage of linalool, and the results confirmed that small increases of geraniol and citronellol increased flowery and fruity flavors even in the presence of high dosages of linalool <ref>[https://onlinelibrary.wiley.com/doi/abs/10.1002/j.2050-0416.2010.tb00428.x The Contribution of Geraniol Metabolism to the Citrus Flavour of Beer: Synergy of Geraniol and β‐Citronellol Under Coexistence with Excess Linalool. Kiyoshi Takoi, Yutaka Itoga, Koichiro Koie, Takayuki Kosugi, Masayuki Shimase, Yuta Katayama, Yasuyuki Nakayama, Junji Watari. 2012. DOI: https://doi.org/10.1002/j.2050-0416.2010.tb00428.x.]</ref>. The data for the Citra beer is shown below:

====Glycosides====Hops contain In addition to terpenes and monoterpene alcohols being found in hops in a free form, they are also present in the form of glycosides, which are flavor compounds that are bound to a sugar molecule. Plants use glycosides for a range of metabolic purposes. The amounts and types of glycosides in hops varies by hop variety, and can be affected by plant fertilization and harvest timing <ref name="Svedlund_2022">[https://link.springer.com/article/10.1007/s00253-022-12068-w Svedlund, N., Evering, S., Gibson, B. et al. Fruits of their labour: biotransformation reactions of yeasts during brewery fermentation. Appl Microbiol Biotechnol 106, 4929–4944 (2022). https://doi.org/10.1007/s00253-022-120.]</ref>. In their bound form, glycosides are flavorless. Studies on hop compounds elude to the possibility of compounds being produced by the glycosidic activity of ''S. cerevisiae'', however direct evidence of glucosidic activity in ''S. cerevisiae'' is lacking. Daenen (2008) reviewed the glycosidic activity of many strains of ''S. cerevisiae'', and found that only a few strains expressed any real glucosidic activity and none that exhibited exo-beta-glucosidase which would be required to break glycosidic bonds in the beer/wort. Daenen did find that enzymatic activity from some strains of ''Brettanomyces'' can efficiently release these bound compounds and release their flavor and aromatic potential <ref name="Praet_2012" />. Beta-glucosidase enzyme can also be added to beer to enhance the breakdown of glycosides and intensify hop-derived flavors and aromas. For example, one study showed an increase in citrus, orange, grapefruit, and tropical pineapple in a Cascade dry hopped beer that had beta-glucosidase enzymes added to it <ref>"Optimizing hop aroma in beer dry hopped with Cascade utilizing glycosidic enzymes (presentation slides)." Kaylyn Kirkpatrick from New Belgium Brewing Co. Young Scientist Symposium, Chico, CA 2016.</ref>. There is also some evidence to support that there is higher glucosidase activity in seeded hops, which are generally not used in the brewing industry <ref>"Seeded and "Unseeded Hops - a Quality Comparison (presentation slides)." Martin Zarnkow. EBC 2015.</ref>. Hops also contain polyhenols that are bound in glycosidic form that could contribute a small amount of bitterness <ref>[https://www.tandfonline.com/doi/abs/10.1080/03610470.2021.2024112?journalCode=ujbc20 Martin Biendl, Stefanie Ritter & Christina Schmidt (2022) Monitoring of Glycosidically Bound Polyphenols in Hops and Hop Products Using LC-MS/MS Technique, Journal of the American Society of Brewing Chemists, DOI: 10.1080/03610470.2021.2024112.]</ref> (see also [https://traffic.libsyn.com/secure/forcedn/thebrulab/056_Applying_the_Science_-_High_Hop_Loads_w_Jordan_Folks.mp3 Bru Lab Podcast Episode 055; Hop Bitterness And Polyphenols w/ Dr. Martin Biendl]).

For techniques and usage amounts of aged hops, see [[Hops#Aged_Hops_in_LambicAged_Hops_in_Lambic_and_Other_Spontaneous_Fermentation_Beer|Aged Hops in Lambic]].

Freshly harvested hops (also called "wet hops") should not be aged. Freshly harvested hops should be dried first, as is normal for hop processing, before aging in order to prevent [[Mold|mold]] growth (see this [https://www.canr.msu.edu/news/drying_hops_on_a_small_scale article from Michigan State University] on measuring moisture levels and [https://www.homebrewersassociation.org/how-to-brew/how-to-harvest-prepare-and-store-homegrown-hops/ this AHA article on drying hops] for home growersand this [https://www.masterbrewerspodcast.com/117 MBAA podcast interview with Val Peacock on industrial hop drying]).

| Hulupinic Acids || Hulupones || Y || Contributes marginal bitterness to beer; flavor threshold of 69 umol/L || Has a relatively low abortion degradation in wort.

'''Oxidized alpha acids''' (humulinones) are similar in taste perception to iso-α-acids, but have been described as less bitter (an average of about 66% as bitter on a 1 to 1 basis). The quality of the bitterness from oxidized alpha acids has been described in one study as "smoother and less lingering" than iso-alpha acids; this was attributed to humulinones being more polar than iso-alpha acids and therefore do not stick or linger on the tongue as long as iso-alpha acids <ref name="Shellhammer, Vollmer and Sharp, CBC 2015"/><ref name="Maye_2016" />. While the taste threshold of iso-alpha acids is 5-6 mg/L in light lager, the threshold for humulinones has been measured to be 8 mg/L in light lager (note that this is an average; tasters vary widely in how much bitterness they perceived from different bitter compounds) <ref name="Algazzali_2014" />. Humulinone content increases in hops after being pelletized (whole leaf hops have less humulinones). In fresh pellet hops that have a relatively low humulinone content, the humulinones contribute little to the bitterness of the beer when boiled, however when dry hopped they readily dissolve into the beer and have a significant impact on the beer's bitterness. With heavy dry hopping, the humulinones also decrease iso-alpha acid content of beer with more than about 25 IBU's, but not in beer with less than about 20 IBU. The decrease in iso-alpha acids and perceived bitterness/IBU is partially made up for the bitterness of the humulinones themselves (humulinones are picked up in IBU measurements with a [http://chem.libretexts.org/Core/Physical_and_Theoretical_Chemistry/Kinetics/Reaction_Rates/Experimental_Determination_of_Kinetcs/Spectrophotometry spectrophotometer] and as such it has been suggested that IBU's be [http://masterbrewerspodcast.com/004-dry-hopping-its-effects-on-bitterness-and-the-ibu-test-0 measured more accurately with HPLC]). In beers with less than 20 IBU, high dry hopping rates greatly increase the bitterness/IBU due to the bitter humulinones<ref name="Maye_2016" />. Humulinones also increase foam creation and stability by binding with the foam positive protein, Protein Z, via hydrogen bonding <ref>[https://www.sciencedirect.com/science/article/abs/pii/S0308814623020678 Chen Xu, Xuanqi Zhang, Mingyang Sun, Hanhan Liu, Chenyan Lv. Interactions between humulinone derived from aged hops and protein Z enhance the foamability and foam stability. Food Chemistry, Volume 434, 2024, 137449, ISSN 0308-8146, https://doi.org/10.1016/j.foodchem.2023.137449.</ref>.  The rate of humulinone formation is limiting, meaning . Maye et al. (2016) showed that humulinone formation occurs occurred rapidly during hop pelletization, and the concentration peaks during this time (these researchers found that further exposure to air did not increase humulinone content). Scientists believe They speculated that this is because when whole leaf hops are baled, only 20% of lupulin glands are broken, whereas when they are pelletized 100% of the lupulin glands are broken. In contrast, Taniguchi et al. (2013) found that humulinone formed slowly over 40 weeks in pellets that were stored at 20°C, but at 40°C and 60°C storage temperature they formed quickly and then diminished to very low levels at 10 weeks and 2 weeks respective to the higher storage temperatures. This demonstrated that warm storage increases the rate of humulinone formation. In addition, the oxidized hop compound 4′-hydroxy-allohumulinone increased trailing behind the humulinone formation and at a similar concentration at 20°C over 40 weeks of storage, and were much more stable than humulinones when stored at 40-60°C for 40 weeks <ref>[https://pubs.acs.org/doi/10.1021/jf3047187 Identification and Quantification of the Oxidation Products Derived from α-Acids and β-Acids During Storage of Hops (Humulus lupulus L.). Yoshimasa Taniguchi, Yasuko Matsukura, Hiromi Ozaki, Koichi Nishimura, and Kazutoshi Shindo. Journal of Agricultural and Food Chemistry 2013 61 (12), 3121-3130. DOI: 10.1021/jf3047187.]</ref>. The exact mechanism by which alpha acids are converted to humulinones is not known . The amount of humulinone correlates strongly with the [http://methods.asbcnet.org/summaries/hops-12.aspx Hop Storage Index (HSI)] <ref name="Maye_2016" />. Humulinone content in long-aged hops (1+ years) has not been studied.

It is therefore advised that brewers ask hop providers that offer aged hops what the original alpha acid percentage was when the hops were fresh, as well as the variety. This could be an important factor when determining how bitter the aged hops will taste, and potentially also how much they will negatively impact lactic acid bacteria growth. See also [[Hops#Aged_Hops_in_LambicAged_Hops_in_Lambic_and_Other_Spontaneous_Fermentation_Beer|"Aged Hops in Lambic" below]] and [https://www.facebook.com/groups/MilkTheFunk/permalink/2503097546385111 this MTF thread on IBU's from aged hops].

A recent 2017 study at the Shellhammer lab looked at how trained panelists and consumers perceived a lager beer dry hopped with slightly oxidized Hallertau Mittelfrüh hops (exposed to oxygen once, then stored at 38°C for two weeks) versus highly oxidized (daily exposure to oxygen and stored at 38°C for two weeks). They found that the trained panelists detected more characteristics that are associated with noble hops; e.g. more woody, earthy, and herbal characteristics in the lager beers dry hopped with oxidized hops. They also found the oxidized hopped beers to be more bitter (probably due to oxidized alpha and beta acids). Consumers were not statistically able to tell the difference. The study determined that oxidized hops might serve to provide nuanced increases in noble hop character <ref>[http://www.asbcnet.org/publications/journal/vol/2017/Pages/ASBCJ-2017-1287-01.aspx Aroma Properties of Lager Beer Dry-Hopped with Oxidized Hops. Daniel M. Vollmer, Victor Algazzali, and Thomas H. Shellhammer. 2017.]</ref>. In a similar study by Hengyuan et al. (2023), aging Saaz hops for a short amount of time (aged at 30 ℃ in a ventilated environment for 5 days) reduced the grassy and resinous character and improved the spicy and woody character of single hopped beers (hopped at three points in the boil and dry hopped). Consumers also preferred this beer over the other samples, including fresh Saaz. However, over-aging Saaz hops resulted in less preference with consumers (30 ℃ for 10 days, 40 ℃ for 5 days, or 40 ℃ for 10 days). This effect was not demonstrated by Simcoe hops, however, indicating that short aging is only beneficial for some hop varieties. Under the same aging condition with Simcoe hops, consumers preferred the fresh Simcoe, and any degree of aged Simcoe was less preferred. The beers with aged Simcoe hops were described as having less fruity and floral character and more dry, thin bitterness <ref>[https://www.bio-conferences.org/articles/bioconf/abs/2023/04/bioconf_icbb2023_01016/bioconf_icbb2023_01016.html Aging of Hops and Their Effects on India Pale Ale Flavor. Hengyuan Xu, Shaokang Sun, Xiaochen Wang, Haojun Zhang and Cong Nie. BIO Web Conf., 59 (2023) 01016. DOI: https://doi.org/10.1051/bioconf/20235901016.]</ref>.

* [https://www.mainiacalyeastyakimachief.com/agedcommercial/hop-hops/ Mainiacal Yeast aged hops (small lots for homebrewers).]* [https://www.yakimachief.comwire/introducing-the-ych-aged-hops-program YCH offers 1-2 oz bags for homebrewers and 44 lb bags of aged hops; contact for more information.]

* <s>[https://hopsdirect.com/products/choice-debittered-pellets Hops Direct "Choice Debittered/Aged Hops" (Pellet - Columbus).]</s>* [https://www.freshops.com/shop/hop/aroma-hopproduct/lambic-hops/ Freshhops "Lambic Hops" (Leaf - Willamette)".]* [httphttps://www.yakimavalleyhops.com/Lambic2oz_pproducts/hopslambichops3.htm lambic-hop-pellets Yakima Valley Hops "Lambic / Aged Hops" (Pellet).]

* [httphttps://www.themaltmiller.co.uk/index.php?_a=viewProd&productId=592 The Malt Miller (UK).]* [http:/product/www.brewstore.co.uk/specially-aged-fuggles-hops-100-grams Brew Store UK / The Malt Miller (Leaf - Fuggles).]* [http://www.brewstore.co.uk/specially-aged-hallertau-hops-100-grams Brew Store UK (Leaf - Hallertau).]

[https://beerandbrewing.com/dictionary/96jvGQTSdT/ Dry hopping] is the technique of adding hops to beer that has finished fermenting or is in the process of fermenting. Historically, dry hopping is associated with English pale ales of the 1800's, and it was re-discovered by Fritz Maytag of Anchor Brewing Company in 1975 when the company brewed the first American IPA, Liberty Ale <ref>[https://beerandbrewing.com/dictionary/96jvGQTSdT/ "The Oxford Companion to Beer definition of dry hopping," Garrett Oliver. Craft beer & Brewing Magazine. Retrieved 11/16/2023.]</ref><ref>[https://northamericanbrewers.org/liberty-ale/ "Liberty Ale". North American Brewers Association. April 28, 2022. Retrieved 11/16/2023.]</ref><ref>[https://www.youtube.com/watch?v=4ijHO5TFG3I Scott Ungermann, Brewmaster of Anchor Brewing Company. The Doug Piper Gourmet Brewing Podcast. July 14th, 2023.]</ref>(20 mins in). Brewers have had positive and interesting results dry-hopping sour and funky beer. Often fresh American or New Zealand varieties that complement fruit flavors are chosen, however, other varieties have been used as well, including English and German hops. Just as in dry hopping normal beers, dry hopping sour/funky should be done after the beer has matured. Dry hopping for around 1-3 days before [[packaging]] the beer is adequate for extraction, depending on whether or not the beer is recirculated or agitated (agitation of the beer while on contact with the dry hops attains full extraction in 24 hours) <ref>[http://ir.library.oregonstate.edu/xmlui/bitstream/handle/1957/34093/Wolfe_thesis.pdf?sequence=1 A Study of Factors Affecting the Extraction of Flavor When Dry Hopping Beer (master thesis). Peter Harold Wolfe. 2012.]</ref>. Hopping rates generally range from 0.5-1 ounces per 1 gallon of beer (1-2 pounds per bbl or 3.7-7.5 grams per liter) to achieve hop-forward flavors, although lesser rates can be used to achieve a more subtle character (see the threads below) <ref>[https://www.facebook.com/groups/MilkTheFunk/permalink/1693639013997639/?comment_id=1693660390662168&comment_tracking=%7B%22tn%22%3A%22R4%22%7D Nate Walter and Dan Pixley. Milk The Funk Facebook group. 05/21/2017.]</ref>.

Kirkpatrick and Shellhammer (2018) found that the enzymes responsible for the conversion of dextrins into sugars include amyloglucosidase (removes glucose from non-reducing ends of α-1,4 and branching α-1,6 linkages, with a preference for α-1,4 linkages and longer chain oligosaccharides), α-amylase (hydrolyzes randomly along glucopolysaccharides to produce maltose, maltotriose, maltopentaose, and maltohexaose products from amylose as well as maltose, glucose, and branched dextrins from amylopectin), β-amylase (saccharifiying enzyme, cleaving maltose in small amounts from nonreducing ends of glucopolysaccharides, and to a minor extent, maltotriose), and limit dextrinase (debranches limit dextrins at α-1,6 linkages, producing linear α-1,4 chains which can further be degraded by the combined action of amylases). They were able to successfully extract them from Cascade pellet hops using commercially available assays (enzyme specific para-nitrophenyl blocked oligosaccharide substrates). The amount of α and β-amylase found in Cascade hops was well below that of malted barley, but within the range reported in other plant leaves. These enzymes are denatured by high temperatures, and as such would be denatured when boiling hops. They reported a similar increase in ABV of 1.3% after 40 days when dry hopping a beer with Cascade hops (and a decrease of 1.9°P) at a rate of 10 g/L. They also found that the hops contained glucose and a small amount of fructose, which accounted for a sugar increase of 0.02−0.03 °P per gram of hops. More studies on whether or not the amount of dry hopping has a large effect needs to be done, and whether or not warmer temperatures speed up the enzymatic breakdown of dextrins, and the authors hypothesized that the rate of dextrin break down could be slowed by dry hopping at lower temperatures <ref name="Kirkpatrick_2018">[https://pubs.acs.org/doi/pdf/10.1021/acs.jafc.8b03563 Evidence of Dextrin Hydrolyzing Enzymes in Cascade Hops (Humulus lupulus). Kaylyn R. Kirkpatrick and Thomas H. Shellhammer. 2018. DOI: DOI: 10.1021/acs.jafc.8b03563.]</ref>. Rubottom and Shellhamer (2023) later demonstrated that drying hops at 150°F reduced the amount of enzymes in dried pellitized hops versus drying them at 130°F <ref>[https://www.tandfonline.com/doi/abs/10.1080/03610470.2023.2194838 Evaluating the Impact of High and Low Kilning Temperatures on Popular American Aroma Hops. Lindsey N. Rubottom, Thomas H. Shellhammer. Received 07 Feb 2023, Accepted 21 Mar 2023, Published online: 28 Apr 2023. https://doi.org/10.1080/03610470.2023.2194838.]</ref>.

===Aged Hops in [[Lambic]] and Other [[Spontaneous Fermentation|Spontaneous Fermentation Beer]]===

Modern lambic traditionally uses aged hops at a moderate rate to help limit and select for microbes and regulate acid production. Modern Lambic brewers cite rates in the range of roughly 450 grams of hops per hectoliter of finished beer (0.6 ounces per gallon) <ref name="Jean Van Roy on Basic Brewing Radio"> [http://hwcdn.libsyn.com/p/e/a/2/ea26e00136fe1638/bbr05-30-13cantillon.mp3?c_id=5723890&expiration=1443888327&hwt=8dd886677defabdd73669cdc262ef446 Jean van Roy on Basic Brewing Radio] </ref> (~43 min in) (see also the notes pertaining hopping rates on the [[Cantillon]] page), with some brewers possibly going above this range. The age of hops used depends on the producer and their preferences/stock. Cantillon uses hops that are roughly 3 years old<ref>D. Janssen personal communication with Jean Van Roy, 9-Nov-2013</ref>, while 3 Fonteinen reports using hops that are over 10 years old<ref name="Drie Fonteinen on Belgian Smaak"> [http://www.belgiansmaak.com/armand-debelder-michael-blancquaert-drie-fonteinen/ Drie Fonteinen on Belgian Smaak] </ref> (~48 minutes in). Jester King reported using 0.66 - 0.75 pounds of whole leaf aged hops per BBL (0.34-0.39 ounces per gallon) in their spontaneously fermented ales <ref>Averie Swanson. "Sour Power! A Pro Brewer Spontaneous Fermentation Roundtable". HomebrewCon seminar. 2018.</ref> (~31:00 mins in). Lambic brewers either add their hops while still collecting wort, sometime before the wort comes to a boil<ref>[https://www.facebook.com/groups/Lambic.Info/permalink/1831338433787524/ Video of Cantillon wort reaching a boil from Bill on Lambic.info]</ref> (also known as "first wort hopping"), or shortly after boil is reached<ref name="Drie Fonteinen on Belgian Smaak"/> (~48 min in). The hops are then boiled with the wort for essentially the full length of the boil <ref>[https://www.facebook.com/groups/MilkTheFunk/permalink/1593059604055581/?comment_id=1593928187302056&reply_comment_id=1593938693967672&comment_tracking=%7B%22tn%22%3A%22R9%22%7D Conversation with Dave Janssen on MTF. 02/24/2017.]</ref><ref>[http://www.lambic.info/Brewing_Lambic#Hopping "Brewing Lambic", section "Hopping". Lambic.info website. Retrieved 02/24/2017.]</ref>. The resulting lambic beers are often surprisingly bitter, especially when young. Historically, there is [http://www.horscategoriebrewing.com/2016/04/hops-in-spontaneous-fermentation.html some evidence] that lambic brewers used a combination of aged hops and fresh dried hops. Not all aged hops are the same; different varieties/sources result in different levels of residual alpha/beta acids (probably not zero), oxidized acids, IBU's, perceived bitterness, and inhibition of lactic acid bacteria. Varieties with high acids and hop oils probably have more residual acids and oils, and aging times/conditions may not be ideal enough to completely age high alpha/beta/oil hop varieties. Therefore, it is impossible to give a blanket statement on how much aged hops to use given a specific lot of aged hops. Andrew Holzhauer from Funk Factory Geuzeria suggests tasting aged hops for bitterness and adjusting the amount of hops depending on how bitter they taste <ref>[https://www.facebook.com/groups/MilkTheFunk/permalink/2723907944304069/?comment_id=2723956477632549&reply_comment_id=2724104977617699&comment_tracking=%7B%22tn%22%3A%22R%22%7D Andrew Holzhauer. Milk The Funk Facebook group on how much aged hops to use. 06/13/2019.]</ref>, while James Howat from Black Project suggests making a small batch and having the wort/beer analyzed for IBU's and adjusting accordingly.