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Tree nut phytochemicals: composition, antioxidant capacity, bioactivity, impact factors. A systematic review of almonds, Brazils, cashews, hazelnuts, macadamias, pecans, pine nuts, pistachios and walnuts

Published online by Cambridge University Press:  12 December 2011

Bradley W. Bolling
Affiliation:
Department of Nutritional Sciences, University of Connecticut, 3624 Horsebarn Road Extension, Unit 4017, Storrs, CT06269, USA
C.-Y. Oliver Chen
Affiliation:
Antioxidants Research Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging, Tufts University, 711 Washington Street, Boston, MA02111, USA
Diane L. McKay
Affiliation:
Antioxidants Research Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging, Tufts University, 711 Washington Street, Boston, MA02111, USA
Jeffrey B. Blumberg*
Affiliation:
Antioxidants Research Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging, Tufts University, 711 Washington Street, Boston, MA02111, USA
*
*Corresponding author: Dr Jeffrey B. Blumberg, fax +1 617 556 3344, email [email protected]
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Abstract

Tree nuts contain an array of phytochemicals including carotenoids, phenolic acids, phytosterols and polyphenolic compounds such as flavonoids, proanthocyanidins (PAC) and stilbenes, all of which are included in nutrient databases, as well as phytates, sphingolipids, alkylphenols and lignans, which are not. The phytochemical content of tree nuts can vary considerably by nut type, genotype, pre- and post-harvest conditions, as well as storage conditions. Genotype affects phenolic acids, flavonoids, stilbenes and phytosterols, but data are lacking for many other phytochemical classes. During the roasting process, tree nut isoflavones, flavanols and flavonols were found to be more resistant to heat than the anthocyanins, PAC and trans-resveratrol. The choice of solvents used for extracting polyphenols and phytosterols significantly affects their quantification, and studies validating these methods for tree nut phytochemicals are lacking. The phytochemicals found in tree nuts have been associated with antioxidant, anti-inflammatory, anti-proliferative, antiviral, chemopreventive and hypocholesterolaemic actions, all of which are known to affect the initiation and progression of several pathogenic processes. While tree nut phytochemicals are bioaccessible and bioavailable in humans, the number of intervention trials conducted to date is limited. The objectives of the present review are to summarise tree nut: (1) phytochemicals; (2) phytochemical content included in nutrient databases and current publications; (3) phytochemicals affected by pre- and post-harvest conditions and analytical methodology; and (4) bioactivity and health benefits in humans.

Type
Review Article
Copyright
Copyright © The Authors 2011

Phytochemical databases with tree nuts

Definition of phytochemicals

The term ‘phytochemical’ broadly refers to all plant-derived chemicals. Hence, macronutrients such as plant carbohydrates (including dietary fibre), lipids and proteins could be categorised as phytochemicals. However, for the purposes of the present report, we use the term ‘phytochemical’ to refer to small non-essential nutrients with putative health-promoting actions. We categorise phytochemicals into six broad classes: alkaloids, organosulfurs, phenolics, carbohydrates, non-nutritive proteins and lipids (Fig. 1).

Fig. 1 Organisation of phytochemical classes.

Tree nut phytochemical classes

Tree nuts contain the majority of phytochemical classes. To date, we are not aware of reports of organosulfurs or non-nutritive proteins (for example, antioxidant enzymes) in tree nuts. The present report examines the content of total phenols, flavonoids, proanthocyanidins (PAC), stilbenes, phytosterols, carotenoids and other classes in tree nuts.

Total phenols

Phenolics are a major phytochemical class, and include the broad term ‘polyphenols’, meaning a molecule with one or more phenolic groups. The Folin–Ciocalteu assay is commonly used as a non-specific measure of ‘total phenols’ or ‘total polyphenols’. However, the assay reagent also reacts with sugars, ascorbic acid, aromatic amines and other non-phenolic substances, many of which are present in tree nuts. Thus, total phenols can be regarded as only an approximation of polyphenol content in tree nuts.

Flavonoids

Flavonoids are a subclass of phenolics, characterised by a chalcone C6C3C6 structure, and include the main six subclasses: flavonols, flavones, flavanones, flavan-3-ols, anthocyanidins and isoflavones (Fig. 2). Flavan-3-ols, flavonols and anthocyanins are the main flavonoids present in nuts, while flavanones and isoflavones are found in lesser amounts.

Fig. 2 Major flavonoid classes and other representative phytochemicals present in tree nuts.

Proanthocyanidins

PAC are flavan-3-ol oligomers linked through carbon–carbon bonds. Type A PAC consist of a C4 to C6 or C8 interflavan bond and a C2-ether bond to the flavanol extension. Type B PAC have single C4 to C6 or C8 interflavan bonding (Fig. 2). Tree nut PAC are comprised mainly of (+)-catechin and ( − )-epicatechin, but also include afzelechin (almonds) and epigallocatechin (hazelnuts, pecans, pistachios)(Reference Gu, Kelm and Hammerstone1Reference Monagas, Garrido and Lebron-Aguilar3). Among tree nuts, the A-type PAC have been found only in almonds. The majority of tree nut PAC are highly polymerised (> 10-mers)(Reference Gu, Kelm and Hammerstone1).

Stilbenes

Stilbenes are similar to chalcones, as their structure consists of two phenyl groups interconnected through an ethene bond. The ethene bond is mainly in the trans configuration, but may revert to the cis form on exposure to light or heat. Resveratrol and piceid are the only stilbenes thus far identified in tree nuts, and are found in pistachios (Fig. 2).

Phytosterols

Phytosterols are lipophilic plant-synthesised steroids. Sterols consist of three six-carbon rings, one five-carbon ring attached to an aliphatic chain, and a C3 hydroxyl group on the A ring(Reference McClements, Decker, Damodaran, Parkin and Fennema4). Sterol esters have a fatty acid esterified to the C3 hydroxyl group(Reference McClements, Decker, Damodaran, Parkin and Fennema4). Sterols and stanols are differentiated by an alkene bond at the C1 position on the B ring. Tree nut phytosterols are mainly composed of β-sitosterol (Fig. 2).

Carotenoids

Carotenoids are polyisoprenoids with differing degrees of conjugated double bonds (Fig. 2). In contrast to other plant foods, tree nuts contain very low amounts of carotenoids with α- and β-carotene, β-cryptoxanthin, lutein and zeaxanthin found in μg/100 g concentrations when present at all. Pistachios present a modest exception, with a mean β-carotene and lutein content of 0·21 and 4·4 mg/100 g dry weight, respectively(Reference Kornsteiner, Wagner and Elmadfa5).

Other phytochemical classes

Tree nuts also contain phytates and the lipid subclasses of chlorophylls and sphingolipids. Other phenolic constituents consist of lignans, alkylphenols and hydrolysable tannins (HT). Walnuts also contain the alkaloid melatonin and the naphthoquinone juglone (Fig. 2).

Phytochemical databases

A number of databases report the phytochemical content of foods (Table 1). In the present report we analysed the US Department of Agriculture (USDA) flavonoid, isoflavone, PAC and standard reference databases, along with the Phenol-Explorer and European Food Information Resource (EuroFIR) databases. We excluded the remaining databases due to inactivity, lack of quantitative information for tree nut phytochemicals or incomplete citations of data sources. Also, we did not analyse international food composition databases equivalent to the USDA Standard Reference, which may include carotenoid or sterol information for tree nuts.

Table 1 Databases that include phytochemical or antioxidant content of foods

USDA, US Department of Agriculture; PAC, proanthocyanidins; ORAC, oxygen radical absorbance capacity; TP, total phenols; FRAP, ferric-reducing antioxidant power; EuroFIR, European Food Information Resource.

* Analysed in the present report.

US Department of Agriculture phytochemical databases

The USDA Nutrient Data Laboratory (Beltsville, MD, USA) established databases for total phenols, flavonoids, isoflavones and PAC(69). The Nutrient Data Laboratory maintains these databases and encourages submission of data directly to their laboratory. In general, the USDA databases report phytochemical mean, minimum and maximum contents, a confidence code that judges the reliability of the data, and the source of information. The USDA phytochemical databases are not frequently updated. For example, the USDA flavonoid database was released in 2003, and updated in 2007. Phytochemical content is reported as aglycone equivalents, which in some cases has been converted from glycoside equivalents. Thus, the phytochemical content of some tree nuts may not match values reported in the literature. This method facilitates combining data from studies using hydrolysis to remove glycosides from polyphenols. The post-harvest processing of tree nuts is not distinguished in these databases, but it should be noted that the flavonoid data are from commercial samples(Reference Harnly, Doherty and Beecher10).

US Department of Agriculture phytochemical databases: total phenols

The USDA Oxygen Radical Absorbance Capacity (ORAC) database includes the total phenol value of each tree nut (Table 2) (6). The data are derived from only one study, with seven or eight samples for each tree nut. Pecans, pistachios and walnuts have the highest total phenol content, with 1556 to 2016 mg gallic acid equivalents (GAE)/100 g.

Table 2 Total phenols content of nine tree nuts reported in the US Department of Agriculture (USDA)(6) and Phenol-Explorer(Reference Neveu, Perez-Jiménez and Vos16) databases

GAE, gallic acid equivalents.

US Department of Agriculture phytochemical databases: flavonoids

The USDA flavonoid database reports the flavan-3-ol, flavanone, flavonol and anthocyanin content of each tree nut (Table 3) (8). Pecans, pistachios, almonds and hazelnuts have the highest reported flavonoid content, with 12 to 34 mg flavonoids/100 g. The data for the USDA database are derived from only three studies and the number of samples ranged from 1 to 16. Therefore, the data populating the USDA flavonoid database are limited. Ideally, these values would be derived from multiple laboratories to arrive at reliable values for flavonoid content.

Table 3 Flavonoid content of tree nuts indexed in the 2007 US Department of Agriculture flavonoid database(8)

All tree nuts except for macadamias and Brazil nuts have flavonoid values listed in the USDA flavonoid database. In contrast, Yang et al. (Reference Yang, Liu and Halim11) reported 107 mg catechin equivalents/100 g in Brazil nuts, and 140 mg catechin equivalents/100 g in macadamias, using a non-specific analytical technique. Therefore, more rigorous investigations into the flavonoid content of Brazil nuts and macadamias are warranted.

Flavan-3-ols, flavonols and anthocyanins are the main flavonoids in nuts. Cashews and pine nuts do not contain anthocyanins. Flavonols are also reported for almonds and pistachios, mainly as isorhamnetin and kaempferol for almonds and quercetin for pistachios. However, no studies are included in the database that measure isorhamnetin or kaempferol content in tree nuts other than almonds. Thus, a significant amount of phytochemical content remains uncharacterised from most tree nuts.

Pecans have the highest total flavonoid content among nuts at 34 mg/100 g, consisting mostly of flavan-3-ols and anthocyanins. Hazelnuts and almonds also have an appreciable content of flavonoids with 18 and 15 mg/100 g, respectively. Flavanones are only reported in almonds, but no studies included in the database have measured eriodictyol in the other tree nuts. Most confidence codes are A and B for all flavonoids and tree nuts, although an unidentified species of walnut received a C value for flavonoid data confidence.

US Department of Agriculture phytochemical databases: isoflavones

Last updated in 2008, the USDA isoflavone database contains entries for most tree nuts, except for macadamias and pine nuts(7). To our knowledge, there are no studies examining isoflavone content of macadamias, but Kuhnle et al. (Reference Kuhnle, Dell'Aquila and Aspinall12) reported 32 μg isoflavones/100 g pine nuts. The isoflavone database includes daidzein, genistein and glycitein content and their sums, reported as ‘total isoflavones’. Values for the isoflavones formononetin and coumestrol are also reported. Pistachios have the highest isoflavone content of nuts at 3·63 mg/100 g mainly as daidzein and genistein, more than 100-fold greater than levels of other nuts (Table 4). Only one or two samples have been analysed for the isoflavone data, and are derived from three references. The confidence codes for these data are mainly C and D values, but Brazil nuts received a B value. Therefore, more work is needed to quantify isoflavones in tree nuts, especially to analyse a wider number of samples for inclusion into the USDA isoflavone database.

Table 4 Isoflavone content of tree nuts listed in the US Department of Agriculture database(7)

NR, not reported.

US Department of Agriculture phytochemical databases: proanthocyanidins

The USDA PAC database was released in 2004(9). All of the tree nuts are included in the database, and values are based solely on the work by Gu et al. (Reference Gu, Kelm and Hammerstone1). In this study, Brazil nuts, pine nuts and macadamias had no detectable PAC. Between five and eight samples were analysed for each tree nut, and each nut was assigned a confidence code of ‘A’.

The USDA PAC database does not distinguish between A- and B-linked PAC or the polymer units (for example, catechin, epicatechin) and reports content as catechin equivalents. Therefore, the database is an approximation of PAC content. In part, this is due to lack of available standards for quantification and characterisation purposes. Also, since monomers are included, catechin and epicatechin content may overlap with the USDA flavonoid database flavan-3-ol content.

The majority of tree nut PAC are highly polymerised (> 10-mers). However, cashews only have monomer and dimer PAC. PAC are the predominant polyphenols in almonds, hazelnuts, groundnuts, pecans and pistachios. Hazelnuts and pecans have the highest PAC content with 501 and 494 mg/100 g, respectively (Table 5). No PAC have been reported in Brazil nuts, macadamias or pine nuts, but Venkatachalam & Sathe(Reference Venkatachalam and Sathe13) reported 10 mg catechin equivalents/100 g using a non-specific method of analysis.

Table 5 Total proanthocyanidins (PAC) content of tree nuts reported in the US Department of Agriculture database(9)

Future revisions of the USDA PAC database may include information about subunits, linkages, and more information about their characterisation. Prodanov et al. (Reference Prodanov, Garrido and Vacas14) and Monagas et al. (Reference Monagas, Garrido and Lebron-Aguilar15) provided qualitative and some quantitative information about almond and hazelnut PAC, but more work is needed to characterise PAC in these and other tree nuts, including developing quantitative methods.

Phenol-Explorer

Phenol-Explorer (PE) is a web-based database of the polyphenol content of foods(Reference Neveu, Perez-Jiménez and Vos16). PE was developed by Augustin Scalbert and colleagues at INRA Clermont-Ferrand, Unité de Nutrition Humaine. PE's web-based interface allows queries for foods or polyphenols. PE has more phenolic classes than the USDA databases, including ‘total phenols’, flavonoids, lignans, stilbenes, phenolic acids and other phenolics (Table 6).

Table 6 Polyphenols included in the Phenol-Explorer database(Reference Neveu, Perez-Jiménez and Vos16)

Phenol-Explorer total phenol database

The PE database includes the total phenol value of each tree nut (Table 2). As compared with the USDA total phenol database derived from Wu et al. (Reference Kornsteiner, Wagner and Elmadfa5), total phenol values presented in this database are derived from studies of Wu et al. (Reference Kornsteiner, Wagner and Elmadfa5) and Kornsteiner et al. (Reference Wu, Beecher and Holden17). Thus, the data retrieved in the PE database could be more consequential than those in the USDA database. Though not considered in detail in the present review, we note that chestnuts are included in the USDA total phenol database and are identified as having the highest total phenol content, followed by pecans, pistachios and walnuts.

Phenol-Explorer phytochemical database

PE is more versatile than the USDA phytochemical databases as it allows for conversion between units such as aglycone equivalents (the USDA database preferred method) or mg/100 g or mol/100 g equivalents for polyphenol glycosides. The web portal has an option for displaying polyphenol class totals. The polyphenol results are organised by method of quantification, such as chromatography, chromatography after hydrolysis, Folin assay (the common measure of total phenols), pH differential method for anthocyanin content, and normal-phase chromatography.

PE also has a variety of summary reports. The selected reports include alcoholic beverages, cereals, cocoa, fruits and fruit products, non-alcoholic beverages, oils, seasonings, seeds, soya and soya products, and vegetables. While tree nut oils are not included in the ‘oils’ report, tree nuts are included in the ‘seeds’ report.

We list the PE entries used for almonds, cashews, hazelnuts, pecans, pistachios and walnuts (Table 7). Notably, no flavonoid, PAC, or phenolic acid entries exist for Brazil nuts, macadamias or pine nuts. While Brazil nuts and macadamias have total phenol entries, pine nuts are not listed in PE. The flavonoid and PAC data included in PE for most tree nuts are largely similar to those in USDA databases. Accordingly, the data are mainly based on the references from Harnly et al. (Reference Harnly, Doherty and Beecher10) and Gu et al. (Reference Gu, Kelm and Hammerstone1) for flavonoid and PAC content. While groundnut isoflavones are listed in PE, tree nut isoflavone content is not. Also, while lignans are included in PE, the studies by Thompson et al. (Reference Thompson, Boucher and Liu18), Smeds et al. (Reference Smeds, Eklund and Sjoholm19) and Kuhnle et al. (Reference Kuhnle, Dell'Aquila and Aspinall12) which quantified lignans in many of the tree nuts are not currently entered. Therefore, existing and future studies of tree nut phytochemicals should be submitted to PE for inclusion. The PAC content of tree nuts is also listed in PE, and appears less than the values for the USDA PAC database (Table 8). This is because PE does not include PAC monomers in foods from Gu et al. (Reference Gu, Kelm and Hammerstone1).

Table 7 Phenol-Explorer concentration of flavonoids, phenolics, stilbenes and other phenols in nuts(Reference Neveu, Perez-Jiménez and Vos16)

fw, Fresh weight.

Table 8 Phenol-Explorer listed concentration of nut proanthocyanidins(Reference Neveu, Perez-Jiménez and Vos16)

fw, Fresh weight.

PE includes data for phenolic acids, stilbenes and naphthoquinones, which are not currently accounted for in the USDA phytochemical databases. Since PE has the ability to compile data for more polyphenol classes, is updated more frequently than USDA databases, and contains a greater number of food types, PE may become more widely used among polyphenol researchers than USDA databases. Nevertheless, existing quality data regarding tree nut lignans, flavonoids, alkylphenols and isoflavones should be submitted to PE for consideration of inclusion in the database.

The PE database has been recently employed to identify the richest dietary sources of polyphenols (as the sum of the contents of all individual polyphenols) and their intake among a large cohort of adults. Pérez-Jiménez et al. (Reference Pérez-Jiménez, Neveu and Vos20) reported five tree nuts (chestnuts, hazelnuts, pecans, almonds and walnuts) among the richest 100 dietary sources of polyphenols at a rank of 11, 21, 22, 40 and 79 containing 1215, 495, 493, 187 and 28 mg/100 g, respectively. Based upon serving sizes of 19, 28, 15 and 10 g, chestnuts, hazelnuts, pecans and almonds were ranked as 15, 21, 33 and 62 for their total polyphenol content of 230, 138, 69 and 19 mg/serving. It is noteworthy that using PE, the values obtained using the Folin assay were found to systematically exceed the total polyphenol content values. Using the French cohort of the SUpplémentation en VItamines et Minéraux AntioXydants (SU.VI.MAX) trial, Pérez-Jiménez et al. (Reference Pérez-Jiménez, Fezeu and Touvier21) assessed the dietary polyphenol intake of 4942 men and women aged 45–60 years and found total polyphenol intakes at 1193 (sd 510) mg/d per person with 8 (sd 18) mg/d derived from seeds, with 37, 27 and 14 % of this amount from walnuts, hazelnuts and chestnuts, respectively. Further, of the 41 (sd 39) mg/d per person intake of hydroxybenzoic acids, 8 % was derived from walnuts; of the 12 (sd 22) mg/d per person ( − )-epigallocatechin intake, 99 % was derived from tea but 0·2 % was consumed as almonds. In contrast, calculating total dietary polyphenols as the sum of extractable polyphenols, condensed tannins and hydrolysable polyphenols determined in their laboratory, Saura-Calixto et al. (Reference Saura-Calixto, Serrano and Goñi22) reported a total bioaccessible polyphenol intake of 2533 mg/d per person in Spain, with 107 mg/d per person derived from consumption of a mean of 5·9 g nuts/d.

US Department of Agriculture National Nutrient Database for Standard Reference for sterols

Phytosterols of tree nuts are reported in the USDA National Nutrient Database for Standard Reference, release 23 (SR-23)(23). The β-sitosterol campesterol and stigmasterol contents of most tree nuts are reported, excluding Brazil nuts and cashews (Table 9). Unlike the USDA phytochemical database, the tree nut phytosterol data in SR-23 are not derived from literature reports, but rather from data supplied by tree nut commodity boards and the Hammons Products Company in the case of black walnuts.

Table 9 Phytosterol content of tree nuts, according to US Department of Agriculture 2009 National Nutrient Database for Standard Reference, release 23(23)

NR, not reported.

* Other, δ-5-avenasterol, sitostanol, campestanol and other minor phytosterols.

The SR-23 phytosterol data for tree nuts range from 72 mg/100 g in English walnuts to 214 mg/100 g in pistachios. Tree nuts are mainly composed of β-sitosterol, but are also composed of a number of minor sterols, sterol esters and stanols. Thus, the phytosterol values for most tree nuts in SR-23 are somewhat less than literature values due to the contribution of other minor sterols.

The SR-23 data could be immediately improved by submitting data for Brazil nuts and cashews that contain 154 to 190 mg sterols/100 g. The USDA Nutrient Data Laboratory encourages submission of data to support SR-23, so the phytosterol data could potentially be updated. Since the almond data for total sterol content include minor sterols, it is plausible that these data could be included for other tree nuts and would more accurately reflect tree nut sterol content.

US Department of Agriculture National Nutrient Database for Standard Reference for carotenoids

The USDA SR-23 database also includes vitamin A equivalents, β-carotene, α-carotene, β-cryptoxanthin, lycopene, lutein and zeaxanthin content of tree nuts. As previously reported, raw pistachios have the highest carotenoid content among tree nuts, which is reported mainly as 1205 μg lutein and zeaxanthin/100 g pistachios, resulting in 415 IU vitamin A/100 g. Raw and dry roasted pistachios also have 13 and 21 retinoic acid equivalents/100 g. Similar to the data on phytosterols, some SR-23 tree nut carotenoid entries are derived from data submitted by tree nut commodity boards, but also include data generated by the USDA Nutrient Data Laboratory and a study by Perry et al. (Reference Perry, Rasmussen and Johnson24). As most tree nuts are not significant dietary sources of carotenoids, an effort to improve carotenoid data may not be worthwhile.

European Food Information Resource database

EuroFIR is funded through the European Union to develop a comprehensive food databank to be used as a single authoritative source for European food composition data(25). Additionally, EuroFIR has published reports about food and health, including a statement about nuts and risk of CVD. EuroFIR is developing a database for bioactive foods components. This database is unique in that it will compile both content and bioactivity data. The EuroFIR database, eBASIS (BioActive Substances in Food Information System), is not yet publicly available, but is currently available to member institutions.

Comparison of tree nut phytochemical database values relative to other foods

A report by Pérez-Jiménez et al. (Reference Pérez-Jiménez, Neveu and Vos20) used the PE database to compare the richest sources of dietary polyphenols. The seeds category, which includes tree nuts, was ranked third behind spices and fruits for containing the most number of items in their list of the 100 foods with the highest polyphenol content. Walnuts, hazelnuts and chestnuts were identified as main contributors to polyphenol content within the seeds class.

To compare tree nut phytochemical content with other whole plant foods, we retrieved database values for fruits and vegetables from PE. Apples, highbush blueberries, purple grapes, green beans, spinach, tomatoes and yellow onions were selected because they are commonly consumed and available for consumption in the USA. Polyphenol values were retrieved from PE and carotenoid and phytosterol values were from the USDA SR-23 database.

The reference fruits and vegetables had phytosterol values of 4 to 15 mg/100 g, while tree nuts had 72 to 214 mg/100 g. Spinach, tomatoes and green beans carotenoid and xanthophyll content provide 690 to 9377 IU vitamin A, which is significantly greater than for tree nuts. Pecans, walnuts, pistachios and hazelnuts had more than double total phenols and PAC than the comparison foods (Fig. 3). Almond, Brazil nut and cashew total phenols were comparable with those of green beans, spinach, blueberries and apples. The PAC content of almonds was similar to those of grapes and blueberries. Polyphenol content by HPLC varied, with blueberries, grapes, spinach and apples having 56 to 310 mg/100 g, while tree nuts had 1·1 to 54 mg/100 g. The stilbene content of purple grapes was comparable with that of pistachios, with 0·19 and 0·11 mg/100 g, respectively. The database value for pistachio content is somewhat higher than the literature average of 0·8 mg stilbene/100 g (Table 10). Walnuts and walnut liquor were the only foods with naphthoquinone content in PE. Alkylphenol contents of cashews and pistachios are not reported in PE, or for the reference vegetables. However, bran breakfast cereals and whole grain flour bread have 286 and 25 mg/100 g, respectively. Several reports in the literature have assigned 144 and 44 mg alkylphenols/100 g for cashews and pistachios, respectively (Table 11). Similarly, while tomatoes have 0·02 mg lignan/100 g, tree nuts values which range from 0·02 to 0·97 mg lignin/100 g are not reported in PE (Table 11). Since all of the polyphenol classes have not been comprehensively surveyed in fruits, vegetables and tree nuts, it is difficult to draw reliable conclusions about the polyphenol abundance from HPLC analysis alone. More work is necessary to characterise, quantify and report fruit, vegetable and tree nut polyphenol values to phytochemical databases.

Fig. 3 Polyphenol content of reference foods and tree nuts in the Phenol-Explorer database. (), Total phenols; (□), polyphenols by HPLC; (■), proanthocyanidins.

Table 10 Phytochemical content of tree nuts reported in the literature*

ND, not determined in the literature; < LOD, below limit of detection.

* Values were determined by compiling data from all available literature reports. Means were based on the reported values for distinct samples; for example, if a study analysed two varieties of tree nuts, the content of both varieties would be included in the determination of the mean.

mg gallic acid equivalents/100 g, a non-specific measure.

Proanthocyanidin values include monomers that are also included in the flavonoid group.

§ mg catechin equivalents/100 g, a non-specific measure.

Table 11 Phytochemical content of tree nuts reported in the literature*

ND, not determined in the literature.

* Values were determined by compiling data from all available literature reports or database values. Means were based on the reported values for distinct samples; for example, if a study analysed two varieties of tree nuts, the content of both varieties would be included in the determination of the mean.

Tree nut phytochemical values reported after database publication

We conducted a comprehensive search of the Chemical Abstracts (CAPLUS) and MedLine literature databases to obtain the most recent qualitative and quantitative information on tree nut phytochemicals in January and February 2010 and updated our search in May 2011. From the initial search, we retrieved 368 references pertaining to the phytochemical composition of tree nuts. Then we extracted information including the source and type of tree nut and extraction and analytical methods. In some cases, the data needed to be transformed into values reflecting the content on a 100 g fresh weight of tree nut basis. These results are summarised in Table 10, Table 11 and Fig. 4, and elaborated on below.

Fig. 4 Phytochemical database values for tree nuts relative to current literature (■) values for (a) total phenols, (b) flavonoids, (c) proanthocyanidins and (d) sterols. (), US Department of Agriculture; (□), Phenol-Explorer; GAE, gallic acid equivalents.

Total phenols and flavonoids

Total phenols

The total phenol values among the nine tree nuts reviewed here vary widely (Table 10), with walnuts and pecans being the top two, followed by pistachios with its value being 50 % lower. Almonds, Brazil nuts, cashews, macadamias and pine nuts all contain similar total phenol content between 200–300 mg GAE/100 g.

As compared with the data presented in the two databases (USDA and PE), total phenol values of almonds, Brazil nuts, cashews, macadamias, pecans and walnuts are not markedly different while mean literature values of hazel nuts and pistachios are 50 % lower than database values and pine nuts are 2-fold larger. There are numerous factors that contribute to the inconsistency in the reported values, including the specific methodology for extraction of the phenols, nut cultivars and nut processing. This issue is discussed below.

Flavonoids

Literature values for flavonoid content of tree nuts range from 0·03 mg/100 g in pine nuts to 2700 mg/100 g in pecans (Table 10). The content of flavonoids has been reported for each tree nut, but comprehensive and systematic investigations characterising flavonoids from tree nuts are lacking. For example, Brazil nuts are reported to have 108 mg flavonoids/100 g by Yang et al. (Reference Yang, Liu and Halim11, Reference Yang26) using a non-specific measure of flavonoids. In contrast, Harnly et al. (Reference Harnly, Doherty and Beecher10) did not find flavonoids in Brazil nuts(Reference Harnly, Doherty and Beecher10). Brazil nuts contain the isoflavones daidzein and biochanin A, albeit at low levels(Reference Kuhnle, Dell'Aquila and Aspinall12). John & Shahidi(Reference John and Shahidi27) quantified catechin, ellagic acid and phenolic acids in Brazil nuts, but about 10-fold less than the report by Yang et al. (Reference Yang, Liu and Halim11). Similarly, Yang et al. found 137·9 mg catechin equivalents/100 g in macadamias(Reference Yang, Liu and Halim11). Thus, a more careful and comprehensive analysis of macadamia and Brazil nut flavonoids and phenolics is warranted.

Flavonoids: pecans

Pecans have an apparently high value for flavonoid content because Malik et al. (Reference Malik, Perez and Lombardini28) reported 1800 to 4700 mg catechin/100 g pecans. This is significantly larger than the report by Harnly et al. (Reference Harnly, Doherty and Beecher10) of only 7·2 mg catechin/100 g pecans. The reason(s) for this extreme difference is not clear, as both techniques employed direct extraction and used similar methods for quantification. Potentially important, Malik et al. (Reference Malik, Perez and Lombardini28) used defatted kernels for extraction, whereas Harnly et al. (Reference Harnly, Doherty and Beecher10) did not.

Flavonoids: almonds

For almonds, a number of reports were published after the USDA flavonoid database release. These include studies from Monagas et al. (Reference Monagas, Garrido and Lebron-Aguilar3), Hughey et al. (Reference Hughey, Wilcox and Minardi29), Garrido et al. (Reference Garrido, Monagas and Gomez-Cordoves30), Mandalari et al. (Reference Mandalari, Tomaino and Arcoraci31), Bolling et al. (Reference Bolling, Dolnikowski and Blumberg32, Reference Bolling, Dolnikowski and Blumberg33) and Teets et al. (Reference Teets, Minardi and Sundararaman34). However, earlier reports by Chen et al. (Reference Chen, Milbury and Lapsley35) and Frison et al. (Reference Frison and Sporns36, Reference Frison-Norrie and Sporns37) were not included in the last revision of the USDA flavonoid database. Combining these reports yields an average of 25·01 mg flavonoids/100 g almonds.

Flavonoids: cashews

A systematic investigation into cashew flavonoid content is lacking, but Kuhnle et al. (Reference Kuhnle, Dell'Aquila and Aspinall12) added to the values of formononetin and biochanin A reported in the USDA isoflavone database and PE.

Flavonoids: hazelnuts

Polyphenols have been further characterised in hazelnut skins. Monagas et al. (Reference Monagas, Garrido and Lebron-Aguilar15) reported the catechin content and Del Rio et al. (Reference Del Rio, Calani and Dall'Asta38) reported monomeric and oligomeric flavan-3-ols, flavonols, dihydrochalcones and phenolic acids in hazelnut skins. Although these studies did not report polyphenol content in terms of whole hazelnuts, monomeric and oligomeric flavan-3-ols were found to be the predominant polyphenol subclass, accounting for 95 % of total polyphenols(Reference Del Rio, Calani and Dall'Asta38). In other studies, Yurttas et al. (Reference Yurttas, Schafer and Warthesen39) reported quercetin from hazelnut extracts, whereas Harnly et al. (Reference Harnly, Doherty and Beecher10) did not detect quercetin following acid hydrolysis of extracts.

Flavonoids: pistachios

In their analysis of pistachios, Ballistreri et al. (Reference Ballistreri, Arena and Fallico40) and Seeram et al. (Reference Seeram, Henning and Niu41, Reference Seeram, Zhang and Henning42) found eriodictyol and anthocyanin. Gentile et al. (Reference Gentile, Tesoriere and Butera43), Seeram et al. (Reference Seeram, Zhang and Henning42) and Kuhnle et al. (Reference Kuhnle, Dell'Aquila and Aspinall12) also reported new isoflavone data for pistachios that could be included in future USDA database updates.

Flavonoids: walnuts

Catechin was detected in extracts of walnuts by Gómez-Caravaca et al. (Reference Gomez-Caravaca, Verardo and Segura-Carretero44). Quercetin was found in black walnuts but not quantified by Anderson et al. (Reference Anderson, Teuber and Gobeille45). Kuhnle et al. (Reference Kuhnle, Dell'Aquila and Aspinall12) added to the isoflavone data available for walnuts.

The widespread presence of flavonoids in tree nuts but the absence of data on the flavonoid content of macadamias, Brazil nuts and pine nuts suggests that thoughtful analyses of these nuts are warranted. Importantly, since truly comprehensive analyses of flavonoids in most tree nuts are lacking and further work to optimise extraction methods is required, further studies are required to confirm and extend the accuracy, breadth and reliability of the available quantitative data.

Proanthocyanidins

A number of non-specific measures of PAC content exist for all tree nuts. However, only studies of almond PAC by Amarowicz et al. (Reference Amarowicz, Troszyoska and Shahidi46), Prodonov et al. (Reference Prodanov, Garrido and Vacas14) and Urpi-Sarda et al. (Reference Urpi-Sarda, Garrido and Monagas47) and a study of PAC in almond and hazelnut skins by Monagas et al. (Reference Monagas, Garrido and Lebron-Aguilar15) have added qualitative and quantitative data on tree nut PAC since the report by Gu et al. (Reference Gu, Kelm and Hammerstone1). Since PAC are estimated to be the most abundant polyphenols in tree nuts, more efforts are needed to develop quantitative methods of PAC analysis in tree nuts.

Stilbenes

Pistachios are the only tree nut with reported stilbene content, with 803 μg/100 g. Only the study by Tokusoglu et al. (Reference Tokusoglu, Unal and Yemis48) is included in PE. Studies by Gentile et al. (Reference Gentile, Tesoriere and Butera43), Grippi et al. (Reference Grippi, Crosta and Aiello49) and Ballistreri et al. (Reference Ballistreri, Arena and Fallico40) have reported on the stilbene content of pistachios but these data have yet to be submitted or included in the PE database. Other tree nuts may contain stilbenes, but a systematic analysis of their abundance is lacking.

Phytosterols

More than sixty studies have reported tree nut sterol data, but only one is included in the SR-23 database. Notably, cashews and Brazil nuts have significant phytosterol content, but are not included in the SR-23 database. Nearly all values are reported on an oil basis, so future research efforts should also report values on a whole-nut basis to facilitate entry into databases. Preliminary reports suggest eBASIS also contains values for tree nut sterols. Minor sterols, sterol esters and stanols have been quantified in tree nuts or their oils (Table 12).

Table 12 Sterols, stanols and sterol esters quantified in tree nuts

Carotenoids

In addition to the USDA SR-23 database, Kornsteiner et al. (Reference Kornsteiner, Wagner and Elmadfa5) reported lutein and β-carotene in tree nuts. Bellomo et al. (Reference Bellomo, Fallico and Muratore50) further reported on the lutein content of pistachios.

Other classes

Phenolic acids and aldehydes

PE includes values for simple phenolics in tree nuts. Pecans and walnuts have high simple phenolic content at 2558 and 39·1 mg/100 g, respectively. The phenolic acids of pecans are primarily gallic acid, while those of walnuts are syringic acid. A high content of ellagic acid (28·5 mg/100 g) was found in Persian walnuts by Li et al. (Reference Li, Tsao and Yang51). Gómez-Caravaca et al. (Reference Gomez-Caravaca, Verardo and Segura-Carretero44), Shahidi et al. (Reference Shahidi, Alasalvar and Liyana-Pathirana52) and Alasalvar et al. (Reference Alasalvar, Karamac and Amarowicz53) also reported quantitative data for phenols in walnuts and hazelnuts, but these data have not been entered into PE. Wijeratne et al. (Reference Wijeratne, Amarowicz and Shahidi54, Reference Wijeratne, Abou-Zaid and Shahidi55) reported simple phenolics in almond skin, but the quantitative data are not reported on a nut basis. More recently, Mandalari et al. (Reference Mandalari, Tomaino and Arcoraci31) have reported on a variety of phenolic acids in almond skin; these data are not included in the current version of PE.

No quantitative data for simple phenols are reported for cashews or pine nuts. Thus, a systematic evaluation of phenols in these tree nuts would be useful to establish the simple phenols present in these nuts.

Alkaloids

One report by Reiter et al. (Reference Reiter, Manchester and Tan56) quantified melatonin in walnuts. There are no other qualitative reports of phyto-alkaloids in tree nuts.

Phytates

Tree nuts contain a significant amount of phytates, from 100 to 2500 mg/100 g (Table 11). Almonds have the highest reported phytate content, with pine nuts and Brazil nuts having the lowest content.

Chlorophylls

Pistachios have the highest chlorophyll content at 11 000 μg/100 g. In contrast, pine nuts (Aleppo pine nuts; Pinus halepensis Mill.) harvested in Tunisia contain 3 μg/100 g chlorophyll. No other published information is available on the chlorophyll content of other tree nuts.

Lignans

Lignans are included in the PE and eBASIS databases. Tree nuts contain 67–973 μg lignans/100 g, with the highest values reported for cashews (Table 11). To date, there have been no reports of lignans in macadamia nuts. Smeds et al. (Reference Smeds, Eklund and Sjoholm19), Thompson et al. (Reference Thompson, Boucher and Liu18) and Kuhnle et al. (Reference Kuhnle, Dell'Aquila and Aspinall12) each reported tree nut lignans. Future studies should also investigate the lignan content of macadamias.

Alkylphenols

Cashews and pistachios have significant alkylphenol contents at 144 and 44 mg/100 g, respectively. The alkylphenols in cashews and other tree nuts are principally cardanols, anacardic acid and cardols(Reference Lercker, Strocchi and Conte57Reference Trevisan, Pfundstein and Haubner59).

Naphthoquinones

Pecans and walnuts have 41 and 12 mg juglone/100 g, respectively. Naphthoquinones have not been reported in other tree nuts. Data from Colaric et al. (Reference Colaric, Veberic and Solar60) for walnut juglone are included in PE. The pecan juglone content reported by Hedin et al. (Reference Hedin, Langhans and Graves61) (regarding tree leaves) and Borazjani et al. (Reference Borazjani, Graves and Hedin62) used less reliable methods for their analyses and, thus, are unlikely to be included in the PE database. Thus, an updated survey of juglone in pecan kernels is necessary to include this nut in PE.

Hydrolysable tannins

HT have only been quantified in walnuts, with 27·56 mg/100 g. Glansreginins A and B are the only HT to be quantified, but more than fifty HT have been characterised in walnuts(Reference Anderson, Teuber and Gobeille45, Reference Cerda, Tomas-Barberan and Espin63Reference Zhang, Liao and Moore68). Future efforts should focus on quantifying these HT in walnuts. The presence of ellagic acid in pecans and almonds and gallic acid in pecans and hazelnuts also suggests that more work is needed to characterise HT in these nuts. Thus, efforts should be made to determine structures of HT in walnuts and other tree nuts.

Sphingolipids

Sphingolipids, mainly squalene and cerebroside, have been reported in all tree nuts except macadamias. Reported sphingolipid content ranges from 0·4 mg/100 g in pistachios to 612 mg/100 g in walnuts. Brazil nuts also have high sphingolipid content at 593 mg/100 g. The majority of the sphingolipid data have been derived by Miraliakbari & Shahidi(Reference Miraliakbari and Shahidi69Reference Miraliakbari and Shahidi71) utilising a non-specific method of quantification. Thus, more effort is needed to gain reliable data for the sphingolipid content of tree nuts.

Summary of phytochemical databases

Current knowledge

Tree nuts contain an abundance of phytochemicals. All tree nuts contain significant amounts of phytates (0·2 to 2·5 g/100 g) and sterols (106 to 234 mg/100 g). Relative to other tree nuts, almonds, hazelnuts, pecans and pistachios have higher contents of PAC, ranging from 184 to 501 mg/100 g. Flavonoids have been detected in all tree nuts, but pecans, macadamias, almonds and pistachios have the highest concentrations (25 to 2713 mg/100 g). Pecans and walnuts have appreciable phenolic acids and aldehydes, with 2052 and 39 mg/100 g, respectively, but not all tree nuts have been surveyed for simple phenolics. Brazil nuts, almonds, pecans, pine nuts and walnuts have significant sphingolipid content, with 304 to 613 mg/100 g. Cashews and pistachios have significant alkylphenol content, with 44 to 144 mg/100 g. Pistachios have higher carotenoids and chlorophylls than other tree nuts, and also have been found to contain stilbenes at 803 μg/100 g. Lignans have been quantified in all tree nuts except macadamias, and are present at 21 to 973 μg/100 g. Walnuts and pecans contain naphthoquinones at 12 and 41 mg/100 g, respectively, and walnuts have 28 mg HT/100 g and trace amounts of the alkaloid melatonin. Phytochemical databases do not index all tree nut phytochemicals, but more recent databases such as PE and eBASIS are more comprehensive indexes of bioactives. Further, all databases do not include key studies of tree nut phytochemicals.

Knowledge gaps

The present review of the literature on tree nut phytochemicals and associated database values has identified several gaps in knowledge or inconsistencies about tree nut phytochemicals, including:

  1. (a) Studies identified flavonoids in cashews, macadamias and Brazil nuts by non-specific methods. However, no studies have characterised flavonoids in these nuts sufficiently by reliable methods such that they cannot be included in phytochemical databases.

  2. (b) Despite total phenol content, studies are not available that have characterised simple phenolic compounds in pine nuts. A robust characterisation of simple phenols in other tree nuts is also lacking.

  3. (c) Except for almonds, no studies have quantified the common flavonoids isorhamnetin and kaempferol in tree nuts.

  4. (d) Confidence codes for USDA isoflavone data of tree nuts are low to poor.

  5. (e) Except for pistachios, no tree nuts have been surveyed for stilbenoids.

  6. (f) Except for walnuts, HT have not been quantified in tree nuts despite evidence for their presence in pecans, walnuts, hazelnuts and cashews.

  7. (g) PAC are quantified by non-specific measures in most tree nuts. Further study is needed to characterise the large-molecular-weight polymer linkages in these PAC and subunit constituents.

  8. (h) Except in cashews and pistachios, alkylphenols have not been characterised in tree nuts.

  9. (i) For pecan flavonoids, the literature reports values with three-orders of magnitude difference in the content of these phytochemicals, thus providing uncertainty to their actual values.

  10. (j) The lignan content of macadamias is unreported despite their being detected in all other tree nuts.

  11. (k) The quantitative data on juglone in pecans are outdated and should be reanalysed with updated methods.

  12. (l) The sphingolipid content of tree nuts could be improved by using more specific methods of quantification.

  13. (m) Studies validating quantification methods (for example, extraction conditions, recovery, stability) of tree nut phytochemicals are lacking.

Future directions

Accurate quantitative analysis and reporting of phytochemicals are critical to understanding the health-promoting properties and quality parameters of tree nuts. Of course, this issue applies to all plant foods and a broader and more detailed discussion of this topic is warranted in future forums. Opportunities should be created to support efforts to: (i) submit available data for inclusion in phytochemical databases, (ii) improve the confidence of values in these databases, and (iii) fill knowledge gaps. Accuracy and reliability of data collection should be improved by designing well-controlled studies. The criteria for sampling, analytical methodology and quality control as proposed by Holden et al. represent a good starting point(Reference Holden, Bhagwat and Patterson72). Quantification of freely extractable and bound polyphenols should also be considered(Reference Arranz, Saura-Calixto and Shaha73). Extraction conditions should also be optimised for each tree nut or food matrix. Since commercial analytical standards of high purity are lacking for many polyphenols, particularly tannins, suitable standards may need to be isolated before quantification. For future research efforts, a very good potential exists for finding new phenolic or other phytochemicals in tree nuts. Particularly, studies of macadamia, Brazil nut and pine nut phenolics are sparse. Further, there is incomplete knowledge of alkylphenols, stilbenes, HT and PAC in most tree nuts. Therefore, new research investigations in these areas are likely to be productive. While increasing the accuracy and precision of database values is an important goal, it is worth appreciating that the extraordinary complexity of the phytochemical composition of tree nuts and other plant foods could detract from one of the principal uses of these resources, i.e. determining nutrient intake from dietary assessments. Instruments for dietary assessment themselves typically conflate closely related foods and do not distinguish between factors such as cultivars. Interestingly, for application to nutrient databases, Milbury et al. (Reference Milbury, Chen and Dolnikowski74) summarised the flavonoid content of different almond genotypes by combining their analytical data with information on market sales to provide a basis for averaging nutrient composition values.

Factors affecting phytochemical content

Phytochemical contents vary extensively between and within nut genotypes. Variables imposed before (intrinsic) and after (extrinsic) harvesting contribute to this variation. While the tree nut genotype contributes to the majority of pre-harvest variation in nut phytochemical content, environmental stresses including starvation, infection, predation and UV light also modulate the capacity for phytochemical synthesis. Some particular phytochemicals are influenced by processing (roasting, irradiation and pasteurisation) and storage (temperature and duration) after nuts are harvested. Data for these factors vary among tree nuts. Thus, the following sections are organised by genotype and other pre- or post-harvest factors where supporting studies are available. It is worthwhile noting that the varying phytochemical composition of tree nuts may influence not only their putative health benefits to consumers but also the agricultural properties of the nut tree, such as resistance to moulds and pests.

Pre-harvest factors

Genetics (variety)

The pathways for the synthesis of phytochemicals are dictated principally by genetics. The data presented in the ‘Phytochemical databases with tree nuts’ and ‘Tree nut phytochemical values reported after database publication’ sections reveal a large difference in phytochemical profiles between tree nuts. This variation is a consequence of divergence of gene expression between nut types. In addition, there is a substantial diversity in phytochemical synthesis between genotypes. Comprehensive research investigating the effect of genotype on phytochemical content within each tree nut type has not been conducted. A few studies have reported that the genotype effect was significant on total phenol, flavonoid and ‘total antioxidant capacity’ (TAC) of almonds, hazelnuts, pecans, pistachios and walnuts.

Genetics (variety): almonds

There are three available almond studies examining the effect of genotype on phytochemical content in California almonds. Milbury et al. (Reference Milbury, Chen and Dolnikowski74) observed that among seven almond genotypes, total phenol content in Padre almonds at 241 mg/100 g GAE was 100 % larger than in Fritz almonds (Table 13). TAC in almond skins of seven genotypes also varied with a 142 % difference between the highest and the lowest ferric-reducing antioxidant power (FRAP) value. Bolling et al. (Reference Bolling, Dolnikowski and Blumberg32) and Milbury et al. (Reference Milbury, Chen and Dolnikowski74) characterised twenty flavonoids and phenolic acids in seven and eight California almond genotypes, respectively. They found the sum of their concentrations varied 2·7-fold between almond genotypes. They also found that polyphenol profile between almond genotypes was able to be discriminated based on their heredity (Fig. 5). Particularly, the concentration of total phenols in Sonora almonds was 170 % larger than in Fritz almonds. Hughey et al. (Reference Hughey, Wilcox and Minardi29) also reported that Carmel almonds had 47 % more flavonoid content than Nonpareil almonds. Similarly, a study of ten Portuguese almond genotypes showed a 4- and 18-fold difference in flavonoids and total phenols between genotypes, respectively(Reference Barreira, Ferreira and Oliveira75).

Table 13 Polyphenol content, total phenols and ferric-reducing antioxidant power (FRAP) values of seven almond genotypes over 3 years(Reference Milbury, Chen and Dolnikowski74)

(Mean values and standard deviations)

GAE, gallic acid equivalents; TE, Trolox equivalents.

a,b,c Mean values within a column with unlike superscript letters are significantly different (P ≤ 0·05; ANOVA and Tukey's honestly significant difference (HSD) test).

Fig. 5 Canonical discriminant analysis of almond genotypes based on polyphenol content and antioxidant activity(Reference Bolling, Dolnikowski and Blumberg32). M, Mission; F, Fritz; B, Butte; C, Carmel; N, Nonpareil; Mo, Monterey; S, Sonora; Can 1, first canonical variable; Can 2, second canonical variable. Data represent the first two canonical variables of almond samples by genotype with 80 % confidence ellipses.

The concentration of individual flavonoids in almonds depends upon the genotype. Bolling et al. (Reference Bolling, Dolnikowski and Blumberg32) found that Sonora almonds are particularly high in catechin and isorhamnetin-3-O-glucoside compared with Nonpareil almonds. Thus, genotype affects the type and concentration of flavonoids synthesised in almonds. The genotype effect on other phytochemicals in almonds remains to be determined.

Genetics (variety): hazelnuts

Amaral et al. (Reference Amaral, Casal and Citová76) observed that phytosterol contents differed between nineteen hazelnut genotypes harvested from Vila Real in 2001. The concentration of total sterols ranged from 134 to 263 mg/100 g oil, and the concentration of the main phytosterol, β-sitosterol ranged from 108 to 220 mg/100 g oil. Cristofori et al. (Reference Cristofori, Ferramondo and Bertazza77) reported that the total phenol content of hazelnuts varied among seven genotypes. Jakopic et al. (Reference Jakopic, Petkovsek and Likozar78) reported that the total phenol content of hazelnuts ranged from 70 to 478 mg GAE/kg kernels, with an average of 189·5 mg/kg among twenty hazelnut genotypes harvested in Maribor, Slovenia. Further, they reported that the concentrations of myricetin-3-O-rhamnoside ranged from 0·2 to 2·1 mg/kg, with an average of 1·0 mg/kg kernels; quercetin-3-O-rhamnoside ranged from 1·4 to 9·9 mg/kg, with an average of 3·6 mg/kg; quercetin-pentoside ranged from 0·05 to 0·15 mg/kg, with an average of 0·08 mg/kg; catechin ranged from 1·4 to 26·3 mg/kg, with an average of 7·3 mg/kg; gallic acid ranged from 0·09 to 0·52 mg/kg, with an average of 0·26 mg/kg; and protocatechuic acid ranged from 0·5 to 2·9 mg/kg, with an average of 0·9 mg/kg. Solar & Stampar(Reference Solar and Stampar79) also reported that epicatechin content ranged from 14·0 to 74·5 mg/kg kernels in sixteen hazelnut genotypes harvested in Slovenia. The impact of genotype on polyphenols in hazelnuts is consistent with that on almonds.

Genetics (variety): pecans

Vilarreal-Lozoya et al. (Reference Villarreal-Lozoya, Lombardini and Cisneros-Zevallos80) and Lombaridini et al. (Reference Lombardini, Villarreal-Lozoya and Cisneros-Zevallos81) reported that total phenol content of five pecan genotypes (Desirable, Kanza, Nacono, Pawnee and Shawnee) grown in Texas (USA) varied almost 1-fold, with concentrations ranging between 62 and 113 mg/100 g defatted kernels. Vilarreal-Lozoya et al. (Reference Villarreal-Lozoya, Lombardini and Cisneros-Zevallos80) also reported that TAC values in defatted kernel of five pecan genotypes (Desirable, Kanza, Nacono, Pawnee and Shawnee) grown in Texas were significantly different from one another. Hydrophilic ORAC values and 2,2-diphenyl-2-picrylhydrazyl (DPPH) values of the Kanza genotype, which were the highest, were 119 and 67 % larger than those of the lowest Desirable genotype. The relationship of genotype to individual flavonoid content has not been studied.

Genetics (variety): pistachios

Tokusoglu et al. (Reference Tokusoglu, Unal and Yemis48) reported that the trans-resveratrol content varied between five pistachio genotypes (Uzun, Kirmizi, Halebi, Ohadi and Sirrt) grown in Turkey. Uzun pistachios with 9 μg trans-resveratrol/100 g were 17·5-fold lower than the content of Ohadi pistachios.

Genetics (variety): walnuts

The genotype effect on walnut polyphenols has not been reported, but its effect is suggested by other data; for example, the tocopherol and fatty acid composition in nine walnut genotypes (Franquette, Lara, Marbot, Mayette, Mellanaise, Parisienne, Arco, Hartley and Rego) harvested in northeastern Portugal were different(Reference Amaral, Alves and Seabra82, Reference Amaral, Cunha and Alves83). Further, walnut leaves collected from the same nine genotypes have varied contents of nine constituent polyphenols(Reference Amaral, Valentao and Andrade84).

Amaral et al. (Reference Amaral, Casal and Pereira85) examined the phytosterol content of six walnut genotypes grown in northeastern Portugal (Table 14). The total sterol content of the Marbot genotype was 68 % greater than the Parisienne genotype. The difference was not ascribed to a geographic effect because walnut trees of all genotypes were planted in the same orchard.

Table 14 Genotype effect on sterol contents in walnuts(Reference Amaral, Casal and Pereira85)

Environment

In addition to genetics, environmental factors can regulate the synthesis of phytochemicals. These factors are either climatic (soil type, sun exposure (UV irradiation), rainfall) or agronomic (organic v. convention cultivation, irrigation, fertilisation, nut yield/tree, etc.). Particularly, environmental stress, i.e. exposure to light, infestation or drought, has a considerable impact on polyphenol synthesis because of their phytoalexin function, defending against predators and pathogens, and in providing reproductive advantage as attractants of pollinators and seed dispensers. The impact of environmental factors on nut phytochemicals has not been systematically investigated.

Almonds

Seasonal factors include climate, soil nutrition, infestation and related parameters. Bolling et al. (Reference Hughey, Wilcox and Minardi29) examined total phenols, polyphenols and FRAP values in almonds across three harvest seasons and found that season had a small but statistically significant effect on total polyphenol content in almonds while there were not differences in total phenols and FRAP values (Table 15). These results suggest the overall phenol production, as well as TAC, may not fluctuate importantly between seasons. However, a more robust study with a larger sample size is necessary to confirm the stability of phenol production between seasons.

Table 15 Effect of harvest season on polyphenol content and antioxidant activity of Butte, Carmel and Nonpareil almonds(Reference Bolling, Dolnikowski and Blumberg32)

(Mean values and standard deviations, n 9)

GAE, gallic acid equivalents; FRAP, ferric-reducing antioxidant power; TE, Trolox equivalents.

a,b Mean values within a column with unlike superscript letters are significantly different (P ≤ 0·05; ANOVA and Tukey's honestly significant difference (HSD) test).

Pecans

De la Rosa et al. (Reference de la Rosa, Alvarez-Parrilla and Shahidi86) characterised the content of ellagic, gallic, p-hydroxybenzoic and protocatechuic acids and TAC in pecans grown in three locations of the State of Chihuahua, Mexico. They found that growing location did not affect TAC measured by ORAC, DPPH, 2,2′-azino-bis(3-ethylbenzothiazolin-6-sulfonic acid (ABTS) and hydroxyl radical-scavenging assay. The content of the four phenolic acids also was not different, with average values of 5, 220, 55 and 21 mg/g, respectively.

Hedin et al. (Reference Hedin, Langhans and Graves61) reported that juglone contents in pecans were increased along with harvesting months (from June to September) within a season from 47·9 (June and July) to 116 mg/100 g (August and September).

Pistachios

The effect of geographic location on the phytochemical content of pistachios has been studied in Europe. Bellomo & Fallico(Reference Bellomo and Fallico87) measured anthocyanins, chlorophylls and xanthophylls in pistachios collected from Italy and Turkey in the 2001–2002 season (Table 16) and found that pistachios from Turkey generally had a much lower phytochemical content. However, Grippi et al. (Reference Grippi, Crosta and Aiello49) found in a small study with twelve pistachio samples that Sicilian pistachios collected from orchards in Bronte and Agrigento, regions about 100 miles (160 km) apart, had comparable total resveratrol content at 0·7 mg/100 g kernels. The geographic effect on phytosterols in pistachios was also reported by the same group, where the distribution of nine phytosterols in pistachios harvested in Italy (Bronte and Agrigento), Turkey, Greece and Iran differed(Reference Arena, Campisi and Fallico88). β-Sitosterol, the main phytosterol found in pistachios, was found at 85·5 and 88·0 %, respectively, with Δ5-avenasterol at 9·2 and 5·7 %, respectively, in Italy and Iran.

Table 16 Geographic effect on anthocyanins, chlorophylls and xanthophylls in pistachios(Reference Bellomo and Fallico87)

Walnuts

Hedin et al. (Reference Hedin, Langhans and Graves61) reported the juglone content in black walnuts was increased from 79 to 193 mg/100 g along with harvesting months (from June to September) within a season. Amaral et al. (Reference Amaral, Valentao and Andrade84) found, in walnut leaves, that there was a seasonal effect on nine polyphenol compounds (3-caffeoylquinic, 3-p-coumaroylquinic and 4-p-coumaroylquinic acids, quercetin 3-galactoside, quercetin 3-arabinoside, quercetin 3-xyloside, quercetin 3-rhamnoside, a quercetin 3-pentoside derivative and a kaempferol 3-pentoside derivative), implicating a seasonal effect on walnut polyphenols.

Post-harvest factors

There are complex and interactive effects of agronomic practices on the production of phytochemicals in many crops, i.e. organic v. conventional cultivation. Precision deficit irrigation practices were found to enhance lycopene and other carotenoids in watermelons and tomatoes, but at the risk of lowered productivity. However, the effect of agronomic practices on tree nuts is not available, so research into this topic is warranted.

After harvesting, nuts are commonly subjected to different treatments before consumption, including pasteurisation, bleaching, roasting, irradiation and storage. Among the tree nuts where research has been conducted, there are significant effects of post-harvesting processing treatments on phytochemicals in almonds, pecans, pistachios and walnuts.

Almonds

Almonds are currently subjected to mandatory pasteurisation or roasting treatments before consumption due to food safety concern. Bolling et al. (Reference Bolling, Blumberg and Oliver Chen89) showed that three pasteurisation procedures did not change TAC of phytochemicals in almond skins, measured by FRAP and total phenol assays, or individual flavonoid concentrations (Table 17). However, because there were large variations in study outcomes within the pasteurisation treatments, a more robust study investigating the pasteurisation effect on almond phytochemicals is warranted. It has been recognised that roasting is potentially destructive to phytochemicals. Bolling et al. (Reference Bolling, Blumberg and Oliver Chen89) found that roasting decreased total phenol content and FRAP values in almonds, but did not change concentrations of flavonoids. This discrepancy might be attributed to specific breakdown of heat-labile antioxidant constituents other than flavonoids.

Table 17 Effect of pasteurisation and roasting on almond skin flavonoids and phenolic acids, total phenols and ferric-reducing antioxidant power (FRAP) values(Reference Bolling, Blumberg and Oliver Chen89)

(Mean values and standard deviations)

GAE, gallic acid equivalents; TE, Trolox equivalents; PPO, polypropylene oxide; S1, steam treatment 1; S2, steam treatment 2.

* Significance was assessed by a paired t test for roasted samples (n 12) (P ≤ 0·05).

During long-term storage, nutrients in nuts are subjected to changes of temperature and humidity. Bolling et al. (Reference Bolling, Blumberg and Oliver Chen89) hypothesised that long-term storage could have a detrimental impact on the polyphenol content and TAC of almonds. In contrast, total polyphenol and total phenol content and FRAP values of raw almond skins were found to increase with storage duration, independent of storage temperature at 4 or 23°C (Fig. 6). Further, individual polyphenol compounds appeared to have different degrees of increase (Fig. 7). In particular, p-hydroxybenzoic acid increased about 400-fold after 15 months of storage.

Fig. 6 Storage of raw almonds in darkness at 4°C (-Δ-) and 23°C (-□-) for 15 months increased flavonoids and phenolic acids determined by liquid chromatography–MS (a), total phenols (b) and ferric-reducing antioxidant power (FRAP) (c) of almond skins(Reference Bolling, Blumberg and Oliver Chen89). Values are means (n 13), with standard errors represented by vertical bars, representing seven almond varieties. * Mean value was significantly different from that at 4°C (P ≤ 0·05).

Fig. 7 (a) Changes to flavonoid aglycone and phenolic acid content in almond skins upon storage at 23°C for 15 months(Reference Bolling, Blumberg and Oliver Chen89). (), p-Hydroxybenzoic acid; (), dihydroxykaempferol; (), kaempferol; (), eriodictyol; (), catechin; (), epicatechin; (), procatechuic acid; (), isorhamnetin; (), quercetin; (), naringenin. (b) Changes to flavonoid glycoside content in almond skins upon storage at 23°C for 15 months(Reference Bolling, Blumberg and Oliver Chen89). (), Quercetin-3-O-galactoside; (), isorhamnetin-3-O-glucoside; (), kaempferol-3-O-glucoside; (), isorhamnetin-3-O-rutinoside; (), naringenin-7-O-glucoside; (), kaempferol-3-O-rutinoside; (), kaempferol-3-O-galactoside; (), quercetin-3-O-rutinoside.

Cashews

The kernel of the cashew nut is removed from the shell by a process known as shelling, which can be achieved by various methods such as drying, steam roasting, oil-bath roasting, or cooking under high-pressure steam. Trox et al. (Reference Trox, Vadivel and Vetter90) examined that the effect of oil-bath roasting, steam roasting, drying, open pan roasting and Flores hand-cracking on carotenoid and tocopherol contents in kernels. They reported that shelling, roasting and drying promoted decreases in β-carotene, lutein, and α- and γ-tocopherol as compared with raw kernels, with widely varied magnitude of reductions (Table 18). The open pan roasting in general exhibited the highest level of decrease in phytochemicals probably due to the direct action of fire; and the Flores hand-cracking method led to a lower level of reduction of phytochemicals. In order to preserve phytochemicals, the selection of the shelling method for cashew nuts is critical.

Table 18 Effect of shelling on contents (μg/100 g DM) of selected carotenoids and tocopherols in cashew nut kernels(Reference Trox, Vadivel and Vetter90)

Hazelnuts

Schmitzer et al. (Reference Schmitzer, Slatnar and Veberic91) reported that roasting had a negative effect on individual phenolics but not on the total phenolic content and TAC (determined by DPPH) of hazelnuts. They found that the roasting decreased protocatechulic acid, phloretin-2-O-glucoside, catechin and epicatechin contents in whole hazelnuts of six genotypes harvested in Maribor, Slovenia. The percentage reduction in the four phenolic compounds could be as high as 84 %. On the other hand, gallic acid content was increased by the roasting, with the magnitude of the increase being from 2 to 818 %. The increase in gallic acid after roasting might be ascribed to degradation of HT.

Pecans

Food irradiation is a food safety procedure to eliminate pathogenic microbial contaminations and involves exposure of food to different sources of ionising energy. Villarreal-Lozoya et al. (Reference Villarreal-Lozoya, Lombardini and Cisneros-Zevallos92) studied the effect of irradiation on phytochemical contents in Kanza and Desirable pecans collected in the autumn of 2004 in Texas. Pecan kernels were treated with 0, 1·5 and 3 kGy irradiation, followed by storage at 40°C and 55 to 60 % relative humidity for up to 134 d. They found that this accelerated storage condition promoted decreases in total phenols (about 20 % reduction as compared with the initial values), condensed tannins (about 30 % reduction), and TAC measured by ORAC (no significant changes) and DPPH (about 15 % reduction for the Desirable genotype), while irradiation itself before storage did not have any major effect on the studied measures. The storage effect on phenol compounds in pecans is largely consistent with those found in almonds.

Pistachios

After harvesting, pistachios are typically sun dried in Italy. Ballistreri et al. (Reference Ballistreri, Arena and Fallico40) found that sun drying for 3 d decreased total phenol content and the majority of determined flavonoids and stilbenes in Bronte pistachios collected in Italy in 2007 (Table 19). The magnitudes of reduction ranged from 30 to 83 %.

Table 19 Content of phenolics (mg/100 g DM) in edible pistachio kernels of Bronte Pistacia vera (Reference Ballistreri, Arena and Fallico40)

GAE, gallic acid equivalents.

Gentile et al. (Reference Gentile, Tesoriere and Butera43) reported that roasting at 160°C for 40 min deceased total phenols, TAC, PAC and trans-resveratrol content in Bronte pistachios collected in Sicily in 2005 (Table 20). Interestingly, isoflavones in pistachios were not degraded by the roasting treatment. These results are consistent with those observed in almonds that roasting decreased FRAP and total phenol values and did not alter flavonoid concentrations(Reference Bolling, Blumberg and Oliver Chen89).

Table 20 The effect of roasting on total phenols, total antioxidant capacity (TAC) and flavonoids in edible kernels of pistachios(Reference Gentile, Tesoriere and Butera43)

GAE, gallic acid equivalents; TEAC, Trolox equivalent antioxidant capacity; TE, Trolox equivalents.

Pistachios in China are often bleached before retailing. Seeram et al. (Reference Seeram, Zhang and Henning42) examined the effect of bleaching treatment with different concentrations of H2O2 for 1 min, followed by 20 min of roasting at 60°C (140°F) on anthocyanins and TAC of in-shell pistachios. They found that bleaching significantly decreased cyanidin-glucoside and -galactoside concentrations and TAC measured by the Trolox equivalent antioxidant capacity (TEAC) assay in pistachio skins in a H2O2 concentration-dependent manner (Table 21). They also found that roasting alone significantly deceased cyanidin-glucoside, cyanidin-galactoside and TAC values compared with raw pistachio skins.

Table 21 Effect of bleaching and roasting on anthocyanins and total antioxidant capacity values in pistachio skins(Reference Seeram, Zhang and Henning42)

TEAC, Trolox equivalent antioxidant capacity.

Bellomo et al. (Reference Bellomo, Fallico and Muratore50) examined the storage effect on chlorophyll-a and -b and lutein in pistachios at 10, 25 and 37°C for up to 14 months. The pistachios were collected from Bronte, Italy in 2003. In general, these phytochemicals decreased over time, dependent on storage temperatures. On average, chlorophyll-a and -b and lutein were decreased by 50, 30 and 44 % at 14 months, respectively.

Walnuts

Sze-Tao et al. (Reference Sze-Tao, Schrimpf and Teuber93) observed that 5 min of roasting at 204°C caused a small but statistically significant decrease in tannins (catechin polymers) in walnuts (585 v. 520 mg catechin equivalents/100 g dry weight). This result is similar to the effect of roasting pistachios at 160°C for 40 min where the content of PAC decreased by 87 %.

Methodology of phytochemical determinations

Extraction of the constituent phytochemicals from the nut matrix is required before their determination by any analytic method. Given that a standardised methodology for different groups of phytochemicals has not been established, there are diverse protocols for their extraction and determination. A few common organic solvents, typically methanol, acetone, acetonitrile or ethyl acetate, have been generally employed to extract polyphenols from nuts; in addition, hexane and chloroform have been employed to extract more lipid-soluble compounds. Each solvent extracts a different profile of phytochemicals due to their wide range of polarity. Thus, different extraction solvents may explain some of the inconsistency in reported values of phytochemicals in tree nuts. Even though there are a few reports discussing the impact of extraction methodology on phytochemical content of foods, establishing a standardised protocol for phytochemical extraction would provide a platform to facilitate valid comparisons in phytochemical data reported by different laboratories and enhance confidence level in values summarised in nutrient databases.

In addition to the influence of extraction protocol, the instruments employed to determine phytochemicals in extracts have a profound effect on the accuracy of reported values. However, there is no published report comparing the consistency of phytochemical values using a wide spectrum of analytical instruments, such as liquid chromatography (LC)-MS, LC-MS/MS, and HPLC with spectrophotometric, fluorometric or electrochemical detection.

Almonds and hazelnuts

Almonds

Since organic solvents employed to extract polyphenols do not closely reflect the physiological bioaccessibility of polyphenols in the gastrointestinal tract, Chen & Blumberg(Reference Chen and Blumberg94) compared the amount of total phenols extracted from almond skins using acidified methanol solvent (M; acetic acid–methanol–water, 3·7:50:46·3 by vol.) and a gastrointestinal mimic juice solvent (GI, containing pepsin and pancreatic juice). They found that the total phenol content of almond skins was different by 4.8-fold (M v. GI solvent: 91.2 v. 14.9 μmol GAE/g or 15.5 v. 2.5 mg/g; P ≤ 0.05). Further, the LC-MS chromatograms of almond skin polyphenols extracted with M and GI at the same GAE concentration showed qualitatively different profiles of flavonoids, largely because of the absence in the GI solvent of catechin, epicatechin, kamperfol-3-O-glucoside, kaemperfol-3-O-galactoside, dihydroxy-kampferol, quercetin-3-O-glucoside, quercetin-3-O-galacoside, rutin, isorhamnetin, kaempferol, naringenin, quercetin and eriodictyol (Fig. 8). These results raise again the question regarding what extraction solvent(s) should be used for characterising nut phytochemicals.

Fig. 8 Typical liquid chromatography − MS/MS extracted ion chromatograms of almond skin polyphenolics from (a) acidified methanol extraction and (b) gastrointestinal juice mimic extraction(Reference Chen and Blumberg94). Peak numbers correspond to compounds as (1) catechin, (2) epicatechin, (3) quercetin-3-O-galactoside, (4) naringein-7-O-glucoside, (5) rutin, (6) quercetin-3-O-glucoside, (7) dihydroxylkaempferol, (8) kaempfer-3-O-galactoside, (9) kaempferol-3-O-glucoside, (10) kaempferol-3-O-rutinoside, (11) isorhamnetin-3-O-runtinoside, (12) eriodictyol, (13) quercetin, (14) naringenin and (15) isorhamnetin.

Hazelnuts

Alasalvar et al. (Reference Alasalvar, Karamac and Amarowicz53) compared the extraction efficiency of 80 % ethanol and 80 % acetone on total phenols in hazelnuts. They found that 80 % acetone was more efficient to extract phenols and tannins than 80 % ethanol (Table 22). Ghirardello et al. (Reference Ghirardello, Prosperini and Zeppa95) compared extraction of phenolic compounds using three different solvent mixtures (80 % (v/v) ethanol, methanol, and acetone with water) at different temperatures. Consistent with the results from Alasalvar et al. (Reference Alasalvar, Karamac and Amarowicz53), they found that 80 % acetone at 50°C exhibited the best extracting capacity with the highest total phenol content and TAC.

Table 22 Total phenols, condensed tannins and total antioxidant capacity measured by Trolox equivalent antioxidant capacity (TEAC) in 1 g dry extracts of hazelnuts(Reference Alasalvar, Karamac and Amarowicz53)

Phytosterols and sphingolipids

Miraliakbari & Shahidi(Reference Miraliakbari and Shahidi70) studied the effect of extraction solvents on the yield of phytosterols and sphingolipids in seven tree nuts. They employed two protocols: (i) three sequential extractions with hexane or (ii) three sequential extractions with chloroform once and then chloroform–methanol (1/1, v/v) twice. They reported that the chloroform–methanol solvent system produced a higher oil yield for all tree nuts than hexane (Table 23). They also measured sphingolipids and sterols including 22-nordehydrocholesterol, cholesterol, cholestanol, campesterol, stigmasterol, 24-methylenecholesterol, β-sitosterol, β-sitostanol and Δ5-avenasterol. They found that chloroform–methanol was equal or more effective in extracting sphingolipids and phytosterols than hexane, for example, with chloroform–methanol providing a 24 % larger sterol yield in pine nuts than methanol (Table 24).

Table 23 Oil yields of seven tree nuts extracted with hexane or chloroform–methanol(Reference Miraliakbari and Shahidi70)

Table 24 Yields of sphingolipids and sterols extracted by hexane or chloroform–methanol (CM) in seven tree nuts(Reference Miraliakbari and Shahidi70)

(Mean values)

* Mean values differ between the two solvent systems in the same nut.

Summary of factors affecting phytochemicals

Current knowledge

The phytochemical content of tree nuts has been reported in a few databases and many articles in the scientific literature. Nevertheless, our understanding on the effect or pre- and post-harvest factors on these values is quite limited. Table 25 summarises the effect of some of these impact factors on the values of eleven phytochemical classes, total phenols and TAC. Information in this area appears to be unavailable for Brazil nuts, cashews, macadamias and pine nuts. The data on almonds, hazelnuts, pecans, pistachios and walnuts indicate that most pre- and post-harvest factors have a significant effect on their polyphenol, total phenols and TAC. The storage effect on the changes in polyphenol content and TAC in almonds and pecans does not appear consistent. In addition, the effect of roasting on decreases in nut polyphenol concentration appears depends on the type of polyphenol; for example, isoflavones (pistachios), flavanols (almonds) and flavonols (almonds) are more resistant to heat than anthocyanins, PAC and trans-resveratrol (pistachios). Thus, more studies are necessary to elucidate the influence of these impact factors on the quality and quantity of nut phytochemicals.

Table 25 Summary of the effect of pre- and post-harvesting factors on phytochemical content in nine tree nuts

Y, yes; TP, total phenols; TAC, total antioxidant capacity; N, no; ↑ , increased; –, unchanged; ↓ , decreased.

To date, there has been no effort to conduct a systematic investigation into the impact of different methodologies for phytochemical extraction and quantification. A few studies have shown that the choice of solvents used for extracting polyphenols and phytosterols significantly affects the results obtained. For example, the capacity of acetone v. ethanol for extracting polyphenols is markedly different, although hexane and chloroform–methanol appear to possess similar efficacy in extracting phytosterols. Further complicating this situation are inter-laboratory comparisons of results obtained from different instruments even when similar solvent systems are employed. Although a systematic comparison of phytochemical values produced by different instruments is not available, inherent differences in instrument performance on parameters such as sensitivity, accuracy and precision would be expected to contribute substantially to differences between reports from multiple laboratories.

Knowledge gaps

The present review of tree nuts has identified several gaps in the knowledge about the effect of impact factors on tree nut phytochemicals and TAC, including:

  1. (a) The genotype of each tree nut has a significant impact on phytochemical content as has been shown for almond flavonoids, pecan total phenol and pistachio trans-resveratrol. Studies investigating the effect of genotype on other tree nuts, as well as their principal phytochemical classes, have not been conducted. This information is important to establishing the reliable values for including in phytochemical databases so that estimates of health benefits from nut consumption (and differences between types of nuts) can be investigated in observational studies. Further, this information can help to guide the breeding of more economically valuable and more nutritious nut genotypes.

  2. (b) Growing location and season have been found to affect some phytochemical classes in almonds, pecans, pistachios and walnuts. However, there is a need to better quantify and understand how important these factors are in altering the phytochemical profile and content of these and other tree nuts. Such data can assist in the improvement of agricultural practices for producing more (or less) phytochemicals for outcomes such as nut appearance, growth, resistance to pests and health benefits.

  3. (c) In general, post-harvest treatments, such as sun drying, storage, hot water blanching, high temperature roasting, irradiation and bleaching, appear to decrease the phytochemical content from that found in raw nuts. However, exceptions to this generalisation have been noted. For example, almond polyphenols are increased during storage and roasting almonds or pistachios does not affect flavonoids or isoflavones, respectively, but does decrease total phenols and TAC in both nuts. Thus, further research on post-harvest factors is required to improve the information provided to phytochemical databases and for considerations of modifying these methods to control the phytochemical content and composition of tree nuts.

  4. (d) Establishing standard methods for extracting and quantifying nut phytochemicals would provide a number of benefits to researchers, including the creation of accurate and reliable values for comparisons between nuts and genotypes and also understanding the stability of these values under varying agricultural and environmental conditions. Further, undertaking this effort with newer HPLC and LC-MS technologies will substantially upgrade the quality of data obtained earlier from less accurate and precise values associated with spectrophotometric assays.

Future directions

The phytochemical content of tree nuts is subject to the influence of many pre- and post-harvest factors, including genetics, environment, cultivation practice, climate, processing and storage. Further, the results from the determination of nut phytochemicals are dependent upon the methodology used to extract and measure them. Thus, the phytochemical values available in the published databases and in many reports in the scientific literature are limited by the absence of all the relevant information necessary to interpret them. Steps can be made through new research, thorough characterisation of the tree nut (including genotype, harvest location and year, processing, etc.), use of HPLC and LC-MS technologies, and careful reporting to provide more accurate, complete and precise information about their phytochemical profiles. This information can then be employed to optimise the production and processing of tree nuts for growth and appearance as well as for human health.

Evidence for bioactivity and health effects of tree nuts in humans

In general, tree nuts are a rich source of unsaturated MUFA and PUFA and are low in SFA. They also contain dietary fibre, protein, micronutrients, plant sterols and several other polyphenolic phytochemical compounds. Many polyphenols possess relatively potent antioxidant, anti-atherosclerotic, anti-inflammatory, anti-mutagenic, anti-tumour and anti-viral activities(Reference Nijveldt, van Nood and van Hoorn96), but further research is necessary to elucidate and quantify the contributions of phytochemicals to health promotion and disease prevention. In humans, evidence of the bioactivity and health effects attributable to the bioactive constituents in nuts is emerging, but remains largely unknown. A few human studies of the bioavailability of tree nut phytochemicals have been published, but observational and intervention studies targeted to health outcomes have only been undertaken with whole tree nuts. As most nut phytochemicals belong to classes for which bioactivity has been demonstrated in vitro, in animal models and human studies, it is reasonable to hypothesise that they contribute to the health benefits associated with the consumption of tree nuts. For example, after feeding 73 g almonds/d to hyperlipidaemic subjects, Jenkins et al. (Reference Jenkins, Kendall and Marchie97) attributed the reduction in biomarkers of oxidative stress to their phenolic antioxidant content as no increase in serum vitamin E was obtained with the intervention. While the MUFA and PUFA content of nuts certainly plays an important role in their beneficial impact on lipid profiles, it is possible that the effect of polyphenols on hepatic cholesterol absorption, TAG assembly and secretion, and the processing of lipoproteins in plasma may also contribute substantially to this health outcome(Reference Zern and Fernandez98). Nonetheless, the health benefits demonstrated following the consumption of whole nuts cannot be specifically attributed to any of their nutrient components, including their phytochemical composition. To date, no human studies have been designed to understand the direct effect of nut phytochemicals on health outcomes. However, clinical studies which examine separately the impact of nut components such as the skin, meat and oil, while incorporating appropriate control groups could provide important new information in this regard and should be undertaken.

Observational studies

Data from large observational studies consistently show that regular nut consumption lowers the risk for several conditions in which oxidative stress may play a role. Four major epidemiological studies, including the Nurses’ Health Study(Reference Hu, Stampfer and Manson99), the Physicians’ Health Study(Reference Albert, Gaziano and Willett100), the Iowa Women's Health Study(Reference Ellsworth, Kushi and Folsom101, Reference Kushi, Folsom and Prineas102) and the Adventist Health Study(Reference Fraser103Reference Fraser, Sumbureru and Pribis106), have all shown that frequent nut consumption is associated with a decreased risk of CHD events. Compared with individuals who ate nuts less than once per week, it was estimated that consuming a 1 oz (28 g) serving of nuts five or more times per week conferred a reduction in CHD risk of up to 50 %(Reference Fraser104, Reference Hu and Stampfer107, Reference Kris-Etherton, Zhao and Binkoski108).

Frequent nut intake has also been associated with a reduction in all-cause mortality. In the Iowa Women's Health Study(Reference Ellsworth, Kushi and Folsom101), the consumption of two or more 28·5 g servings per week was associated with a 12 % reduction in all-cause mortality compared with those who consumed <  one serving per month (95 % CI 0·77, 0·99; P trend = 0·047), while in the Adventist Health Study subjects who consumed nuts five times per week had an 18 % lower risk of death compared with those who consumed nuts less than one serving per week (95 % CI 0·70, 0·96; P < 0·01)(Reference Fraser and Shavlik105).

Nut consumption was also associated with a lower risk of developing hypertension in the Physicians’ Health Study I(Reference Djousse, Rudich and Gaziano109) and type 2 diabetes mellitus in the Nurses’ Health Study(Reference Jiang, Manson and Stampfer110). In this same cohort, a positive correlation with adiponectin(Reference Mantzoros, Williams and Manson111), a biomarker of cardioprotection, and an inverse correlation with CVD risk(Reference Li, Brennan and Wedick112) was observed among women with type 2 diabetes mellitus.

Evidence from the Multi-Ethnic Study of Atherosclerosis (MESA) suggests that frequent nut consumption is inversely correlated with biomarkers of inflammation and endothelial dysfunction, including C-reactive protein (CRP), IL-6, fibrinogen and soluble intercellular adhesion molecule-1 (sICAM-1)(Reference Jiang, Jacobs and Mayer-Davis113, Reference Nettleton, Steffen and Mayer-Davis114). Normal endothelial function is impaired by inflammatory cytokines and cell adhesion molecules, and, in prospective studies, these biomarkers have been shown to be independent predictors of CVD(Reference Danesh, Wheeler and Hirschfield115Reference Pai, Pischon and Ma117). More recently, Gopinath et al. (Reference Gopinath, Buyken and Flood118) reported a protective role of nuts against inflammatory disease mortality (primarily respiratory, nervous or digestive system diseases) in the Blue Mountains Eye Study cohort.

To date, no observational studies have directly correlated the intake of nuts with plasma total antioxidant activity or biomarkers of oxidative stress, as these measures are not routinely assessed in large cohorts. Similarly, no observational studies have correlated the intake of specific nut bioactive constituents with biomarkers of disease risk.

Clinical trials

Lipid-lowering effects

Most randomised clinical trials of nuts conducted thus far have focused on the hypocholesterolaemic effects of whole nuts, and not their individual constituents. In a systematic review of twenty-three intervention studies, Mukuddem-Petersen et al. (Reference Mukuddem-Petersen, Oosthuizen and Jerling119) reported the consumption of 50–100 g of almonds, groundnuts, pecans or walnuts five or more times per week, as part of a heart-healthy diet moderate in fat (about 35 % of energy), significantly lowered total cholesterol (2–16 %) and LDL-cholesterol (2–19 %) in both normo- and hyperlipidaemic individuals compared with control diets without nuts or with a different fatty acid profile. Similarly, in their review, Griel & Kris-Etherton(Reference Griel and Kris-Etherton120) concluded that tree nuts, i.e. walnuts, almonds, macadamias, pecans, pistachios and hazelnuts, reduced LDL-cholesterol 3–19 % when compared with Western and lower-fat diets. Subsequent trials of hazelnuts(Reference Mercanligil, Arslan and Alasalvar121, Reference Tey, Brown and Chisholm122), pistachios(Reference Sheridan, Cooper and Erario123), macadamia nuts(Reference Griel, Cao and Bagshaw124) and Brazil nuts(Reference Maranhao, Kraemer-Aguiar and Oliveira125) have also confirmed their hypocholesterolaemic effect.

In a pooled analysis of twenty-five nut intervention trials, Sabate et al. (Reference Sabate, Oda and Ros126) determined a mean intake of 67 g/d lowered total cholesterol 5 %, LDL-cholesterol 7 %, LDL:HDL 8 %, total cholesterol:HDL 6 % and TAG 10 % (among those with initial levels ≥  150 mg/dl (1500 mg/l) only). Their analysis also revealed that the lipid-lowering effect of nuts was dose-related and greatest among subjects with high LDL and low BMI, regardless of the type of nut consumed.

Nuts are rich in chemically related phytosterols, a class of compounds that interfere with intestinal cholesterol absorption which, according to Segura et al. (Reference Segura and Javierre127) might explain part of the cholesterol-lowering effect of nut intake beyond that attributable to fatty acid exchange. Given the evidence that polyphenols also lower cholesterol absorption(Reference Zern and Fernandez98), it is plausible that there are multiple mechanisms of action and/or potential synergistic effects between the individual nut constituents. However, no definitive studies have examined the extent of the contribution of polyphenols to the observed lipid-lowering effect.

Inflammation and endothelial function

A limited number of human studies have examined the effects of nuts on inflammation, endothelial function and vascular reactivity. In the Prevención con Dieta Mediterránea (PREDIMED) Study of 772 asymptomatic adults, aged 55–80 years, a Mediterranean diet including nuts (30 g/d) reduced levels of circulating IL-6 (P < 0·018), ICAM-1 (P < 0·003) and vascular cell adhesion molecule-1 (VCAM-1) from baseline after 3 months, but not CRP(Reference Estruch, Martínez-González and Corella128). Compared with a low-fat control diet, between-group differences in endothelial function were also observed, but no P values were reported. In this study, lowered fasting glucose (P = 0·039), insulin (P < 0·001), homeostatic model assessment (HOMA) index (P < 0·001), and systolic (P < 0·001) and diastolic blood pressure (P = 0·001) were also observed after 3 months with the nut diet when compared with the control diet.

A Mediterranean diet in which 32 % of the energy from MUFA fat was replaced with walnuts improved VCAM-1 status (P < 0·05), a circulating marker of endothelial activation, but had no effect on ICAM-1, CRP or homocysteine after 4 weeks when compared with a cholesterol-lowering Mediterranean diet(Reference Ros, Nunez and Perez-Heras129). Flow-mediated dilation, a measure of brachial artery vasomotor function and a biomarker of CHD risk, also improved significantly after both acute and chronic walnut feeding in twenty-four hypercholesterolaemic subjects from this cohort(Reference Ros, Nunez and Perez-Heras129, Reference Cortes, Nunez and Cofan130). A similar substitution with pistachios also improved endothelial function (P < 0·002) and lowered levels of IL-6 (P < 0·001), as well as fasting glucose (P < 0·001), with no change in either CRP or TNF-α after 4 weeks in a cohort of thirty-two healthy young men living in a controlled environment(Reference Sari, Baltaci and Bagci131).

Macadamia nuts, when incorporated into the diet at 15 % of energy (40–90 g/d), lowered plasma leucotriene B4 levels from baseline after 4 weeks in seventeen hypercholesterolaemic men(Reference Garg, Blake and Wills132). A non-significant reduction in the plasma thromboxane B2:prostacyclin I2 ratio was also observed following macadamia nut consumption.

Among healthy adults, incorporating almonds into the diet at 10 and 20 % of energy (34 and 68 g/2000 kcal (8368 kJ), respectively) for 4 weeks lowered CRP when compared with a nut-free control diet, although no dose–response relationship was observed. E-selectin was also significantly lower, but only with the higher almond dose(Reference Rajaram, Connell and Sabate133).

A controlled feeding trial incorporating walnuts as a source of α-linolenic acid (ALA) demonstrated the anti-inflammatory effects of an ALA-rich diet in hypercholesterolaemic subjects(Reference Zhao, Etherton and Martin134). In this study, a diet containing about 37 g walnuts/d and 15 g walnut oil/d reduced CRP (P < 0·01) and ICAM-1 (P < 0·01) when compared with an average American diet, while also lowering VCAM-1 (P < 0·01) and E-selectin (P < 0·01) when compared with a diet high in linoleic acid. This walnut diet also lowered levels of IL-6, IL-6β and TNF-α production by peripheral blood mononuclear cells (P < 0·05)(Reference Zhao, Etherton and Martin135). In contrast, a controlled feeding trial of walnuts and cashews showed no effect on serum CRP(Reference Mukuddem-Petersen, Stonehouse Oosthuizen and Jerling136) in sixty-four subjects with the metabolic syndrome. While the anti-inflammatory effects shown by Zhao et al. (Reference Zhao, Etherton and Martin134, Reference Zhao, Etherton and Martin135) were most probably due to the walnut fatty acids, neither feeding trial controlled for the presence of dietary antioxidants or phytochemicals, which alone can make an impact on these biomarkers.

Oxidative stress and antioxidant activity

In vitro assessment of the TAC of tree nuts, using the ORAC, FRAP, total peroxyl radical-trapping potential (TRAP) and Trolox equivalent antioxidant capacity (TEAC) assays, has been reported in the USDA Oxygen Radical Absorbance Capacity (ORAC) of Selected Foods(6), a FRAP database of over 3100 foods(Reference Carlsen, Halvorsen and Holte137) and in selected research reports. However, TAC data specifically on nut skins (pellicles), the location for most nut phytochemicals (except the phytosterols), are not generally available. As these assays are not particularly sensitive to tocopherols (present in the kernel or meat), much of the TAC value of nuts is probably derived from polyphenolic compounds in the skin. Importantly, TAC values correlate little or poorly with in vivo biomarkers of antioxidant status. However, TAC assays appear potentially useful in assessing antioxidant effects in food products, for example, to identify natural replacements for synthetic antioxidants such as butylated hydroxyanisole and butylated hydroxytoluene to promote shelf life and other applications for developing new applications in foods(Reference Mermelstein138).

The effects of nut consumption on antioxidant status and biomarkers of oxidative stress have been reported in a limited number of human intervention studies. Lopez- Uriarte et al. (Reference Lopez-Uriarte, Bullo and Casas-Agustench139) and Ros(Reference Ros140) reviewed a total of twenty-one clinical studies in which the potential effects of tree nuts on biomarkers of oxidation or antioxidant activity were evaluated.

As most of these studies used whole nuts, rather than nut components (such as the skins which contain much of the polyphenol content or the kernels where the tocopherols are found) or their individual phytochemical constituents, the contribution of these bioactive compounds to these results is unknown. However, when the reported outcomes of these nut studies are considered, it is clear that their effects cannot be due entirely to their MUFA or PUFA content alone.

Early intervention studies comparing a walnut-enriched, high-PUFA diet with a walnut-free, lower-PUFA diet showed no differences in the prevention of LDL oxidation(Reference Ros, Nunez and Perez-Heras129, Reference Iwamoto, Imaizumi and Sato141Reference Zambón, Sabaté and Muñoz143) or TAC(Reference Tapsell, Gillen and Patch144) between diets. While the shift to more PUFA in the diet and plasma with walnut consumption could be predicted to increase plasma biomarkers of lipid peroxidation, the absence of an effect may be due to the concurrent intake and bioavailability of walnut phytochemicals, including phenolic compounds and tocopherols. Davis et al. (Reference Davis, Stonehouse and Loots du145) reported no change in plasma antioxidant capacity following the consumption of 63–108 g walnuts or cashews/d for 8 weeks in metabolic syndrome patients. After 6 weeks, no significant changes in TAC (specifically, the ORAC, FRAP and total antioxidant parameter assays), antioxidant status (total plasma phenols, thiols and glutathione peroxidase) or lipid peroxidation (malondialdehyde) were observed with either 21 or 42 g walnuts/d in a randomised cross-over trial conducted in twenty-one generally healthy men and postmenopausal women aged ≥  50 years by McKay et al. (Reference McKay, Chen and Yeum146). Interestingly, a significant reduction in erythrocyte lipid peroxidation was observed in subjects at increased risk for CVD following a diet with 21·4 g walnuts/d for 5 weeks, when compared with a control diet(Reference Canales, Benedi and Nus147), but this effect was modulated according to each subject's particular paraoxonase (PON1) polymorphism(Reference Nus, Frances and Librelotto148).

According to Ros(Reference Ros140), the available evidence suggests that while PUFA-rich nuts confer a neutral or minimal effect on oxidative status, the effects of MUFA-rich nuts are more moderate. Indeed, Fito et al. (Reference Fito, Guxens and Corella149) reported a significant reduction in circulating oxidised LDL concentrations among asymptomatic adults, aged 55–80 years, 3 months after consuming a Mediterranean diet including 30 g whole nuts/d mixed at 50 % walnuts, 25 % almonds and 25 % hazelnuts. Moreover, other chronic feeding studies using low-PUFA nuts, including pecans(Reference Haddad, Jambazian and Karunia150), hazelnuts(Reference Durak, Koksal and Kacmaz151, Reference Yucesan, Orem and Kural152), macadamia nuts(Reference Garg, Blake and Wills132), pistachios(Reference Kocyigit, Koylu and Keles153), almonds(Reference Jalali-Khanabadi, Mozaffari-Khosravi and Parsaeyan154Reference Jenkins, Kendall and Marchie156) and Brazil nuts(Reference Stockler-Pinto, Mafra and Farage157, Reference Thomson, Chisholm and McLachlan158), all showed either an improvement in oxidation status or increased antioxidant enzyme activity. It is plausible that with lower PUFA intake, the need to protect this oxidisable substrate is reduced and a higher proportion of the nut bioactives are available for other functions.

Some studies have shown that the antioxidant effects of nuts are not limited to reduced lipid peroxidation and improved plasma antioxidant capacity. Jenkins et al. (Reference Jenkins, Kendall and Josse159) reported a significant postprandial increase in serum protein thiol concentrations, reflecting less oxidative damage to proteins, following a meal with 60 g almonds in a study of fifteen healthy young adults. Similarly, McKay et al. (Reference McKay, Chen and Yeum146) reported elevated plasma total thiols within 1 h of consuming either 21 or 42 g walnuts in a study of twenty-one healthy older adults. Lopez-Uriarte et al. (Reference Lopez-Uriarte, Nogues and Saez160) found a significant reduction in DNA damage, measured as urinary 8-oxo-7,8-dihydro-2′-deoxyguanosine, a biomarker of oxidatively modified nucleic acids, after 12 weeks with 30 g mixed nuts (15 g walnuts, 7·5 g almonds, 7·5 g hazelnuts) when compared with a nut-free diet in a study of fifty metabolic syndrome patients. Jia et al. (Reference Jia, Li and Zhang161) and Li et al. (Reference Li, Jia and Chen162) both reported significant reductions in oxidative DNA damage among smokers following 4 weeks of almond consumption at 84 g/d. Li et al. (Reference Li, Jia and Chen162) evaluated the effects of almonds v. pork (120 g/d) in a cohort of sixty male smokers serving in the Chinese army, and compared these effects with thirty non-smokers who consumed the control (pork) diet. After 4 weeks, the amount of DNA strand breaks and urinary 8-hydroxy-deoxyguanosine were significantly lower in the almond-supplemented smokers, compared with the pork-supplemented smokers. Significantly lower urinary malondialdehyde, a biomarker of lipid peroxidation, and higher serum α-tocopherol status and activities of superoxide dismutase and glutathione peroxidase were also observed in the almond group. No changes in these biomarkers of oxidative stress were observed in the pork-supplemented non-smokers. Although the authors did not measure the specific contribution of the nut polyphenols or antioxidants to these outcomes, this study does suggest that almonds confer an antioxidant benefit.

Bioavailability studies in humans

In a randomised, cross-over controlled-feeding trial of twenty-eight hypercholesterolaemic adults, Kay et al. (Reference Kay, Gebauer and West163) determined that the antioxidant nutrients present in pistachios were bioavailable and associated with decreases in oxidised LDL. After consuming a diet enriched with pistachios at either 10 or 20 % energy from fat for 4 weeks, plasma levels of lutein, α-carotene and β-carotene were significantly higher compared with baseline, while lutein and γ-tocopherol levels were higher compared with a lower-fat control diet. The increases in serum lutein and γ-tocopherol following the higher-pistachio diet were modestly associated with decreases in oxidised LDL (r − 0·36, P = 0·06 and r − 0·35, P = 0·08, respectively) after adjusting for the change in serum LDL-cholesterol.

The acute bioavailability of polyphenols from both walnuts and almonds, as well as a concomitant reduction in plasma lipid peroxidation and increased antioxidant capacity following their consumption, was demonstrated by Torabian et al. (Reference Torabian, Haddad and Rajaram164) in a randomised, placebo-controlled cross-over study of thirteen healthy adults. The total phenolic content of plasma significantly increased 30 min after consuming either 81 g walnuts or 91 g almonds (blended in water), while no changes were observed following an isoenergetic control meal. Peak phenolic concentrations coincided with a significant reduction at 90 min in plasma thiobarbituric acid-reactive substances, a measure of lipid peroxidation. Values from the FRAP and both lipophilic and hydrophilic ORAC assays also increased significantly following the consumption of both nut meals, with peak capacity observed at 150 min. No changes in plasma TAC were observed following the control meal.

The acute bioavailability of polyphenols from almond skins alone was determined in two studies by the same group. Urpi-Sarda et al. (Reference Urpi-Sarda, Garrido and Monagas47) conducted an initial pilot study in which two healthy adults were given a single dose of almond skin extract containing 884 mg total polyphenols. Plasma was collected for 4·5 h and urine for 24 h. Several derivatives of epicatechin and conjugated forms of naringenin and isorhamnetin were detected in plasma and urine samples following the consumption of almond skins, as were numerous microbial-derived metabolites of flavonols and hydroxyphenylvalerolactones. The urinary excretion of these microbial metabolites accounted for a larger proportion of the total polyphenol ingested than phase II metabolites of epicatechin, indicating the important role of intestinal bacteria in the metabolism of highly polymerised almond skin polyphenols. In a larger, placebo-controlled study by Bartolome et al. (Reference Bartolome, Monagas and Garrido165) twelve healthy adults were given a single dose of almond skin extract (884 mg total polyphenols) and compared with four adults given a control (450 mg cellulose). Concentrations of epicatechin sulfate and naringenin-O-glucuronide in the urine of subjects who consumed the almond skins were significantly higher at 2–6 h compared with the control subjects, while isorhamnetin sulfate was higher at 10–24 h, and 5-(hydroxymethoxyphenyl)-γ-valerolactone was higher at all time points between 2 and 24 h.

The results of these studies demonstrate that almond skin polyphenols are bioavailable in humans and appear as phase-II and microbial-derived metabolites in plasma and urine.

Summary

In addition to being a rich source of several essential vitamins and minerals, MUFA, PUFA and fibre, tree nuts provide a rich array of phytochemicals that may affect: (i) their cultivation, growth and appearance; (ii) tree nut characteristics during processing and storage; (iii) the promotion of human health; and (iv) their value as a by-product of tree nut processing such as blanching. Although many of these bioactive components remain to be fully identified and characterised in tree nuts, particularly their concentration and profiles as affected by genotype, environmental factors and geography, broad classes include the carotenoids, phenolic acids, phytosterols, and polyphenolic compounds such as flavonoids, PAC and stilbenes.

While the number of studies remains limited, available evidence indicates that these phytochemicals are bioaccessible and bioavailable in humans. These two parameters are important, as these phytochemicals have been associated with an array of bioactivities, including antioxidant, anti-inflammatory, anti-proliferative, antiviral, chemopreventive and hypocholesterolaemic actions potentially capable of affecting the initiation and progression of several pathogenic processes.

The present report provides a detailed and up-to-date summary and scientific review of the available data on tree nut phytochemicals. This information has been created and collected in disparate and inconsistent ways, making clear, comparative and comprehensive analysis and interpretation difficult. Nonetheless, the information about tree nut phytochemicals presented here can help to: (i) identify gaps in our knowledge about these compounds; (ii) prepare research strategies relevant to agricultural practices (for example, identifying phytoalexin and secondary metabolite properties in different nut genotypes) and human nutrition (for example, studying synergistic interactions among these compounds and between micronutrients in tree nuts and other foods); (iii) place these ingredients in a comparative context with established phytochemical intakes from fruit, vegetables, whole grains and other plant foods; and (iv) allow for consideration of these compounds as potentially valuable by-products of tree nut processing.

Acknowledgements

The present review was supported by the USDA Agricultural Research Service Cooperative Agreement no. 58-1950-7-707. The contents of the present publication do not necessarily reflect the views or policies of the USDA nor does mention of trade names, commercial products or organisations imply endorsement by the US government. Each author has declared to have no conflicts of interest. We thank Maureen Ternus, MS, RD and The International Tree Nut Council Nutrition Research & Education Foundation for their encouragement of our efforts on tree nut phytochemicals. The authors are grateful to Kerilyn Kimball, Jo Obelsky and Elizabeth Wallet for assistance in manuscript preparation.

B. W. B., C.-Y. O. C., D. L. M. and J. B. B. wrote or contributed to the writing of the manuscript.

The authors declare no conflict of interest.

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Figure 0

Fig. 1 Organisation of phytochemical classes.

Figure 1

Fig. 2 Major flavonoid classes and other representative phytochemicals present in tree nuts.

Figure 2

Table 1 Databases that include phytochemical or antioxidant content of foods

Figure 3

Table 2 Total phenols content of nine tree nuts reported in the US Department of Agriculture (USDA)(6) and Phenol-Explorer(16) databases

Figure 4

Table 3 Flavonoid content of tree nuts indexed in the 2007 US Department of Agriculture flavonoid database(8)

Figure 5

Table 4 Isoflavone content of tree nuts listed in the US Department of Agriculture database(7)

Figure 6

Table 5 Total proanthocyanidins (PAC) content of tree nuts reported in the US Department of Agriculture database(9)

Figure 7

Table 6 Polyphenols included in the Phenol-Explorer database(16)

Figure 8

Table 7 Phenol-Explorer concentration of flavonoids, phenolics, stilbenes and other phenols in nuts(16)

Figure 9

Table 8 Phenol-Explorer listed concentration of nut proanthocyanidins(16)

Figure 10

Table 9 Phytosterol content of tree nuts, according to US Department of Agriculture 2009 National Nutrient Database for Standard Reference, release 23(23)

Figure 11

Fig. 3 Polyphenol content of reference foods and tree nuts in the Phenol-Explorer database. (), Total phenols; (□), polyphenols by HPLC; (■), proanthocyanidins.

Figure 12

Table 10 Phytochemical content of tree nuts reported in the literature*

Figure 13

Table 11 Phytochemical content of tree nuts reported in the literature*

Figure 14

Fig. 4 Phytochemical database values for tree nuts relative to current literature (■) values for (a) total phenols, (b) flavonoids, (c) proanthocyanidins and (d) sterols. (), US Department of Agriculture; (□), Phenol-Explorer; GAE, gallic acid equivalents.

Figure 15

Table 12 Sterols, stanols and sterol esters quantified in tree nuts

Figure 16

Table 13 Polyphenol content, total phenols and ferric-reducing antioxidant power (FRAP) values of seven almond genotypes over 3 years(74)(Mean values and standard deviations)

Figure 17

Fig. 5 Canonical discriminant analysis of almond genotypes based on polyphenol content and antioxidant activity(32). M, Mission; F, Fritz; B, Butte; C, Carmel; N, Nonpareil; Mo, Monterey; S, Sonora; Can 1, first canonical variable; Can 2, second canonical variable. Data represent the first two canonical variables of almond samples by genotype with 80 % confidence ellipses.

Figure 18

Table 14 Genotype effect on sterol contents in walnuts(85)

Figure 19

Table 15 Effect of harvest season on polyphenol content and antioxidant activity of Butte, Carmel and Nonpareil almonds(32)(Mean values and standard deviations, n 9)

Figure 20

Table 16 Geographic effect on anthocyanins, chlorophylls and xanthophylls in pistachios(87)

Figure 21

Table 17 Effect of pasteurisation and roasting on almond skin flavonoids and phenolic acids, total phenols and ferric-reducing antioxidant power (FRAP) values(89)(Mean values and standard deviations)

Figure 22

Fig. 6 Storage of raw almonds in darkness at 4°C (-Δ-) and 23°C (-□-) for 15 months increased flavonoids and phenolic acids determined by liquid chromatography–MS (a), total phenols (b) and ferric-reducing antioxidant power (FRAP) (c) of almond skins(89). Values are means (n 13), with standard errors represented by vertical bars, representing seven almond varieties. * Mean value was significantly different from that at 4°C (P ≤ 0·05).

Figure 23

Fig. 7 (a) Changes to flavonoid aglycone and phenolic acid content in almond skins upon storage at 23°C for 15 months(89). (), p-Hydroxybenzoic acid; (), dihydroxykaempferol; (), kaempferol; (), eriodictyol; (), catechin; (), epicatechin; (), procatechuic acid; (), isorhamnetin; (), quercetin; (), naringenin. (b) Changes to flavonoid glycoside content in almond skins upon storage at 23°C for 15 months(89). (), Quercetin-3-O-galactoside; (), isorhamnetin-3-O-glucoside; (), kaempferol-3-O-glucoside; (), isorhamnetin-3-O-rutinoside; (), naringenin-7-O-glucoside; (), kaempferol-3-O-rutinoside; (), kaempferol-3-O-galactoside; (), quercetin-3-O-rutinoside.

Figure 24

Table 18 Effect of shelling on contents (μg/100 g DM) of selected carotenoids and tocopherols in cashew nut kernels(90)

Figure 25

Table 19 Content of phenolics (mg/100 g DM) in edible pistachio kernels of Bronte Pistacia vera(40)

Figure 26

Table 20 The effect of roasting on total phenols, total antioxidant capacity (TAC) and flavonoids in edible kernels of pistachios(43)

Figure 27

Table 21 Effect of bleaching and roasting on anthocyanins and total antioxidant capacity values in pistachio skins(42)

Figure 28

Fig. 8 Typical liquid chromatography − MS/MS extracted ion chromatograms of almond skin polyphenolics from (a) acidified methanol extraction and (b) gastrointestinal juice mimic extraction(94). Peak numbers correspond to compounds as (1) catechin, (2) epicatechin, (3) quercetin-3-O-galactoside, (4) naringein-7-O-glucoside, (5) rutin, (6) quercetin-3-O-glucoside, (7) dihydroxylkaempferol, (8) kaempfer-3-O-galactoside, (9) kaempferol-3-O-glucoside, (10) kaempferol-3-O-rutinoside, (11) isorhamnetin-3-O-runtinoside, (12) eriodictyol, (13) quercetin, (14) naringenin and (15) isorhamnetin.

Figure 29

Table 22 Total phenols, condensed tannins and total antioxidant capacity measured by Trolox equivalent antioxidant capacity (TEAC) in 1 g dry extracts of hazelnuts(53)

Figure 30

Table 23 Oil yields of seven tree nuts extracted with hexane or chloroform–methanol(70)

Figure 31

Table 24 Yields of sphingolipids and sterols extracted by hexane or chloroform–methanol (CM) in seven tree nuts(70)(Mean values)

Figure 32

Table 25 Summary of the effect of pre- and post-harvesting factors on phytochemical content in nine tree nuts