Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-21T19:28:23.445Z Has data issue: false hasContentIssue false

Novel plant-based meat alternatives: future opportunities and health considerations

Published online by Cambridge University Press:  06 January 2023

Megan Flint*
Affiliation:
Food and Nutrition Subject Group, Sheffield Hallam University, Sheffield S1 1WB, UK
Simon Bowles
Affiliation:
Food and Nutrition Subject Group, Sheffield Hallam University, Sheffield S1 1WB, UK
Anthony Lynn
Affiliation:
Food and Nutrition Subject Group, Sheffield Hallam University, Sheffield S1 1WB, UK
Jenny R. Paxman
Affiliation:
Food and Nutrition Subject Group, Sheffield Hallam University, Sheffield S1 1WB, UK
*
*Corresponding author: Megan Flint, email m.flint@shu.ac.uk
Rights & Permissions [Opens in a new window]

Abstract

Present food systems threaten population and environmental health. Evidence suggests reduced meat and increased plant-based food consumption would align with climate change and health promotion priorities. Accelerating this transition requires greater understanding of determinants of plant-based food choice. A thriving plant-based food industry has emerged to meet consumer demand and support dietary shift towards plant-based eating. ‘Traditional’ plant-based diets are low-energy density, nutrient dense, low in saturated fat and purportedly associated with health benefits. However, fast-paced contemporary lifestyles continue to fuel growing demand for meat-mimicking plant-based convenience foods which are typically ultra-processed. Processing can improve product safety and palatability and enable fortification and enrichment. However, deleterious health consequences have been associated with ultra-processing, though there is a paucity of equivocal evidence regarding the health value of novel plant-based meat alternatives (PBMAs) and their capacity to replicate the nutritional profile of meat-equivalents. Thus, despite the health halo often associated with plant-based eating, there is a strong rationale to improve consumer literacy of PBMAs. Understanding the impact of extensive processing on health effects may help to justify the use of innovative methods designed to maintain health benefits associated with particular foods and ingredients. Furthering knowledge regarding the nutritional value of novel PBMAs will increase consumer awareness and thus support informed choice. Finally, knowledge of factors influencing engagement of target consumer subgroups with such products may facilitate production of desirable, healthier PBMAs. Such evidence-based food manufacturing practice has the potential to positively influence future individual and planetary health.

Type
Conference on ‘Food and nutrition: Pathways to a sustainable future’
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Context

Food systems have the potential to promote both human and planetary health but currently pose a significant threat to both(Reference Bryant, Szejda and Parekh1,2) . Global population, expected to reach approximately 10 billion by 2050, longer life expectancy, increased income and urbanisation will increase demand on global resources(Reference García-Oliveira, Fraga-Corral and Pereira3Reference Willett, Rockström and Loken6). The projected increase in demand for food (50 %) and animal-derived food (70 %) will add substantial pressure to an already failing food system while animal husbandry, it is argued, also has an overall negative impact on environmental sustainability(Reference Choudhury, Singh and Seah7,Reference Gastaldello, Giampieri and De Giuseppe8) . Some estimates suggest food production is already responsible for approximately one-third of anthropogenic greenhouse gas emissions(Reference Culliford and Bradbury9Reference Gibbs and Cappuccio12). Meat and dairy also require more land and water use than foods of plant-based origin, potentially furthering deforestation and biodiversity loss(Reference Fiorentini, Kinchla and Nolden13Reference Szenderák, Fróna and Rákos16). Although historically considered an essential dietary component, providing vitamin B12, iron and calcium, overconsumption of meat, particularly processed meat, has been associated with certain deleterious health consequences(Reference Rust, Ridding and Ward17Reference Farsi, Uthumange and Munoz Munoz19).

International recognition of this challenge has led to global strategies to accelerate transition towards a healthier, more sustainable food system(Reference Sridhar, Bouhallab and Croguennec5,Reference Malek and Umberger20) . These include the UN Sustainable Development Goals and the Paris Agreement of Climate Change(Reference García-Oliveira, Fraga-Corral and Pereira3,Reference Willett, Rockström and Loken6) . However, the complexity and multi-faceted nature of this problem emphasises the need for strong multi-sectoral partnerships(Reference MacDiarmid21Reference Anderson, Thorndike and Lichtenstein23). Extensive evidence suggests that reduced meat and increased plant-based food consumption would align with both climate change and health promotion strategies(Reference Willett, Rockström and Loken6,Reference Rust, Ridding and Ward17,Reference Graça, Oliveira and Calheiros24Reference Kwasny, Dobernig and Riefler26) .

Present animal-based protein consumption is unsustainably high(Reference Wellesley, Happer and Froggatt27). In 2021, global meat consumption was estimated to be 328 million metric tonnes and is expected to increase approximately 70 % by 2050(Reference Choudhury, Singh and Seah7,Reference Gastaldello, Giampieri and De Giuseppe8,28,29) . High intake of red and processed meat have been associated with increased risk of non-communicable diseases including type 2 diabetes, colorectal cancer and reduced life expectancy(Reference Richi, Baumer and Conrad30Reference González, Marquès and Nadal34). Indeed, the WHO classifies red meat as a group 2A carcinogen (likely cause of cancer) and processed meats as a group 1 carcinogen (known cause of cancer)(Reference Bouvard, Loomis and Guyton35), with the World Cancer Research Fund recommending restriction of red meat consumption to three or less portions weekly and avoidance or restriction of processed meat(36). However, guidance does not support the total elimination of meat as a key source of energy and nutrition(Reference Tso and Forde18,Reference MacDiarmid21) . Against this backdrop, however the WHO has endorsed animal-derived foods for high-quality nutrition in children aged 6–23 months(37) and Adesogan et al.(Reference Adesogan, Havelaar and McKune38) challenge the notion that one-size-fits all. In many developing countries animal-sourced protein consumption is limited and nutrient intake often suboptimal, reinforcing the need to tailor recommendations to different regions to prevent exacerbating present public health challenges. Additional benefits also warrant careful consideration: the livestock sector provides increased food and nutrition security, a living income for many, and contributes to national revenue, particularly in more deprived populations(Reference Szenderák, Fróna and Rákos16,Reference Adesogan, Havelaar and McKune38,Reference Jairath, Mal and Gopinath39) . Nonetheless, estimates suggest that to sustainably feed 10 billion people, a significant reduction in meat consumption of about 50–75 %, accompanied by increased consumption of plant-based foods (see Table 1) is required(Reference Willett, Rockström and Loken6,Reference Gastaldello, Giampieri and De Giuseppe8,Reference Hartmann and Siegrist40) . It is noted that replacing 3 % of daily energy intake derived from processed red meat with plant-derived sources could reduce risk of all-cause mortality by 12 %(Reference Song, Fung and Hu41). Furthermore, substituting 1 kg of beef-derived protein with kidney bean sources could offer an 18-fold reduction in land use(Reference Sabaté, Sranacharoenpong and Harwatt42). Heterogeneity in modelling methods used to estimate the required intake of plant-derived proteins remains however(Reference Willett, Rockström and Loken6,Reference Lonnie and Johnstone43Reference Reynolds, Horgan and Whybrow46) . While EAT-Lancet(Reference Willett, Rockström and Loken6) recommend a daily intake of 25 g soyabeans plus 50 g of beans, lentils and peas, other suggested increases in legumes, beans, pulses, nuts and oil seeds vary between 26 and 30 g daily(Reference Scarborough, Kaur and Cobiac4547).

Table 1. Definitions of key terminology referred to in the present review

Currently, 21 % of the UK population identify as flexitarian (12⋅5 % as meat-free) and 39 % report reducing meat intake, while consumption of plant-based products between 2008–2011 and 2017–2019 doubled(Reference Alae-Carew, Green and Stewart48,Reference Alcorta, Porta and Tárrega49) . Globally, 40 % report reducing meat intake while 10 % avoid red meat although these changes may have been accelerated by the recent Covid-19 global pandemic(Reference Alcorta, Porta and Tárrega49,Reference Attwood and Hajat50) . Increased consumer awareness of zoonosis, coupled with the food chain disruption during the pandemic may have facilitated a dietary shift to reduce meat consumption(Reference Attwood and Hajat50). However, to achieve the UK climate change commitments, an additional 20 % reduction in high carbon meat and dairy would be required over the next decade(Reference Alae-Carew, Green and Stewart48). Novel plant-based meat alternatives (PBMAs; see Table 1) designed to replicate the preparation methods, organoleptic and nutritional qualities of meat-based equivalents, may offer a viable avenue to help facilitate the required dietary shift(Reference Choudhury, Singh and Seah7,Reference Gastaldello, Giampieri and De Giuseppe8,Reference Bakhsh, Lee and Lee11,Reference MacDiarmid21,Reference Boukid51,Reference Bryant52) . This gradual shift towards reduced meat consumption and increased engagement with plant-based foods has resulted in a reportedly thriving plant-based food industry(Reference Alae-Carew, Green and Stewart48). However, accelerating this transition requires a greater understanding of the factors influencing plant-based food choice. It should be noted that there is a lack of consensus regarding a universal definition for numerous terminologies in the present review. For clarity, the present review will use the definitions outlined in Table 1.

Traditional plant-based diets v. consumption of novel plant-based meat alternatives

Consumer enthusiasm to adopt healthier, more sustainable diets has led to an increase in plant-based dietary patterns such as vegetarianism, veganism and flexitarianism(Reference Alcorta, Porta and Tárrega49,Reference Boukid51) . ‘Traditional’ plant-based diets are frequently characterised as low-energy density, nutrient dense, low in saturated fat and associated with a range of health benefits including healthier BMI and protection against CVD(Reference Harland and Garton53Reference Naghshi, Sadeghi and Willett55). A large body of evidence also recognises the role of plant-based dietary patterns in reducing risk of all-cause mortality(Reference Naghshi, Sadeghi and Willett55Reference Kim, Caulfield and Rebholz58). Naghshi et al.(Reference Naghshi, Sadeghi and Willett55) reviewed thirty-two prospective cohort studies and reported plant-based protein consumption was significantly associated with reduced risk of all-cause mortality and CVD mortality. Furthermore, a 3 % increase in energy derived from plant proteins was associated with a 5 % reduced risk of all-cause mortality(Reference Naghshi, Sadeghi and Willett55). While the authors reported no association between plant-based protein consumption and cancer mortality, other studies have inferred that ‘traditional’ plant-based diets may protect against cancer and mortality(Reference Dinu, Abbate and Gensini56,Reference Tantamango-Bartley, Jaceldo-Siegl and Fan59Reference Segovia-Siapco and Sabaté61) .

Extensive epidemiological evidence also supports the adoption of ‘traditional’ plant-based diets to facilitate weight management(Reference Huang, Huang and Hu62Reference Turner-McGrievy, Davidson and Wingard64). For example, Tran et al.(Reference Tran, Dale and Jensen65) systematically reviewed twenty-two studies, eight of which demonstrated significantly reduced body weight and/or BMI. While most studies applied the gold-standard randomised controlled trial (RCT) study design, heterogeneity in methodology, such as restrictions on dietary fat intake, limited generalisability. Furthermore, some studies failed to consider confounding factors such as physical activity, limiting the internal validity. A more recent study, which did not emphasise restricted energy intake, involved a 6 month five-arm RCT(Reference Turner-McGrievy, Davidson and Wingard64). Participants were randomly assigned to a low fat, low glycaemic index; vegan (n 12), vegetarian (n 13), semi-vegetarian (n 13), pesco-vegetarian (n 13) or omnivorous (control, n 12) group dietary pattern. All intervention group participants attended dietitian-led group meetings for 6 months. While significant weight reduction was demonstrated across all dietary groups at 6 months, the vegan dietary group demonstrated significantly greater weight loss [−7⋅5(sem 4⋅5)%] compared to the semi-vegetarian [−3⋅2(sem 3⋅8)%], pesco-vegetarian [−3⋅2(sem 3⋅4)%] and omnivorous groups [3⋅1(sem 3⋅6)%]. However, it should be noted that no significant difference was reported between the vegan and vegetarian dietary groups.

Although present evidence demonstrates health benefits linked to ‘traditional’ plant-based consumption, much of the literature base relies on large-scale, historic, observational studies in restricted populations thus increasing risk of inherent methodological bias(Reference Spencer, Appleby and Davey66Reference Orlich, Singh and Sabaté71). For example, Kwok et al.'s(Reference Kwok, Umar and Myint69) systematic review and meta-analysis identified the positive impact of a vegetarian diet on risk of CVD mortality based on studies of Seventh Day Adventist communities. However, it should be noted that the healthy lifestyles behaviours associated with this population typically includes regular physical activity and abstinence from alcohol and tobacco. Thus, the influence of potential confounding variables on cardiovascular outcomes limits the generalisability of findings to the wider population.

The fast-paced nature of contemporary lifestyles has increased demand for convenience foods, as opposed to adoption of ‘traditional’ plant-based diets, leading to a rapid expansion of PBMAs designed to mimic sensory attributes of meat(Reference Weinrich72,73) . Unlike ‘traditional’ whole-plant foods, PBMAs undergo considerable processing to effectively deliver tasty, convenient substitutes for meat and meat-products(Reference Bryant52,Reference Michel, Hartmann and Siegrist74,Reference Elzerman, Hoek and van Boekel75) . Such novel products may be deemed inferior to minimally processed, ‘traditional’ plant-based foods with regards to impact on sustainability and health(Reference Tso and Forde18,Reference MacDiarmid21,Reference Bryant52,Reference Hoek, Luning and Weijzen76Reference van Vliet, Kronberg and Provenza79) . However, PBMAs are not designed to replace whole-plant foods but instead to offer a steppingstone in the transition away from meat to increased plant consumption(Reference Gastaldello, Giampieri and De Giuseppe8,Reference MacDiarmid21,Reference Bryant52) . For example, meat-eaters are more likely to replace a beef burger with a plant-based equivalent as this substitute does not require substantial dietary change. Thus future investigations focusing on the perceived benefits of plant-based meat v. meat-based equivalent products are warranted in order to understand consumer demand.

Consumer perceptions influencing plant-based food choice

There are a wide range of complex interacting factors that influence an individual's food-related behaviours(Reference Onwezen, Bouwman and Reinders80,Reference Szejda, Urbanovich and Wilks81) . Taste, cost and convenience have all been reported as primary drivers underpinning general and plant-based food choice(Reference Bryant52,Reference Szejda, Urbanovich and Wilks81) . Increased awareness of animal welfare, environmental sustainability and individual health has increased demand for plant-based foods more aligned with aspirational factors(Reference McClements and Grossmann14,Reference Singh, Trivedi and Enamala15,Reference Tso and Forde18,Reference Bryant52) (Fig. 1).

Fig. 1. Key factors influencing individual plant-based food choice adapted from Szejda and Parry(Reference Szejda and Parry188).

Primary drivers

Cost

The perceived high cost of PBMAs presents a barrier to consumer engagement(Reference Michel, Hartmann and Siegrist74,Reference Knaapila, Michel and Jouppila82Reference Apostolidis and Mcleay84) . Numerous cross-sectional surveys have reported affordability as a significant determinant of present and future engagement with PBMAs(Reference Bryant, Szejda and Parekh1,Reference Szenderák, Fróna and Rákos16,Reference Szejda, Urbanovich and Wilks81,Reference Knaapila, Michel and Jouppila82,Reference Clark and Bogdan85) . Clark and Bogdan(Reference Clark and Bogdan85) reported that Canadians considered cost more important than availability and convenience (47 , 39  and 34 %, respectively) and a recent European survey(Reference Broeckhoven, Verbeke and Tur-Cardona86) highlighted a reluctance to pay for plant-based burgers amongst older adults. Sociodemographic factors and annual income of respondents may confound survey responses(Reference Szenderák, Fróna and Rákos16,Reference Collier, Oberrauter and Normann87) with cost recognised as a salient product attribute amongst low-income groups and those with lower education outcomes and engagement with PBMAs reportedly being higher amongst individuals with higher socioeconomic status(Reference Hoek, Luning and Weijzen76,Reference Clark and Bogdan85) . Consumer segment may also influence response: meat consumers cited cost of Quorn as a negative attribute while vegetarians were reportedly more ambivalent(Reference Apostolidis and Mcleay84). While the interrelationship between dietary pattern and sociodemographic characteristics warrants further investigation it is clear that affordability of novel PBMAs is a key consideration when it comes to their adoption across a range of consumer segments(Reference Michel, Hartmann and Siegrist74,Reference Szejda, Urbanovich and Wilks81,Reference Knaapila, Michel and Jouppila82,Reference Allès, Baudry and Méjean88Reference Bedford and Barr91) .

Convenience

Convenience, and its perceived influence on self-efficacy, may also restrict engagement with plant-based foods(Reference Michel, Hartmann and Siegrist74,Reference Szejda, Urbanovich and Wilks81,Reference Tobler, Visschers and Siegrist92) . A Dutch focus group study identified that the preparation time for a desirable meal with PBMAs was perceived to be significantly greater than that needed for an equivalent meat-based meal(Reference Elzerman, van Boekel and Luning93). This is supported by a Finnish survey where one-third of individuals perceived the preparation of plant-based meals to be more challenging compared to meat-based equivalents(Reference Pohjolainen, Vinnari and Jokinen94). The availability of PBMAs in UK supermarkets is also highlighted as a barrier to engagement(Reference Apostolidis and Mcleay84) though the degree of importance of convenience varies across consumer segments with flexitarians valuing convenience more than meat-avoiders(Reference Malek and Umberger20,Reference Szejda, Urbanovich and Wilks81,Reference Apostolidis and Mcleay84) . Demographic factors may be important confounders here since meat-eaters and flexitarians are more likely found in households with children, thus value time-convenience more, compared to meat-avoiders(Reference Allès, Baudry and Méjean88,Reference Webster, Greenwood and Cade95,Reference Gehring, Touvier and Baudry96) . Developing and marketing widely available PBMAs that are easy to cook and contextually appropriate substitutes to meat may accelerate adoption of plant-based dietary patterns.

Taste

Novel PBMAs differ from the early generation PBMAs, such as soya and tofu, in that they mimic sensory attributes of meat(Reference Jahn, Furchheim and Strässner31,73) . Bryant(Reference Bryant52) reported that PBMAs that successfully replicated the taste and texture of processed meat have the greatest potential to replace meat-based equivalent products. Several studies have emphasised that desirable sensorial qualities, including taste, texture, appearance and smell are crucial to achieving consumer acceptance and engagement(Reference Graça, Oliveira and Calheiros24,Reference Jahn, Furchheim and Strässner31,Reference Alcorta, Porta and Tárrega49,Reference Szejda, Urbanovich and Wilks81,Reference Apostolidis and Mcleay84,Reference Gonera, Svanes and Bugge97,Reference Beacom, Bogue and Repar98) . In total, 86 % of US adults cited taste as a driver of purchase intent ahead of price (68 %)(99). This supports the results of a recent Norwegian study(Reference Gonera, Svanes and Bugge97) which reported 78 % of consumers considered taste the most salient determinant of food purchase. However, reproducing desirable meat characteristics poses a significant challenge. For example, the higher lipid content in meat-based equivalents adds taste and texture that is limited in PBMAs making them less juicy(Reference Gastaldello, Giampieri and De Giuseppe8,Reference Fiorentini, Kinchla and Nolden13,Reference Alcorta, Porta and Tárrega49,Reference Schouteten, De Steur and De Pelsmaeker100) . Furthermore, legumes as a replacement protein source may negatively impact the flavour(Reference Fiorentini, Kinchla and Nolden13,Reference Boukid51) . Thus, taste can simultaneously also be considered as a barrier(Reference Michel, Hartmann and Siegrist74,Reference Circus and Robison83,Reference Apostolidis and Mcleay84,Reference Hielkema and Lund101) .

Several studies cite lack of familiarity(Reference Hartmann and Siegrist40,Reference Beacom, Bogue and Repar98) and food neophobia (an individual's unwillingness to try novel foods) as playing a crucial role in the acceptance of PBMAs(Reference Knaapila, Michel and Jouppila82). Regular consumers of PBMAs score significantly lower in the Food Neophobia Scale compared to non-users and occasional users(Reference Hoek, Luning and Weijzen76). Hence, novel products resembling familiar meat-based foods may mitigate against neophobia(Reference Jahn, Furchheim and Strässner31). However, increased processing to mimic meat results in foods that are further removed from the perceived ‘natural state’(Reference Circus and Robison83,Reference Aschemann-Witzel, Varela and Peschel102) . While there is no universal definition of what comprises a ‘clean label’ product it typically refers to consumer desire for foods that have undergone minimal processing, using familiar ingredients and excluding ‘additives’(Reference Aschemann-Witzel, Varela and Peschel102Reference Asioli, Aschemann-Witzel and Caputo104). In contrast, novelty may also be a potential motivator in people who are curious to try new foods(Reference Onwezen, Bouwman and Reinders80).

The influence of hedonic characteristics of pleasure elicited in response to perceived sensory characteristics may also pose a barrier to the adoption of PBMAs(Reference Jahn, Furchheim and Strässner31,Reference Hoek, Luning and Weijzen76) . Michel et al.(Reference Michel, Hartmann and Siegrist74) reported consumer associations between meat and ‘delicious’ in contrast to PBMA and ‘disgust’. Although consumer perceptions offer valuable insights, they are self-reported and are not direct comparisons of consumer acceptance. Thus, it has been suggested that consumers may react differently to a novel product which they can actually taste/smell before purchasing(Reference Slade105). Slade(Reference Slade105) conducted a hypothetical choice experiment where participants indicated their willingness to purchase a range of burger products. Despite being informed that all burgers tasted the same, 65 % of respondents indicated they would purchase the beef burger in contrast to the plant-based burger and cultured meat burger (21 and 11 %, respectively) with 4 % stating they would purchase neither option. However, the hypothetical nature of the study design restricts findings to perceived taste not actual taste. Hedonic tests would generate a more reliable indication of actual sensorial acceptance v. perceived acceptance(Reference Hartmann and Siegrist40). Schouteten et al.(Reference Schouteten, De Steur and De Pelsmaeker100) conducted a sensory analysis experiment under blind, expected and informed conditions. The study again reported stronger preference for the meat burger v. the plant-based burger under all conditions and across both consumers and non-consumers. Participants attributed negative sensorial qualities, including a lack of juiciness, dryness and off flavouring, to the plant-based burger compared to the meat-based equivalent. Another sensory evaluation reported similar findings, highlighting the inability of plant-based nuggets to replicate their meat-based equivalent and critiquing the off-flavours of plant-based nuggets that included a beany aftertaste(Reference Ettinger, Falkeisen and Knowles106).

Sustained adoption of PBMAs is also influenced by taste(Reference Bryant, Szejda and Parekh1,Reference Szenderák, Fróna and Rákos16,Reference Knaapila, Michel and Jouppila82) . In total, 42 % of North Americans cited perceived taste as the reason for not trying to increase purchase of protein alternatives in a recent Mintel report(Reference Clark and Bogdan85). In addition, Collier et al.(Reference Collier, Oberrauter and Normann87) highlighted focus group participants' disappointment in PBMAs’ ability to replicate the taste of meat. In fact, missing the taste of meat has been cited as the most common factor, after health, for returning to a meat-based diet(Reference Barr and Chapman107). High meat attachment and high levels of food neophobia have been noted as significant barriers to adopting PBMAs(Reference Bryant, Szejda and Parekh1,Reference Jahn, Furchheim and Strässner31) . Meat attachment may also be associated with an emotional response to meat abstinence, strong enough to overcome the reported negative health impact of meat(Reference Hoek, Pearson and James108). Additionally, the influence of the taste of plant-based foods as a barrier to adoption varies across different consumer segments with males more likely to reject plant-based foods as not being tasty(Reference Pohjolainen, Vinnari and Jokinen94) and approximately twice the number of women citing taste as a driver of regular PBMA consumption(Reference Knaapila, Michel and Jouppila82). Of interest is the finding that while omnivore/flexitarian subgroups demand products mimicking sensory properties of meat, vegan and vegetarians are more likely to accept non-meat mimicking substitutes(Reference Alcorta, Porta and Tárrega49,Reference Hoek, Luning and Weijzen76) .

Aspirational drivers

While primary drivers of cost, taste and convenience are important, animal welfare, environmental impact and health have a significant influence on food choice(Reference Szejda, Urbanovich and Wilks81).

Animal welfare

Animal welfare has long been a driver of meat-avoidance though concerns regarding differing global meat rearing standards and live animal transportation issues continue to influence the gradual reduction in meat consumption in both the UK and worldwide(Reference Kwasny, Dobernig and Riefler26,Reference Ishaq, Irfan and Sameen32,Reference He, Evans and Liu109) . The reported degree of its relative importance as a driver of both meat-avoidance and adoption of PBMAs varies however, with some studies suggesting it to be a key factor (amongst about 45–65 % of respondents)(Reference Knaapila, Michel and Jouppila82,Reference Circus and Robison83,Reference Estell, Hughes and Grafenauer110) and others suggesting it is of lower importance(Reference Szejda, Urbanovich and Wilks81,Reference Wyker and Davison111,Reference Neff, Edwards and Palmer112) . Neff et al.(Reference Neff, Edwards and Palmer112) found as few as 12 % of respondents in the USA cited animal welfare as the reason for reduced meat consumption in contrast to other factors such as cost and health. Inconsistency in findings may be the result of variation across consumer subgroups(Reference Michel, Hartmann and Siegrist74,Reference Hoek, Luning and Weijzen76) , with rural consumers less influenced than urban consumers(Reference Beacom, Bogue and Repar98), and personal experience of animal husbandry or limited access to large supermarkets also influencing this phenomenon(Reference Clark and Bogdan85,Reference Beacom, Bogue and Repar98) . Vegetarian and vegan consumers also tend to place greater value on the welfare of animals(Reference Kahleova, Levin and Barnard54,Reference Kim, Caulfield and Rebholz58,Reference Barnard, Levin and Yokoyama63,Reference Boonpor, Petermann-Rocha and Parra-Soto89Reference Tobler, Visschers and Siegrist92) .

Environment

Estimates of the extent to which environmental awareness influences the popularity of and engagement with plant-based food varies(Reference Alae-Carew, Green and Stewart48,Reference Onwezen, Bouwman and Reinders80,Reference Szejda, Urbanovich and Wilks81,Reference Slade105,Reference Sucapane, Roux and Sobol113) . A recent cross-sectional survey(Reference Knaapila, Michel and Jouppila82) found over 80 % of respondents cited environmental reasons as the primary driver behind regular PBMA consumption. In contrast, Circus and Robison(Reference Circus and Robison83) reported only 21⋅6 % of respondents reduced meat for environmental reasons. In addition, a recent food standards agency survey(114) reported 36 % of respondents were willing to try plant-based proteins for sustainability reasons compared to health (39 %) and safety (44 %). This supports the findings which suggest that personal health has a greater influence on the adoption of plant-based eating compared to environmental sustainability amongst omnivores and semi-vegetarians (32⋅9 and 20⋅3 %, respectively)(Reference Mullee, Vermeire and Vanaelst115). Thus, personal health gains may outweigh altruistic factors when it comes to reducing meat and consuming more plant-based foods.

Historically low levels of public awareness of the environmental impact of meat consumption may partially explain the so far limited dietary shift towards plant-based(Reference Jahn, Furchheim and Strässner31,Reference Hartmann and Siegrist40,Reference Tobler, Visschers and Siegrist92,Reference Hielkema and Lund101) . Macdiarmid et al.(Reference Macdiarmid, Douglas and Campbell116) highlighted a substantial lack of awareness in focus groups regarding the impact of meat consumption upon climate change and a mutual perception that personal consumption was negligible in addressing environmental sustainability. However, socioeconomic status has been shown to influence awareness(Reference Culliford and Bradbury9,Reference Clark and Bogdan85) and, more recently following publication of EAT-Lancet and media coverage of the issue, awareness has been heightened(Reference Bryant, Szejda and Parekh1,Reference Willett, Rockström and Loken6) . Estell et al.(Reference Estell, Hughes and Grafenauer110) reported over 80 % of survey respondents agreed that following a plant-based diet is environmentally friendly. Despite increased awareness however, only a small minority of consumers are willing to change meat consumption behaviour(Reference Alcorta, Porta and Tárrega49,Reference Sanchez-Sabate and Sabaté117,Reference Perez-Cueto118) . Demographic characteristics of study respondents predict consumer behaviour(Reference Hartmann and Siegrist40,Reference Hoek, Pearson and James108) with age and sex noted to influence both degree of awareness and importance of environmental impact of meat consumption, appearing to be greatest amongst younger adults, Millennials and females compared to older adults and males(Reference Culliford and Bradbury9,Reference Hartmann and Siegrist40,Reference Michel, Hartmann and Siegrist74,Reference Knaapila, Michel and Jouppila82,Reference De Backer and Hudders119) .

While it appears altruistic drivers of animal and environmental welfare are important to consumers, they are consistently identified as secondary to health(Reference Malek and Umberger20,Reference Hartmann and Siegrist40,Reference Gonera, Svanes and Bugge97,Reference Slade105,Reference Hoek, Pearson and James108,Reference De Backer and Hudders119Reference Mann, Thornton and Crawford122) . Parry and Mitchell(Reference Parry and Mitchell123) highlight that perceived importance of altruistic factors was at least 20 % lower than other attributes including taste and health when purchasing plant-based products (see Table 1). Furthermore, concern for the environment (12 %) and animal welfare (12 %) was substantially lower than health (50 %) as a driver for reduced meat consumption(Reference Neff, Edwards and Palmer112). This emphasises the salient role of health in driving meat reduction and increased engagement with plant-based foods.

Health

Excessive red and processed meat consumption has been associated with deleterious health consequences such as increased risk of type 2 diabetes, colorectal cancer and reduced life expectancy(Reference Richi, Baumer and Conrad30Reference González, Marquès and Nadal34). In contrast, ‘traditional’ plant-based dietary patterns are noted to maintain cardiovascular health, reduce obesity and prevent or improve the management of type 2 diabetes(Reference Alae-Carew, Green and Stewart48,Reference Alcorta, Porta and Tárrega49,Reference Beacom, Bogue and Repar98,Reference Perez-Cueto118) . Increased consumer awareness of putative health benefits may therefore have fuelled a dietary shift to reduce animal-sourced food products and increase engagement with plant-based foods(Reference Malek and Umberger20,Reference Jahn, Furchheim and Strässner31,Reference Ishaq, Irfan and Sameen32,Reference Hartmann and Siegrist40,Reference Alae-Carew, Green and Stewart48,Reference Onwezen, Bouwman and Reinders80,Reference Szejda, Urbanovich and Wilks81,Reference Apostolidis and Mcleay84,Reference Gonera, Svanes and Bugge97,Reference Noguerol, Pagán and García-Segovia103,Reference Mullee, Vermeire and Vanaelst115,Reference Mann, Thornton and Crawford122) .

The perceived health benefits of consuming plant-based foods relate to their predicted nutritional composition (low-energy density, low saturated fat content, rich micronutrient profile), and the likely associated physiological effects of dietary adoption (altered cardiometabolic risk and reduced risk of overweight/obesity)(Reference Hoek, Luning and Weijzen76,Reference Apostolidis and Mcleay84,Reference Elzerman, van Boekel and Luning93,Reference Wyker and Davison111,Reference Mullee, Vermeire and Vanaelst115,Reference De Backer and Hudders119,Reference Bryant124Reference Lea, Crawford and Worsley126) . Elzerman et al.(Reference Elzerman, van Boekel and Luning93) highlighted that PBMAs were perceived as healthier than meat amongst Dutch consumer focus groups. This supports the conclusions of cross-sectional surveys where the term ‘nutritious’ was associated with plant-based eating and plant-based burgers were considered healthier than their meat-based equivalent(Reference Van Loo, Hoefkens and Verbeke127,128) . While the online nature of these studies restricts validity of findings, a recent sensory evaluation reported meat-based burgers were deemed ‘unhealthy’ compared PBMAs(Reference Grasso, Rondoni and Bari129). Once again, demographic differences exist with females and middle aged-older consumers more likely to be influenced by health drivers(Reference Szenderák, Fróna and Rákos16,Reference Tonstad, Butler and Yan68,Reference Elzerman, Hoek and van Boekel75) .

When it comes to weight control there are contrasting findings. Hoek et al.(Reference Hoek, Luning and Weijzen76) identified weight control as a motive to try PBMAs across consumers and non-consumers. However, weight loss was not a strong health-related motive for plant-based product adoption amongst plant-based food and beverage product consumers and non-consumers in the UK and Republic of Ireland(Reference Beacom, Bogue and Repar98). Moreover, Culliford and Bradbury(Reference Culliford and Bradbury9) concluded that weight loss was perceived to be substantially less influential compared to health when determining food choice (76 and 12 %, respectively).

Health concerns have been described as a ‘double-edged sword’(Reference Szejda, Urbanovich and Wilks81). Particularly restrictive plant-based dietary patterns (e.g. veganism) may be associated with nutrient deficiency or insufficiency(Reference Jahn, Furchheim and Strässner31). Thus, a lack of awareness regarding the health benefits of regular consumption of PBMAs may enhance the perception that they are nutritionally inferior and limit consumer engagement(Reference Jahn, Furchheim and Strässner31,Reference He, Evans and Liu109) . Elzerman et al.(Reference Elzerman, van Boekel and Luning93) reported that although most focus group participants perceived PBMAs to be healthy (e.g. high in protein and low in saturated fat), concerns were raised regarding digestibility, suitability for children (particularly regarding nutritional needs) and a lack of clarity in relation to their health value. The reported perception that meat is a necessary component of the diet and thus its avoidance raises health concerns may be a key reason for meat-excluders returning to meat consumption(Reference Hoek, Luning and Weijzen76,Reference Pohjolainen, Vinnari and Jokinen94,Reference Barr and Chapman107,Reference de Boer, Schösler and Aiking125) .

Leroy and Cofnas(Reference Leroy and Cofnas130) emphasised the juxtaposition between consumer health-related motivations and the arguably ultra-processed nature of PBMAs(Reference Jahn, Furchheim and Strässner31,Reference Alae-Carew, Green and Stewart48,Reference Wickramasinghe, Breda and Berdzuli131) . Excessive consumption of, so-called ‘ultra-processed’ foods (UPF; see Table 1) has been argued to elevate risk of obesity and associated comorbidities such as CVD(Reference Wickramasinghe, Breda and Berdzuli131). This may explain the findings of Mullee et al.(Reference Mullee, Vermeire and Vanaelst115) who reported nearly a quarter of respondents perceived habitual consumption of vegetarian foods to be ‘unhealthy’. Jahn et al.(Reference Jahn, Furchheim and Strässner31) also identified degree of processing, even processes that are paradoxically designed to enhance nutritional quality (such as fortification), as an important factor in consumer product evaluation and reduced product desirability.

While clearly many factors are associated with engagement with plant-based foods, health plays a salient role in consumer decisions and behaviour(Reference Noguerol, Pagán and García-Segovia103,Reference Mann, Thornton and Crawford122) . More research is needed regarding the specific health-related drivers beyond weight loss. Furthermore, the present evidence base highlights variation in drivers and barriers associated with plant-based food engagement amongst different sub-groups of consumers. This reinforces the need for a strong, evidence-based, whole systems approach to facilitate effective and sustainable dietary behaviour change. It also reinforces the fact that a one-size-fits all approach is not sufficient to accelerate engagement with PBMAs. Instead an increased understanding of the specific needs and barriers within different subgroups of consumers is required to effectively tailor new product development and marketing strategies to meet those needs. Application of segmentation theories to divide populations into smaller subgroups based on similarities can enable consumer segments to be targeted with a more customised strategy. Studies within the present research field have segmented according to sociodemographic factors, dietary patterns and product usage(Reference Culliford and Bradbury9,Reference Hoek, Luning and Weijzen76,Reference Apostolidis and Mcleay84,Reference Gonera, Svanes and Bugge97,Reference Beacom, Bogue and Repar98,Reference Estell, Hughes and Grafenauer110,Reference Neff, Edwards and Palmer112,Reference Parry and Mitchell123,Reference de Boer, Schösler and Aiking125,Reference Lea, Crawford and Worsley126) . However, using models of behaviour change to identify sub-groups more pre-disposed to engage with innovative PBMAs has the potential to accelerate adoption(Reference Szejda, Urbanovich and Wilks81). For example, Roger's diffusion of innovation identifies predisposition to change while the transtheoretical model describes the process of intentional behaviour change(Reference Prochaska and Velicer132,Reference Rogers133) . Together these models would enable investigation of perceptions of, drivers of and barriers to the adoption of novel PBMAs relative to specific population subgroups.

Novel plant-based meat alternatives: health considerations

Despite the paucity in evidence regarding the impact of novel PBMAs on health, a limited number of published studies have indicated their adoption may be associated with a range of health benefits. Notably, a systematic review and meta-analysis of RCTs investigating the impact of plant-protein consumption on lipaemia proposed that protein itself may be responsible for the health-associated benefits(Reference Li, Mejia and Lytvyn134). Hence, processing whole-plant foods into protein isolates may not necessarily compromise their health value. An RCT(Reference Crimarco, Springfield and Petlura135) comparing the impact of PBMAs with animal-derived meat across a range of health risk factors in thirty-six healthy omnivorous adults randomised participants to either plant–animal or animal–plant sequence and instructed them to consume ≥2 servings of the intervention meat product daily while ensuring consumption of other (non-study) foods was comparable in each phase (8 weeks each). PBMA consumption was associated with cardioprotective changes including significantly lower trimethylamine-N-oxide concentrations [PBMA mean = 2⋅7(sem 0⋅3) μm v. meat mean = 4⋅7(sem 0⋅9) μm; mean difference = −2⋅0 [95 % CI −3⋅6, −0⋅3]], LDL-cholesterol concentrations [PBMA mean = 109⋅9(sem 4⋅5) mg/dl v. meat mean = 120⋅7(sem 4⋅5) mg/dl; mean difference = −10⋅8 [95 % CI −17⋅3, −4⋅3]] and weight [PBMA mean = 78⋅7(sem 3⋅0) kg v. meat mean = 79⋅6(sem 3⋅0) kg; mean difference = −1⋅0 [95 % CI −1⋅5, −0⋅5]] compared to meat consumption. It should be noted that the level of dietary control was limited as participants were able to consume chicken or fish in the plant-arm and self-selected all other dietary components. However, this in turn increases the generalisability and external validity of the study findings. A recent RCT(Reference Toribio-Mateas, Bester and Klimenko136) also demonstrated positive changes in the gut microbiome when substituting several meat-based meals weekly for PBMA meals, resulting in a significant increase in butyrate-production pathways and significant decrease in the Tenericutes phylum; attributes associated with a healthy gut microbiome. Zhou et al.(Reference Zhou, Hu and Tan137) also reported higher levels of dietary fibre from the digestion of PBMAs compared to meat that may increase satiation after consumption of the PBMA.

There is conflicting evidence regarding the impact of plant-based foods upon appetite(Reference Kristensen, Bendsen and Christensen138Reference Kahleova, Tintera and Thieme140). Williamson et al.(Reference Williamson, Geiselman and Lovejoy141) conducted a three-way crossover study in overweight subjects (n 42) investigating the satiating efficacy of a mycoprotein pasta preload and a tofu pasta preload compared to an isoenergetic chicken pasta preload, closely matched for protein and organoleptic characteristics. The authors concluded pre-loading with mycoprotein and tofu led to significantly lower food intake compared to chicken preloading (138⋅7, 135⋅2 and 158⋅3 g, respectively). A similar study(Reference Kristensen, Bendsen and Christensen138) reported plant-based protein (beans/peas) to be significantly more effective than energy and protein matched animal-based protein (veal/pork) on subjective markers of appetite in a healthy cohort of male participants (n 43). In contrast, no differences were found between plant-based (fava beans/split peas) and meat-derived (veal/pork) protein meals, matched for energy, macronutrient and fibre, in a single-blinded RCT(Reference Nielsen, Kristensen and Klingenberg139). Similarly, a recent double-blind RCT(Reference Pham, Knowles and Bermingham142) also reported no significant differences regarding markers of appetite between a lamb burrito and a plant-based meat burrito meal. However, it should be noted that the study meals were not matched for protein which may have influenced the results. In addition, Neacsu et al.(Reference Neacsu, Fyfe and Horgan143) suggested plant-based and meat-based high-protein diets had a similar impact on gut-peptide hormones and subjective appetite responses. However, a randomised crossover study demonstrated increased peptide YY, glucagon-like peptide 1, amylin and thalamus perfusion following consumption of a plant-based meal compared to an energy- and macronutrient-matched meat-based meal(Reference Kahleova, Tintera and Thieme140,Reference Klementova, Thieme and Haluzik144) . Proposed satiating mechanisms include high dietary fibre content (promoting SCFA production) in addition to modification of gastric hormone secretion and gastric emptying related to appetite suppression(Reference Salleh, Fairus and Zahary145,Reference Sánchez, Miguel and Aleixandre146) . Grundy et al.(Reference Grundy, Edwards and Mackie147) also described how dietary fibre encapsulates macronutrients to regulate digestion, while soluble dietary fibre increases viscosity in the gastrointestinal tract which in turn may slow macronutrient digestion. However, extensive processing is associated with nutrient loss and UPFs are noted to be limited in appetite-regulating nutrients such as dietary fibre and protein(Reference Fardet and Rock148,Reference Sha and Xiong149) . Thus, the influence of processing on the capacity of commercial PBMAs to elicit fullness needs further investigation. Furthermore, while the RCT study design is considered the gold-standard method, there is an urgent need for longitudinal data to evaluate the long-term consequences of habitual consumption of PBMAs on appetite and health.

Ultra-processed foods

Many novel PBMAs are typically classified as ultra-processed, according to the NOVA definition(Reference Gehring, Touvier and Baudry96,Reference Wickramasinghe, Breda and Berdzuli131) . While processing improves safety and, shelf-life and fortification enhances nutrient content, deleterious health consequences have been associated with ultra-processing. For example, so-called UPFs are noted to contain less appetite-regulating nutrients such as dietary fibre and protein. Additional concerns relate to higher levels of saturated fat, salt and free sugar content and inclusion of additives such as artificial colours, flavours and preservatives(Reference Wickramasinghe, Breda and Berdzuli131,Reference Srour and Touvier150Reference Monteiro and Astrup152) . Moreover, a recent systematic review and meta-analysis by Suksatan and collegues(Reference Suksatan, Moradi and Naeini153) demonstrated a significant dose–response association between UPF consumption and risk of all-cause mortality.

Gehring et al.(Reference Gehring, Touvier and Baudry96) noted greater UPF consumption within meat reduction or avoidant diets compared to omnivorous diets in the French NutriNet-Santé cohort. This supports the notion that while novel PBMAs facilitate reduced meat consumption, their health value needs further consideration(Reference Alae-Carew, Green and Stewart48). However, there is a lack of consensus as to whether all UPFs can be labelled ‘unhealthy’. In fact, Derbyshire(Reference Derbyshire154) argued that some UPFs demonstrate ‘healthy’ nutritional profiles. For example, the authors(Reference Derbyshire154) highlighted fifty UPF products (characterised according to the NOVA classification system) that were identified as ‘healthy’ food products according to the 2011 and 2018 nutritional profiling tool. This and similar findings have led to criticism of NOVA as an ambiguous classification system(Reference Visioli, Marangoni and Fogliano155Reference Gibney, Forde and Mullally159). Additional concern relates to the use of one umbrella term of ‘ultra-processed’ to describe a diverse range of processing techniques which have distinct functions(Reference Rego156). Nonetheless, there is a paucity of evidence supporting the detrimental health consequences associated with ultra-processing upon both the nutritional and mechanistic quality of foods, specifically in relation to PBMAs(Reference Aschemann-Witzel, Gantriis and Fraga4,Reference Srour and Touvier150,Reference Elizabeth, Machado and Zinöcker151) .

Nutritional profile of novel plant-based meat alternatives

Limited published scientific evidence is inconclusive regarding the health value of novel PBMAs and their capacity to replicate the nutritional profile of meat-equivalents. Curtain and Grafenauer(Reference Curtain and Grafenauer160) reported that most PBMAs demonstrated a healthier nutrient profile than meat-based equivalents in their audit of Australian supermarkets. For example, PBMAs were significantly lower in energy density, total fat, saturated fat and significantly higher in dietary fibre. However, the sodium content of PBMAs was particularly high, with only 4 % of products classified as ‘low in sodium’. In fact, plant-based mince had 6-fold higher sodium content than the meat-based equivalent while meat sausages had significantly greater sodium than PBMAs. A similar study in the UK(Reference Alessandrini, Brown and Pombo-Rodrigues161) also reported significantly higher sodium levels in all categories except for sausages and reinforced concerns by identifying approximately three-quarters of products having salt content greater than their maximum salt reduction target. The authors also reported significantly lower protein content in four out of six PBMA categories. However, although the study targeted fourteen UK retailers for PBMAs, Covid-19 restrictions meant that only one supermarket was targeted for meat-equivalent products. Consistency in search method for both product types would increase rigour in future research.

Tonheim et al.(Reference Tonheim, Austad and Torheim162) recently conducted a similar survey investigating PBMAs available on the Norwegian market. Again the Covid-19 pandemic restricted the range of suppliers and data collection was undertaken in two phases. The authors compared PBMAs to their meat-based equivalents in two categories: ‘regular’ meat and ‘healthy’ meat (identified with a keyhole symbol, a labelling scheme identifying healthier food products)(163). These ‘healthy’ meats were typically reduced fat alternatives to ‘regular’ meats. PBMAs were typically lower in energy content compared to ‘regular’ meat, though they contained more energy than their ‘healthy’ meat comparator. PBMAs were generally lower in saturated fat and higher in dietary fibre than either category of meat comparator. There was also between product variation in salt content. While salt content was more favourable in the plant-based meatballs v. both meat-equivalents, it was greater than both meat-equivalents in other product categories with plant-based mince demonstrating a 10-fold greater salt content than the ‘healthy’ meat comparator. In contrast, Boukid and Castellari(Reference Boukid and Castellari164) reported no significant difference in sodium content between the four burger products (vegetarian, red meat, fish and poultry-based) in their survey of the EU burger market.

Heterogeneity both within and between product categories was also demonstrated in other similar studies(Reference Curtain and Grafenauer160,Reference Pocklington, Hackett and Lamkin165Reference SafeFood167) . Fresán et al.(Reference Fresán, Mejia and Craig10) reviewed fifty-six PBMAs according to their protein source and concluded that despite some between product variation, the nutritional profile demonstrated no substantial differences. Meanwhile, Bohrer(Reference Bohrer166) reported the nutritional composition of a plant-based burger to be similar to that of a McDonald's® beef patty but found differences in meatballs where the plant-based version was lower in energy, saturated fat and higher in dietary fibre compared to the meat-based equivalent. In addition, safefood(Reference SafeFood167) identified chicken alternatives to be less favourable on a number of nutritional components including energy density, protein, saturated fat, sugar and salt in their audit of PBMAs in Irish supermarkets. However, the method of product categorisation may have influenced the findings(Reference SafeFood167). For example, while other studies(Reference Curtain and Grafenauer160Reference Tonheim, Austad and Torheim162,Reference Bryngelsson, Moshtaghian and Bianchi168) typically selected an equivalent meat-based product as a comparator, the authors(Reference SafeFood167) compared all chicken alternatives, including breaded, battered and plain alternative products, to a skinless, grilled chicken breast. Similarly, while other studies(Reference Curtain and Grafenauer160,Reference Alessandrini, Brown and Pombo-Rodrigues161,Reference Bryngelsson, Moshtaghian and Bianchi168) compared plant-based mince to beef mince, the authors(Reference SafeFood167) compared plant-based alternative steaks, mince, meatballs and Bolognese to beef mincemeat. This method of categorisation limits the reliability of study findings as the selected meat product does not reflect a suitable comparator. This highlights a substantial challenge for research conducted within this area. For example, a robust feeding trial would require an appropriate comparator arm which includes an element of blinding across a range of factors including sensory attributes, cooking technique and nutritional profiling. However, a major limitation in the afore-mentioned studies is the omission of micronutrient analysis. As meat is considered a valuable vehicle of vital micronutrients such as vitamin B12, zinc, iron and calcium, vitamin and mineral content should be considered when evaluating nutritional value of PBMAs(Reference Rust, Ridding and Ward17,Reference Tso and Forde18,Reference Curtain and Grafenauer160) .

More recent studies have considered micronutrient alongside macronutrient composition in their evaluation of PBMAs(Reference Bryngelsson, Moshtaghian and Bianchi168Reference Cole, Goeler-Slough and Cox170). These studies used similar methods, identifying PBMAs via a search of defined supermarkets and extracting nutritional information from product packaging, front of pack information and both supermarket and manufacturer websites. While there was substantial between product variation, the studies generally reported PBMAs to be lower in saturated fat, richer in dietary fibre and substantially higher in sodium than their meat-based comparator. However, despite reporting an intention to analyse micronutrient content of PBMAs, D'Alessandro et al.(Reference D'Alessandro, Pezzica and Bolli169) failed to present data for these variables. While Bryngelsson et al.(Reference Bryngelsson, Moshtaghian and Bianchi168) reported that a large proportion of PBMAs lacked micronutrient information, the limited data highlighted a wide variation between product categories. For example, while PBMAs were typically richer in iron and folate compared to their meat-equivalent, vitamin B12 was noted to be higher in plant-based sausages, lower in bacon and similar within the nugget product range. However, these data were derived from a very limited number of products as information for iron, folate and vitamin B12 were provided on 13, 6 and 6 % of products, respectively.

Cole et al.(Reference Cole, Goeler-Slough and Cox170) restricted their analysis to burger categories (imitation burger, vegetarian burger and conventional beef burgers) and highlighted variation in vitamin and mineral content. For example, although the imitation burger demonstrated comparable levels of iron, it was significantly richer in vitamins A, C and D, potassium and calcium compared to the meat-based equivalent. However, the authors were unable to obtain information regarding a range of vitamins and minerals that are key components of beef, including zinc, vitamin B12, phosphorus and magnesium. This may reflect that in the EU labelling of vitamin and mineral information on packaged food labelling is at the discretion of the manufacturer and highlights a limitation of evaluating micronutrient value through nutrition facts labelling(171). Meanwhile, Harnack et al.(Reference Harnack, Mork and Valluri172) used food ingredient information alongside nutrition facts labelling to develop recipes and estimate nutritional value of selected beef alternative products in contrast to meat counterparts. They reported plant-based ground beef to be a rich source of dietary fibre with comparable levels of iron compared to ground beef but highlighted a shortfall in protein, zinc and vitamin B12 alongside substantially higher sodium content. Again, the authors acknowledged that inaccurate labelling and limitations in the Food and Nutrition Database used to develop recipes increased the risk of inaccurate calculations of nutritional value.

Two studies(Reference Swing, Thompson and Guimaraes173,Reference De Marchi, Costa and Pozza174) have investigated nutritional composition using laboratory analysis techniques. Although it was not reported, it could be inferred that the associated time and cost-burden may have resulted in restricted focus of these studies(Reference Swing, Thompson and Guimaraes173,Reference De Marchi, Costa and Pozza174) to single-product categories (burger products). Both studies(Reference Swing, Thompson and Guimaraes173,Reference De Marchi, Costa and Pozza174) concluded that the plant-based burger products were able to demonstrate a comparable nutritional profile and richer content of certain minerals although there was again variability between products. However, in contrast to other studies where PBMAs were reported to be lower in saturated fat content but contain substantially more sodium, De Marchi and colleagues(Reference De Marchi, Costa and Pozza174) reported no significant difference in sodium or saturated fat content between plant-based and meat-based burgers. However, the comparable levels of saturated fat may be attributed to use of particular ingredients in the selected products such as coconut oil in the plant-based burgers(Reference Kołodziejczak, Onopiuk and Szpicer175).

A more recent study conducted a comprehensive nutritional analysis of a large range of PBMAs (hot and cold categories) v. their meat-based counterparts using four national nutrient databases and laboratory analyses(Reference Pointke and Pawelzik176). The authors support previous study findings(Reference Curtain and Grafenauer160,Reference Alessandrini, Brown and Pombo-Rodrigues161,Reference Bryngelsson, Moshtaghian and Bianchi168,Reference Cole, Goeler-Slough and Cox170) where despite substantial variation between PBMA product ranges, PBMAs were demonstrated to have lower energy density, total and saturated fat but considerably higher sugar and sodium levels compared to their meat-equivalents. In addition, analysis of micronutrients demonstrated similarities to other reports where PBMAs were notably higher in calcium, phosphorus and iron(Reference Bryngelsson, Moshtaghian and Bianchi168,Reference Cole, Goeler-Slough and Cox170) . In contrast to other studies, the authors analysed a greater range of micronutrients and highlighted substantial between product heterogeneity. For example, while levels of micronutrients, such as folate, vitamins B6, E and K, were either comparable or superior to their meat-based comparator, others demonstrated a significant shortfall, in particularly vitamin B12 and zinc. Similarly, the study was unable to detect vitamin D within PBMAs; highlighting the need for manufacturers to consider fortification of certain products to ensure sufficient nutrient content. This supports previous studies that have raised concern regarding the level of and/or bioavailability of nutrients such as vitamin B12, zinc and iron in plant-based diets and the need to consider meal plans and supplementation to avoid nutrient deficiency(Reference Harnack, Mork and Valluri172,Reference Rizzo, Laganà and Rapisarda177Reference Craig, Mangels and Fresán179) . For example, plant-based foods are a primary source of non-haem iron, which has much lower bioavailability compared to haem iron, the predominant form present in animal-derived foods; reinforcing the need for PBMA fortification(Reference van Vliet, Kronberg and Provenza79,Reference Kołodziejczak, Onopiuk and Szpicer175,Reference Rizzo, Laganà and Rapisarda177,Reference Harnack, Reese and Johnson180) . However, fortification of PBMAs with vitamin B12, iron and zinc is inconsistent with under a quarter of products fortified with these nutrients(Reference Curtain and Grafenauer160,Reference Bryngelsson, Moshtaghian and Bianchi168,Reference Harnack, Reese and Johnson180) . Tso and Forde(Reference Tso and Forde18) recently compared a model omnivorous reference diet to model diets replacing animal-derived products for either ‘traditional’ plant-based foods or novel plant-based products (e.g. PBMAs). Acknowledging the variability in fortification of plant-based products, the authors excluded fortified products from their reference diets. The findings highlighted that novel plant-based products were unable to meet dietary requirements for a range of nutrients including zinc and vitamin B12 in contrast to the omnivorous reference diet. While this study was a hypothetical comparison, it yet again reinforces the need to consider fortification methods to protect against deficiency for diets incorporating PBMAs.

Ultimately, these findings demonstrate the inconsistent nutrient profile of PBMAs and highlight the challenge of successful replication of meat-equivalents. There are multiple confounding variables that may have influenced the heterogeneity of the reported findings including geographical location, product search methods and measurement tools used. For example, despite being deemed a reliable tool, questions have been raised regarding the ability of the UK Nutrient Profiling Index to reflect present consumption behaviour and recent revisions have been made to the model to address such limitations(181). Furthermore, while the healthy star rating system has been praised for inclusivity and understandability, it is contextualised to Australia and New Zealand(Reference Jones, Thow and Ni Mhurchu182). However, a key limitation of these tools is that they fail to consider the potential impact of degree of processing on the nutritional and mechanistic quality of food products and there is a need for greater understanding of the possible impact of this on the health benefits associated with particular ingredients. For example, processing can increase or decrease the bioavailability, digestibility, nutritional and functional characteristics of particular foods and ingredients(Reference Aguilera183). Furthermore, the potential impact of antinutrients commonly present in PBMAs, such as phytate and tannins, requires further understanding, particularly regarding possible positive or negative interactions within the food matrix in addition to their potential inhibition of the absorption of other key vitamins and minerals(Reference Aguilera183). In addition, despite some inconsistency, the majority of studies highlighted considerably higher levels of sodium in PBMAs and some authors attributed this to ultra-processing(Reference Gehring, Touvier and Baudry96,Reference Wickramasinghe, Breda and Berdzuli131) . This is concerning given the association between high sodium intake and increased risk of non-communicable disease such as CVD(Reference Lane, Davis and Beattie184,Reference Mozaffarian, Fahimi and Singh185) .

Thus, without further clarification on the impact of processing, categorising UPFs as ‘healthy’ may inflate the so-called ‘health halo’ surrounding PBMAs(Reference Wickramasinghe, Breda and Berdzuli131). Present paucity in knowledge, coupled with the rapid expansion of the PBMA market means there is a growing urgency for more scientific evidence to address this ambiguity and a strong rationale to improve consumer literacy of PBMAs(Reference Estell, Hughes and Grafenauer110,Reference Wickramasinghe, Breda and Berdzuli131) .

Conclusions

The equivocal nature of the limited published findings, specifically in relation to the health value of novel PBMAs, raises concern as to whether consumers are using historic evidence related to ‘traditional’ plant-based dietary patterns to make assumptions. While such products may not align with aspirational, ‘traditional’ plant-based food consumption, one must consider whether these novel products do offer a healthier alternative to meat-based equivalents. With the exception of sodium and possibly some micronutrients, the present evidence suggests this may be the case. If so, this raises the question whether accelerating the adoption of these products will create a good compromise with incremental benefits to public health and climate change targets while meeting consumer demand.

Food manufacturers are now recognising the urgency to deliver products with healthier nutrient profiles, emphasising the need for rigorous studies which consider a range of variables such as level of processing and nutritional composition. Understanding the impact of extensive processing on health effects may help to justify the use of innovative methods designed to maintain health benefits associated with particular foods and ingredients. In addition, furthering knowledge regarding the nutritional value of PBMAs will identify opportunities to enhance their health profile and promote consumer capacity to make informed food choices.

Finally, a clearer understanding of factors influencing engagement of target consumer subgroups with PBMAs may support production of desirable healthier plant-based foods. Such evidence-based food manufacturing practice has the potential to positively influence future individual and planetary health.

Acknowledgements

The authors thank the organisers of the Nutrition Society 2022 Summer Conference and Postgraduate Competition for their invitation to present this review.

Financial Support

M. F. is supported by a Sheffield Business School GTA Studentship, Sheffield Hallam University. This work received no specific grant from any funding agency, commercial or not-for-profit sectors.

Conflict of Interest

None.

Authorship

Substantial conception and contribution to the design of this work was made by J. R. P. and A. L. with significant contribution from M. F. and S. B. M. F. drafted the manuscript with intellectual contribution and revision from A. L., J. R. P. and S. B. All authors approved the final version of the manuscript.

References

Bryant, C, Szejda, K, Parekh, N et al. (2019) A survey of consumer perceptions of plant-based and clean meat in the USA, India, and China. Front Sustain Food Syst 3, 11.10.3389/fsufs.2019.00011CrossRefGoogle Scholar
European Commission (2020) Farm to fork strategy for a fair, healthy and environmentally-friendly food system. https://food.ec.europa.eu/system/files/2020-05/f2f_action-plan_2020_strategy-info_en.pdf (accessed September 2022).Google Scholar
García-Oliveira, P, Fraga-Corral, M, Pereira, AG et al. (2022) Solutions for the sustainability of the food production and consumption system. Crit Rev Food Sci Nutr 62, 17651781.CrossRefGoogle ScholarPubMed
Aschemann-Witzel, J, Gantriis, RF, Fraga, P et al. (2021) Plant-based food and protein trend from a business perspective: markets, consumers, and the challenges and opportunities in the future. Crit Rev Food Sci Nutr 61, 31193128.10.1080/10408398.2020.1793730CrossRefGoogle ScholarPubMed
Sridhar, K, Bouhallab, S, Croguennec, T et al. (2022) Recent trends in design of healthier plant-based alternatives: nutritional profile, gastrointestinal digestion, and consumer perception. Crit Rev Food Sci Nutr 1, 116.10.1080/10408398.2022.2081666CrossRefGoogle Scholar
Willett, W, Rockström, J, Loken, B et al. (2019) Food in the Anthropocene: the EAT–Lancet commission on healthy diets from sustainable food systems. Lancet 393, 447492.CrossRefGoogle ScholarPubMed
Choudhury, D, Singh, S, Seah, JSH et al. (2020) Commercialization of plant-based meat alternatives. Trends Plant Sci 25, 10551058.10.1016/j.tplants.2020.08.006CrossRefGoogle ScholarPubMed
Gastaldello, A, Giampieri, F, De Giuseppe, R et al. (2022) The rise of processed meat alternatives: a narrative review of the manufacturing, composition, nutritional profile and health effects of newer sources of protein, and their place in healthier diets. Trends Food Sci Technol 127, 263271.10.1016/j.tifs.2022.07.005CrossRefGoogle Scholar
Culliford, A & Bradbury, J (2020) A cross-sectional survey of the readiness of consumers to adopt an environmentally sustainable diet. Nutr J 19, 113.10.1186/s12937-020-00644-7CrossRefGoogle ScholarPubMed
Fresán, U, Mejia, MA, Craig, WJ et al. (2019) Meat analogs from different protein sources: a comparison of their sustainability and nutritional content. Sustainability 11, 3231.CrossRefGoogle Scholar
Bakhsh, A, Lee, S-J, Lee, E-Y et al. (2021) Traditional plant-based meat alternatives, current, and future perspective: a review. J Agric Life Sci 55, 111.CrossRefGoogle Scholar
Gibbs, J & Cappuccio, FP (2022) Plant-based dietary patterns for human and planetary health. Nutrients 14, 111.CrossRefGoogle ScholarPubMed
Fiorentini, M, Kinchla, AJ & Nolden, AA (2020) Role of sensory evaluation in consumer acceptance of plant-based meat analogs and meat extenders: a scoping review. Foods 9, 1334.10.3390/foods9091334CrossRefGoogle ScholarPubMed
McClements, DJ & Grossmann, L (2021) A brief review of the science behind the design of healthy and sustainable plant-based foods. npj Sci Food 5, 17.10.1038/s41538-021-00099-yCrossRefGoogle ScholarPubMed
Singh, M, Trivedi, N, Enamala, MK et al. (2021) Plant-based meat analogue (PBMA) as a sustainable food: a concise review. Eur Food Res Technol 247, 24992526.10.1007/s00217-021-03810-1CrossRefGoogle Scholar
Szenderák, J, Fróna, D & Rákos, M (2022) Consumer acceptance of plant-based meat substitutes: a narrative review. Foods 11, 1274.CrossRefGoogle ScholarPubMed
Rust, NA, Ridding, L, Ward, C et al. (2020) How to transition to reduced-meat diets that benefit people and the planet. Sci Total Environ 718, 137208.10.1016/j.scitotenv.2020.137208CrossRefGoogle ScholarPubMed
Tso, R & Forde, CG (2021) Unintended consequences: nutritional impact and potential pitfalls of switching from animal- to plant-based foods. Nutrients 13, 116.CrossRefGoogle ScholarPubMed
Farsi, DN, Uthumange, D, Munoz Munoz, J et al. (2021) The nutritional impact of replacing dietary meat with meat alternatives in the UK: a modelling analysis using nationally representative data. Br J Nutr 127, 111.Google Scholar
Malek, L & Umberger, WJ (2021) How flexible are flexitarians? Examining diversity in dietary patterns, motivations and future intentions. Clean Responsible Consumption 3, 100038.10.1016/j.clrc.2021.100038CrossRefGoogle Scholar
MacDiarmid, JI (2021) The food system and climate change: are plant-based diets becoming unhealthy and less environmentally sustainable? Proc Nutr Soc 3, 16.Google Scholar
Zhang, R, Tang, X, Liu, J et al. (2022) From concept to action: a united, holistic and one health approach to respond to the climate change crisis. Infect Dis Poverty 11, 49.10.1186/s40249-022-00941-9CrossRefGoogle Scholar
Anderson, CAM, Thorndike, AN, Lichtenstein, AH et al. (2019) Innovation to create a healthy and sustainable food system: a science advisory from the American heart association. Circulation 139, 10251032.CrossRefGoogle ScholarPubMed
Graça, J, Oliveira, A & Calheiros, MM (2015) Meat, beyond the plate. Data-driven hypotheses for understanding consumer willingness to adopt a more plant-based diet. Appetite 90, 8090.CrossRefGoogle ScholarPubMed
Joyce, A, Dixon, S, Comfort, J et al. (2012) Reducing the environmental impact of dietary choice: perspectives from a behavioural and social change approach. J Environ Public Health. Published online: 17 June 2021. doi: https://doi.org/101.155%2F2012%2F978672.CrossRefGoogle ScholarPubMed
Kwasny, T, Dobernig, K & Riefler, P (2022) Towards reduced meat consumption: a systematic literature review of intervention effectiveness, 2001–2019. Appetite 168, 105739.10.1016/j.appet.2021.105739CrossRefGoogle ScholarPubMed
Wellesley, L, Happer, C & Froggatt, A (2015) Changing climate, changing diets pathways to lower meat consumption. https://www.chathamhouse.org/2015/11/changing-climate-changing-diets-pathways-lower-meat-consumption (accessed September 2022).Google Scholar
Statista (2022) Meat consumption worldwide from 1990 to 2021, by meat type. https://www.statista.com/statistics/274522/global-per-capita-consumption-of-meat/#statisticContainer (accessed September 2022).Google Scholar
Our World in Data (2017) Meat and dairy production. https://ourworldindata.org/meat-production (accessed September 2022).Google Scholar
Richi, EB, Baumer, B, Conrad, B et al. (2015) Health risks associated with meat consumption: a review of epidemiological studies. Int J Vitam Nutr Res 85, 7078.10.1024/0300-9831/a000224CrossRefGoogle Scholar
Jahn, S, Furchheim, P & Strässner, AM (2021) Plant-based meat alternatives: motivational adoption barriers and solutions. Sustainability 13, 117.CrossRefGoogle Scholar
Ishaq, A, Irfan, S, Sameen, A et al. (2022) Plant-based meat analogs: a review with reference to formulation and gastrointestinal fate. Curr Res Food Sci 5, 973983.CrossRefGoogle ScholarPubMed
Harguess, JM, Crespo, NC & Hong, MY (2020) Strategies to reduce meat consumption: a systematic literature review of experimental studies. Appetite 144, 104478.10.1016/j.appet.2019.104478CrossRefGoogle ScholarPubMed
González, N, Marquès, M, Nadal, M et al. (2020) Meat consumption: which are the current global risks? A review of recent (2010–2020) evidences. Food Res Int 137, 109341.10.1016/j.foodres.2020.109341CrossRefGoogle ScholarPubMed
Bouvard, V, Loomis, D, Guyton, KZ et al. (2015) Carcinogenicity of consumption of red and processed meat. Lancet Oncol 16, 15991600.CrossRefGoogle ScholarPubMed
World Cancer Research Fund (n.d.) Limit red meat and avoid processed meat. https://www.wcrf-uk.org/preventing-cancer/our-cancer-prevention-recommendations/limit-red-meat-and-avoid-processed-meat/ (accessed September 2022).Google Scholar
World Health Organisation. Global nutrition targets 2025: stunting policy brief [Internet]. 2014 [cited 5 September 2022]. Available from: https://www.who.int/publications/i/item/WHO-NMH-NHD-143.Google Scholar
Adesogan, AT, Havelaar, AH, McKune, SL et al. (2020) Animal source foods: sustainability problem or malnutrition and sustainability solution? Perspective matters. Glob Food Sec 25, 100325.10.1016/j.gfs.2019.100325CrossRefGoogle Scholar
Jairath, G, Mal, G, Gopinath, D et al. (2021) An holistic approach to access the viability of cultured meat: a review. Trends Food Sci Technol 110, 700710.10.1016/j.tifs.2021.02.024CrossRefGoogle Scholar
Hartmann, C & Siegrist, M (2017) Consumer perception and behaviour regarding sustainable protein consumption: a systematic review. Trends Food Sci Technol 61, 1125.10.1016/j.tifs.2016.12.006CrossRefGoogle Scholar
Song, M, Fung, TT, Hu, FB et al. (2016) Animal and plant protein intake and all-cause and cause-specific mortality: results from two prospective US cohort studies. JAMA Intern Med 176, 14531463.CrossRefGoogle Scholar
Sabaté, J, Sranacharoenpong, K & Harwatt, H (2015) The environmental cost of protein food choices. Public Health Nutr 18, 20672073.CrossRefGoogle ScholarPubMed
Lonnie, M & Johnstone, AM (2020) The public health rationale for promoting plant protein as an important part of a sustainable and healthy diet. Nutr Bull 45, 281293.CrossRefGoogle Scholar
Steenson, S & Buttriss, JL (2021) Healthier and more sustainable diets: what changes are needed in high-income countries? Nutr Bull 46, 279309.10.1111/nbu.12518CrossRefGoogle Scholar
Scarborough, P, Kaur, A, Cobiac, L et al. (2016) Eatwell guide: modelling the dietary and cost implications of incorporating new sugar and fibre guidelines. BMJ Open 6, 110.CrossRefGoogle ScholarPubMed
Reynolds, CJ, Horgan, GW, Whybrow, S et al. (2019) Healthy and sustainable diets that meet greenhouse gas emission reduction targets and are affordable for different income groups in the UK. Public Health Nutr 22, 15031517.10.1017/S1368980018003774CrossRefGoogle ScholarPubMed
Alae-Carew, C, Green, R, Stewart, C et al. (2022) The role of plant-based alternative foods in sustainable and healthy food systems: consumption trends in the UK. Sci Total Environ 807, 151041.CrossRefGoogle ScholarPubMed
Alcorta, A, Porta, A & Tárrega, A (2021) Foods for plant-based diets: challenges and innovations. Foods 10, 123.10.3390/foods10020293CrossRefGoogle ScholarPubMed
Attwood, S & Hajat, C (2020) How will the COVID-19 pandemic shape the future of meat consumption? Public Health Nutr 23, 116120.CrossRefGoogle ScholarPubMed
Boukid, F (2020) Plant-based meat analogues: from niche to mainstream. Eur Food Res Technol 247, 297308.CrossRefGoogle Scholar
Bryant, CJ (2022) Plant-based animal product alternatives are healthier and more environmentally sustainable than animal products. Future Foods 6, 100174.10.1016/j.fufo.2022.100174CrossRefGoogle Scholar
Harland, J & Garton, L (2016) An update of the evidence relating to plant-based diets and cardiovascular disease, type 2 diabetes and overweight. Nutr Bull 41, 323338.10.1111/nbu.12235CrossRefGoogle Scholar
Kahleova, H, Levin, S & Barnard, N (2017) Cardio-metabolic benefits of plant-based diets. Nutrients 9, 113.CrossRefGoogle ScholarPubMed
Naghshi, S, Sadeghi, O, Willett, WC et al. (2020) Dietary intake of total, animal, and plant proteins and risk of all cause, cardiovascular, and cancer mortality: systematic review and dose–response meta-analysis of prospective cohort studies. Br Med J 370, 2412.10.1136/bmj.m2412CrossRefGoogle ScholarPubMed
Dinu, M, Abbate, R & Gensini, GF (2017) Vegetarian, vegan diets and multiple health outcomes: a systematic review with meta-analysis of observational studies. Crit Rev Food Sci Nutr 57, 36403649.10.1080/10408398.2016.1138447CrossRefGoogle ScholarPubMed
Jafari, S, Hezaveh, E, Jalilpiran, Y et al. (2022) Plant-based diets and risk of disease mortality: a systematic review and meta-analysis of cohort studies. Crit Rev Food Sci Nutr 62, 77607772.10.1080/10408398.2021.1918628CrossRefGoogle ScholarPubMed
Kim, H, Caulfield, LE & Rebholz, CM (2018) Healthy plant-based diets are associated with lower risk of all-cause mortality in US adults. J Nutr 148, 624631.10.1093/jn/nxy019CrossRefGoogle ScholarPubMed
Tantamango-Bartley, Y, Jaceldo-Siegl, K, Fan, J et al. (2013) Vegetarian diets and the incidence of cancer in a low-risk population. Cancer Epidemiol Biomarkers Prev 22, 286294.10.1158/1055-9965.EPI-12-1060CrossRefGoogle Scholar
Lanou, AJ & Svenson, B (2011) Reduced cancer risk in vegetarians: an analysis of recent reports. Cancer Manag Res 3(1), 18.Google Scholar
Segovia-Siapco, G & Sabaté, J (2019) Health and sustainability outcomes of vegetarian dietary patterns: a revisit of the EPIC-Oxford and the Adventist Health Study-2 cohorts. Eur J Clin Nutr 72, 6070.CrossRefGoogle ScholarPubMed
Huang, RY, Huang, CC, Hu, FB et al. (2016) Vegetarian diets and weight reduction: a meta-analysis of randomized controlled trials. J Gen Intern Med 31, 109116.10.1007/s11606-015-3390-7CrossRefGoogle ScholarPubMed
Barnard, ND, Levin, SM & Yokoyama, Y (2015) A systematic review and meta-analysis of changes in body weight in clinical trials of vegetarian diets. J Acad Nutr Diet 115, 954969.10.1016/j.jand.2014.11.016CrossRefGoogle ScholarPubMed
Turner-McGrievy, GM, Davidson, CR, Wingard, EE et al. (2015) Comparative effectiveness of plant-based diets for weight loss: a randomized controlled trial of five different diets. Nutrition 31, 350358.10.1016/j.nut.2014.09.002CrossRefGoogle ScholarPubMed
Tran, E, Dale, HF, Jensen, C et al. (2020) Effects of plant-based diets on weight status: a systematic review. Diabetes, Metab Syndr Obes Targets Ther 13, 34333448.CrossRefGoogle ScholarPubMed
Spencer, EA, Appleby, PN, Davey, GK et al. (2003) Diet and body mass index in 38 000 EPIC-Oxford meat-eaters, fish-eaters, vegetarians and vegans. Int J Obes 27, 728734.10.1038/sj.ijo.0802300CrossRefGoogle Scholar
Rosell, M, Appleby, P, Spencer, E et al. (2006) Weight gain over 5 years in 21 966 meat-eating, fish-eating, vegetarian, and vegan men and women in EPIC-Oxford. Int J Obes 30, 13891396.10.1038/sj.ijo.0803305CrossRefGoogle ScholarPubMed
Tonstad, S, Butler, T, Yan, R et al. (2009) Type of vegetarian diet, body weight, and prevalence of type 2 diabetes. Diabetes Care 32, 791796.10.2337/dc08-1886CrossRefGoogle ScholarPubMed
Kwok, CS, Umar, S, Myint, PK et al. (2014) Vegetarian diet, Seventh Day Adventists and risk of cardiovascular mortality: a systematic review and meta-analysis. Int J Cardiol 176, 680686.10.1016/j.ijcard.2014.07.080CrossRefGoogle ScholarPubMed
Banta, JE, Lee, JW, Hodgkin, G et al. (2018) The global influence of the Seventh-Day Adventist church on diet. Religions 9, 125.10.3390/rel9090251CrossRefGoogle Scholar
Orlich, MJ, Singh, PN, Sabaté, J et al. (2013) Vegetarian dietary patterns and mortality in Adventist Health Study 2. JAMA Intern Med 173, 12301238.10.1001/jamainternmed.2013.6473CrossRefGoogle ScholarPubMed
Weinrich, R (2019) Opportunities for the adoption of health-based sustainable dietary patterns: a review on consumer research of meat substitutes. Sustainability 11, 4028.10.3390/su11154028CrossRefGoogle Scholar
Mintel (2021) Meat substitutes market report 2021. https://store.mintel.com/report/uk-meat-substitutes-market-report (accessed September 2022).Google Scholar
Michel, F, Hartmann, C & Siegrist, M (2021) Consumers’ associations, perceptions and acceptance of meat and plant-based meat alternatives. Food Qual Prefer 87, 104063.10.1016/j.foodqual.2020.104063CrossRefGoogle Scholar
Elzerman, JE, Hoek, AC, van Boekel, MAJS et al. (2011) Consumer acceptance and appropriateness of meat substitutes in a meal context. Food Qual Prefer 22, 233240.10.1016/j.foodqual.2010.10.006CrossRefGoogle Scholar
Hoek, AC, Luning, PA, Weijzen, P et al. (2011) Replacement of meat by meat substitutes. A survey on person- and product-related factors in consumer acceptance. Appetite 56, 662673.10.1016/j.appet.2011.02.001CrossRefGoogle ScholarPubMed
Vatanparast, H, Islam, N, Shafiee, M et al. (2020) Increasing plant-based meat alternatives and decreasing red and processed meat in the diet differentially affect the diet quality and nutrient intakes of Canadians. Nutrients 12, 114.CrossRefGoogle ScholarPubMed
Rosi, A, Mena, P, Pellegrini, N et al. (2017) Environmental impact of omnivorous, ovo-lacto-vegetarian, and vegan diet. Sci Rep 7, 19.10.1038/s41598-017-06466-8CrossRefGoogle ScholarPubMed
van Vliet, S, Kronberg, SL & Provenza, FD (2020) Plant-based meats, human health, and climate change. Front Sustain Food Syst 4, 128.CrossRefGoogle Scholar
Onwezen, MC, Bouwman, EP, Reinders, MJ et al. (2021) A systematic review on consumer acceptance of alternative proteins: pulses, algae, insects, plant-based meat alternatives, and cultured meat. Appetite 159, 105058.10.1016/j.appet.2020.105058CrossRefGoogle ScholarPubMed
Szejda, K, Urbanovich, T & Wilks, m (2020) accelerating consumer Adoption of Plant-Based Meat: An Evidence-Based Guide for Effective Practice. https://gfi.org/images/uploads/2020/03/FINAL-Consumer-Adoption-Strategic-Recommendations-Report.pdf (accessed September 2022).Google Scholar
Knaapila, A, Michel, F, Jouppila, K et al. (2022) Millennials’ consumption of and attitudes toward meat and plant-based meat alternatives by consumer segment in Finland. Foods 11, 456.CrossRefGoogle ScholarPubMed
Circus, VE & Robison, R (2019) Exploring perceptions of sustainable proteins and meat attachment. Br Food J 121, 533545.CrossRefGoogle Scholar
Apostolidis, C & Mcleay, F (2016) It's not vegetarian, it's meat-free! meat eaters, meat reducers and vegetarians and the case of Quorn in the UK. Soc Bus 6, 267290.10.1362/204440816X14811339560938CrossRefGoogle Scholar
Clark, LF & Bogdan, AM (2019) The role of plant-based foods in Canadian diets: a survey examining food choices, motivations and dietary identity. J Food Prod Mark 25, 355377.10.1080/10454446.2019.1566806CrossRefGoogle Scholar
Broeckhoven, I, Verbeke, W, Tur-Cardona, J et al. (2021) Consumer valuation of carbon labeled protein-enriched burgers in European older adults. Food Qual Prefer 89, 104114.10.1016/j.foodqual.2020.104114CrossRefGoogle Scholar
Collier, ES, Oberrauter, LM, Normann, A et al. (2021) Identifying barriers to decreasing meat consumption and increasing acceptance of meat substitutes among Swedish consumers. Appetite 167, 105643.CrossRefGoogle ScholarPubMed
Allès, B, Baudry, J, Méjean, C et al. (2017) Comparison of sociodemographic and nutritional characteristics between self-reported vegetarians, vegans, and meat-eaters from the Nutrinet-Santé study. Nutrients 9, 1023.CrossRefGoogle ScholarPubMed
Boonpor, J, Petermann-Rocha, F, Parra-Soto, S et al. (2022) Types of diet, obesity, and incident type 2 diabetes: findings from the UK biobank prospective cohort study. Diabetes Obes Metab 24, 13511359.10.1111/dom.14711CrossRefGoogle ScholarPubMed
Wozniak, H, Larpin, C, De Mestral, C et al. (2020) Vegetarian, pescatarian and flexitarian diets: sociodemographic determinants and association with cardiovascular risk factors in a Swiss urban population. Br J Nutr 124, 844852.10.1017/S0007114520001762CrossRefGoogle Scholar
Bedford, JL & Barr, SI (2005) Diets and selected lifestyle practices of self-defined adult vegetarians from a population-based sample suggest they are more ‘health conscious’. Int J Behav Nutr Phys Act 2, 4.10.1186/1479-5868-2-4CrossRefGoogle ScholarPubMed
Tobler, C, Visschers, VHM & Siegrist, M (2011) Eating green. Consumers’ willingness to adopt ecological food consumption behaviors. Appetite 57, 674682.10.1016/j.appet.2011.08.010CrossRefGoogle ScholarPubMed
Elzerman, JE, van Boekel, MAJS & Luning, PA (2013) Exploring meat substitutes: consumer experiences and contextual factors. Br Food J 115, 700710.CrossRefGoogle Scholar
Pohjolainen, P, Vinnari, M & Jokinen, P (2015) Consumers’ perceived barriers to following a plant-based diet. Br Food J 117, 11501167.CrossRefGoogle Scholar
Webster, J, Greenwood, DC & Cade, JE (2022) Risk of hip fracture in meat-eaters, pescatarians, and vegetarians: results from the UK women's cohort study. BMC Med 20, 275.CrossRefGoogle ScholarPubMed
Gehring, J, Touvier, M, Baudry, J et al. (2021) Consumption of ultra-processed foods by pesco-vegetarians, vegetarians, and vegans: associations with duration and age at diet initiation. J Nutr 151, 120131.10.1093/jn/nxaa196CrossRefGoogle ScholarPubMed
Gonera, A, Svanes, E, Bugge, AB et al. (2021) Moving consumers along the innovation adoption curve: a new approach to accelerate the shift toward a more sustainable diet. Sustainability 13, 4477.10.3390/su13084477CrossRefGoogle Scholar
Beacom, E, Bogue, J & Repar, L (2021) Market-oriented development of plant-based food and beverage products: a usage segmentation approach. J Food Prod Mark 27, 204222.10.1080/10454446.2021.1955799CrossRefGoogle Scholar
IFIC (2019) 2019 Food and health survey. https://foodinsight.org/2019-food-and-health-survey/ (accessed September 2022).Google Scholar
Schouteten, JJ, De Steur, H, De Pelsmaeker, S et al. (2016) Emotional and sensory profiling of insect-, plant- and meat-based burgers under blind, expected and informed conditions. Food Qual Prefer 52, 2731.CrossRefGoogle Scholar
Hielkema, MH & Lund, TB (2021) Reducing meat consumption in meat-loving Denmark: exploring willingness, behavior, barriers and drivers. Food Qual Prefer 93, 104257.CrossRefGoogle Scholar
Aschemann-Witzel, J, Varela, P & Peschel, AO (2019) Consumers’ categorization of food ingredients: do consumers perceive them as ‘clean label’ producers expect? An exploration with projective mapping. Food Qual Prefer 71, 117128.10.1016/j.foodqual.2018.06.003CrossRefGoogle Scholar
Noguerol, AT, Pagán, MJ, García-Segovia, P et al. (2021) Green or clean? Perception of clean label plant-based products by omnivorous, vegan, vegetarian and flexitarian consumers. Food Res Int 149, 110652.10.1016/j.foodres.2021.110652CrossRefGoogle ScholarPubMed
Asioli, D, Aschemann-Witzel, J, Caputo, V et al. (2017) Making sense of the ‘clean label’ trends: a review of consumer food choice behavior and discussion of industry implications. Food Res Int 99, 5871.10.1016/j.foodres.2017.07.022CrossRefGoogle ScholarPubMed
Slade, P (2018) If you build it, will they eat it? Consumer preferences for plant-based and cultured meat burgers. Appetite 125, 428437.CrossRefGoogle ScholarPubMed
Ettinger, L, Falkeisen, A, Knowles, S et al. (2022) Consumer perception and acceptability of plant-based alternatives to chicken. Foods 11, 2271.10.3390/foods11152271CrossRefGoogle ScholarPubMed
Barr, SI & Chapman, GE (2002) Perceptions and practices of self-defined current vegetarian, former vegetarian, and nonvegetarian women. J Am Diet Assoc 102, 354360.CrossRefGoogle ScholarPubMed
Hoek, AC, Pearson, D, James, SW et al. (2017) Shrinking the food-print: a qualitative study into consumer perceptions, experiences and attitudes towards healthy and environmentally friendly food behaviours. Appetite 108, 117131.CrossRefGoogle ScholarPubMed
He, J, Evans, NM & Liu, H (2020) A review of research on plant-based meat alternatives: driving forces, history, manufacturing, and consumer attitudes. Compr Rev Food Sci Food Saf 19, 26392656.CrossRefGoogle ScholarPubMed
Estell, M, Hughes, J & Grafenauer, S (2021) Plant protein and plant-based meat alternatives: consumer and nutrition professional attitudes and perceptions. Sustainability 13, 118.CrossRefGoogle Scholar
Wyker, BA & Davison, KK (2010) Behavioral change theories can inform the prediction of young adults’ adoption of a plant-based diet. J Nutr Educ Behav 42, 168177.CrossRefGoogle ScholarPubMed
Neff, RA, Edwards, D, Palmer, A et al. (2018) Reducing meat consumption in the USA: a nationally representative survey of attitudes and behaviours. Public Health Nutr 21, 18351844.CrossRefGoogle Scholar
Sucapane, D, Roux, C & Sobol, K (2021) Exploring how product descriptors and packaging colors impact consumers’ perceptions of plant-based meat alternative products. Appetite 167, 105590.CrossRefGoogle ScholarPubMed
Food Standards Agency (2021) Survey of consumer perceptions of alternative, or, novel sources of protein. https://www.food.gov.uk/research/behaviour-and-perception/survey-of-consumer-perceptions-of-alternative-or-novel-sources-of-protein (accessed September 2022).Google Scholar
Mullee, A, Vermeire, L, Vanaelst, B et al. (2017) Vegetarianism and meat consumption: a comparison of attitudes and beliefs between vegetarian, semi-vegetarian, and omnivorous subjects in Belgium. Appetite 114, 299305.CrossRefGoogle ScholarPubMed
Macdiarmid, JI, Douglas, F & Campbell, J (2016) Eating like there's no tomorrow: public awareness of the environmental impact of food and reluctance to eat less meat as part of a sustainable diet. Appetite 96, 487493.CrossRefGoogle ScholarPubMed
Sanchez-Sabate, R & Sabaté, J (2019) Consumer attitudes towards environmental concerns of meat consumption: a systematic review. Int J Environ Res Public Health 16, 1220.10.3390/ijerph16071220CrossRefGoogle ScholarPubMed
Perez-Cueto, FJA (2020) Sustainability, health and consumer insights for plant-based food innovation. Int J Food Des 5, 139148.Google Scholar
De Backer, CJS & Hudders, L (2015) Meat morals: relationship between meat consumption consumer attitudes towards human and animal welfare and moral behavior. Meat Sci 99, 6874.CrossRefGoogle ScholarPubMed
Lentz, G, Connelly, S, Mirosa, M et al. (2018) Gauging attitudes and behaviours: meat consumption and potential reduction. Appetite 127, 230241.10.1016/j.appet.2018.04.015CrossRefGoogle ScholarPubMed
Fehér, A, Gazdecki, M, Véha, M et al. (2020) A comprehensive review of the benefits of and the barriers to the switch to a plant-based diet. Sustainability 12, 118.10.3390/su12104136CrossRefGoogle Scholar
Mann, D, Thornton, L, Crawford, D et al. (2018) Australian consumers’ views towards an environmentally sustainable eating pattern. Public Health Nutr 21, 27142722.CrossRefGoogle ScholarPubMed
Parry, J & Mitchell, R (2019) Assessing the general population's implicit perceptions of the plant-based food category. https://drive.google.com/open?id=1fPtX1mB4dUIVEIv8kvTBM7AUo4-GPYTb&authuser=0 (accessed September 2022).Google Scholar
Bryant, CJ (2019) We can't keep meating like this: attitudes towards vegetarian and vegan diets in the United Kingdom. Sustainability 11, 6844.CrossRefGoogle Scholar
de Boer, J, Schösler, H & Aiking, H (2017) Towards a reduced meat diet: mindset and motivation of young vegetarians, low, medium and high meat-eaters. Appetite 113, 387397.CrossRefGoogle ScholarPubMed
Lea, EJ, Crawford, D & Worsley, A (2006) Consumers’ readiness to eat a plant-based diet. Eur J Clin Nutr 60, 342351.CrossRefGoogle ScholarPubMed
Van Loo, EJ, Hoefkens, C & Verbeke, W (2017) Healthy, sustainable and plant-based eating: perceived (mis)match and involvement-based consumer segments as targets for future policy. Food Policy 69, 4657.10.1016/j.foodpol.2017.03.001CrossRefGoogle Scholar
International Food Information Council (2020) A consumer survey on plant alternatives to animal meat. https://foodinsight.org/consumer-survey-plant-alternatives-to-meat/ (accessed September 2022).Google Scholar
Grasso, S, Rondoni, A, Bari, R et al. (2022) Effect of information on consumers’ sensory evaluation of beef, plant-based and hybrid beef burgers. Food Qual Prefer 96, 104417.CrossRefGoogle Scholar
Leroy, F & Cofnas, N (2019) Should dietary guidelines recommend low red meat intake? Crit Rev Food Sci Nutr 60, 27632772.CrossRefGoogle ScholarPubMed
Wickramasinghe, K, Breda, J & Berdzuli, N (2021) The shift to plant-based diets: are we missing the point? Glob Food Sec 29, 100530.CrossRefGoogle Scholar
Prochaska, JO & Velicer, WF (1997) The transtheoretical model of health behavior change. Am J Health Promot 12, 3848.CrossRefGoogle ScholarPubMed
Rogers, EM (2003) Diffusion of Innovations. London: Simon and Schuster.Google Scholar
Li, SS, Mejia, SB, Lytvyn, L et al. (2017) Effect of plant protein on blood lipids: a systematic review and meta-analysis of randomized controlled trials. J Am Heart Assoc 6, 6659.10.1161/JAHA.117.006659CrossRefGoogle ScholarPubMed
Crimarco, A, Springfield, S, Petlura, C et al. (2020) A randomized crossover trial on the effect of plant-based compared with animal-based meat on trimethylamine-N-oxide and cardiovascular disease risk factors in generally healthy adults: study with appetizing plant food – meat eating alternative trial (SWAP-MEAT). Am J Clin Nutr 112, 11881199.CrossRefGoogle Scholar
Toribio-Mateas, MA, Bester, A & Klimenko, N (2021) Impact of plant-based meat alternatives on the gut microbiota of consumers: a real-world study. Foods 10, 126.CrossRefGoogle ScholarPubMed
Zhou, H, Hu, Y, Tan, Y et al. (2021) Digestibility and gastrointestinal fate of meat versus plant-based meat analogs: an in vitro comparison. Food Chem 364, 130439.CrossRefGoogle ScholarPubMed
Kristensen, MD, Bendsen, NT, Christensen, SM et al. (2016) Meals based on vegetable protein sources (beans and peas) are more satiating than meals based on animal protein sources (veal and pork) – a randomized cross-over meal test study. Food Nutr Res 60, 19.CrossRefGoogle ScholarPubMed
Nielsen, LV, Kristensen, MD, Klingenberg, L et al. (2018) Protein from meat or vegetable sources in meals matched for fiber content has similar effects on subjective appetite sensations and energy intake – a randomized acute cross-over meal test study. Nutrients 10, 96.CrossRefGoogle ScholarPubMed
Kahleova, H, Tintera, J, Thieme, L et al. (2021) A plant-based meal affects thalamus perfusion differently than an energy- and macronutrient-matched conventional meal in men with type 2 diabetes, overweight/obese, and healthy men: a three-group randomized crossover study. Clin Nutr 40, 18221833.CrossRefGoogle Scholar
Williamson, DA, Geiselman, PJ, Lovejoy, J et al. (2006) Effects of consuming mycoprotein, tofu or chicken upon subsequent eating behaviour, hunger and safety. Appetite 46, 41–8.CrossRefGoogle ScholarPubMed
Pham, T, Knowles, S, Bermingham, E et al. (2022) Plasma amino acid appearance and status of appetite following a single meal of red meat or a plant-based meat analog: a randomized crossover clinical trial. Curr Dev Nutr 6,nzac082.CrossRefGoogle ScholarPubMed
Neacsu, M, Fyfe, C, Horgan, G et al. (2014) Appetite control and biomarkers of satiety with vegetarian (soy) and meat-based high-protein diets for weight loss in obese men: a randomized crossover trial. Am J Clin Nutr 100, 548558.CrossRefGoogle Scholar
Klementova, M, Thieme, L, Haluzik, M et al. (2019) A plant-based meal increases gastrointestinal hormones and satiety more than an energy- and macronutrient-matched processed-meat meal in T2D, obese, and healthy men: a three-group randomized crossover study. Nutrients 11, 110.CrossRefGoogle Scholar
Salleh, SN, Fairus, AAH, Zahary, MN et al. (2019) Unravelling the effects of soluble dietary fibre supplementation on energy intake and perceived satiety in healthy adults: evidence from systematic review and meta-analysis of randomised-controlled trials. Foods 8, 15.CrossRefGoogle ScholarPubMed
Sánchez, D, Miguel, M & Aleixandre, A (2012) Dietary fiber, gut peptides, and adipocytokines. J Med Food 15, 223230.CrossRefGoogle ScholarPubMed
Grundy, MML, Edwards, CH, Mackie, AR et al. (2016) Re-evaluation of the mechanisms of dietary fibre and implications for macronutrient bioaccessibility, digestion and postprandial metabolism. Br J Nutr 116, 816833.CrossRefGoogle ScholarPubMed
Fardet, A & Rock, E (2019) Ultra-processed foods: a new holistic paradigm? Trends Food Sci Technol 93, 174184.CrossRefGoogle Scholar
Sha, L & Xiong, YL (2020) Plant protein-based alternatives of reconstructed meat: science, technology, and challenges. Trends Food Sci Technol 102, 5161.CrossRefGoogle Scholar
Srour, B & Touvier, M (2020) Processed and ultra-processed foods: coming to a health problem? Int J Food Sci Nutr 71, 653655.CrossRefGoogle ScholarPubMed
Elizabeth, L, Machado, P & Zinöcker, M (2020) Ultra-processed foods and health outcomes: a narrative review. Nutrients 12, 136.CrossRefGoogle ScholarPubMed
Monteiro, CA & Astrup, A. Does the concept of ‘ultra-processed foods’ help inform dietary guidelines, beyond conventional classification systems? YES. Am J Clin Nutr. Published online: 7 June 2022. doi: https://doi.org/101.093/ajcn/nqac122.Google Scholar
Suksatan, W, Moradi, S, Naeini, F et al. (2021) Ultra-processed food consumption and adult mortality risk: a systematic review and dose-response meta-analysis of 207,291 participants. Nutrients 14, 174.CrossRefGoogle Scholar
Derbyshire, E (2019) Are all ‘ultra-processed’ foods nutritional demons? A commentary and nutritional profiling analysis. Trends Food Sci Technol 94, 98104.CrossRefGoogle Scholar
Visioli, F, Marangoni, F, Fogliano, V et al. (2022) The ultra-processed foods hypothesis: a product processed well beyond the basic ingredients in the package. Nutr Res Rev. Published online: 22 June 2022. doi: https://doi.org/10.1017/s0954422422000117.CrossRefGoogle ScholarPubMed
Rego, RA (2022) Ultra-processed: the search of positioning from the food industry regulatory authorities. Front Nutr 9, 906561.CrossRefGoogle ScholarPubMed
Drewnowski, A, Gupta, S & Darmon, N (2020) An overlap between ‘ultraprocessed’ foods and the preexisting nutrient rich foods index? Nutr Today 55, 7581.CrossRefGoogle Scholar
Braesco, V, Souchon, I, Sauvant, P et al. (2022) Ultra-processed foods: how functional is the NOVA system? Eur J Clin Nutr 76, 12451253.CrossRefGoogle ScholarPubMed
Gibney, MJ, Forde, CG, Mullally, D et al. (2017) Ultra-processed foods in human health: a critical appraisal. Am J Clin Nutr 106, 717724.CrossRefGoogle ScholarPubMed
Curtain, F & Grafenauer, S (2019) Plant-based meat substitutes in the flexitarian age: an audit of products on supermarket shelves. Nutrients 11, 114.CrossRefGoogle ScholarPubMed
Alessandrini, R, Brown, MK, Pombo-Rodrigues, S et al. (2021) Nutritional quality of plant-based meat products available in the UK: a cross-sectional survey. Nutrients 13, 4225.CrossRefGoogle ScholarPubMed
Tonheim, LE, Austad, E, Torheim, LE et al. (2022) Plant-based meat and dairy substitutes on the Norwegian market: comparing macronutrient content in substitutes with equivalent meat and dairy products. J Nutr Sci 11, 18.CrossRefGoogle ScholarPubMed
The Norwegian Directorate of Health (2019) The keyhole – for healthier food. https://www.helsenorge.no/en/kosthold-og-ernaring/keyhole-healthy-food/.Google Scholar
Boukid, F & Castellari, M (2021) Veggie burgers in the EU market: a nutritional challenge? Eur Food Res Technol 247, 24452453.CrossRefGoogle Scholar
Pocklington, C, Hackett, M, Lamkin, A et al. (2021) Evaluating the nutritional quality of UK meat and dairy analogues compared to conventional animal products using multiple nutrient profiling models. Proc Nutr Soc 80(OCE5), E209.CrossRefGoogle Scholar
Bohrer, BM (2019) An investigation of the formulation and nutritional composition of modern meat analogue products. Food Sci Hum Wellness 8, 320329.CrossRefGoogle Scholar
Bryngelsson, S, Moshtaghian, H, Bianchi, M et al. (2022) Nutritional assessment of plant-based meat analogues on the Swedish market. Int J Food Sci Nutr 73, 889901.CrossRefGoogle ScholarPubMed
D'Alessandro, C, Pezzica, J, Bolli, C et al. (2022) Processed plant-based foods for CKD patients: good choice, but be aware. Int J Environ Res Public Health 19, 6653.CrossRefGoogle ScholarPubMed
Cole, E, Goeler-Slough, N, Cox, A et al. (2022) Examination of the nutritional composition of alternative beef burgers available in the United States. Int J Food Sci Nutr 73, 425432.CrossRefGoogle ScholarPubMed
Harnack, L, Mork, S, Valluri, S et al. (2021) Nutrient composition of a selection of plant-based ground beef alternative products available in the United States. J Acad Nutr Diet 121, 24012408.CrossRefGoogle ScholarPubMed
Swing, CJ, Thompson, TW, Guimaraes, O et al. (2021) Nutritional composition of novel plant-based meat alternatives and traditional animal-based meats. Food Sci Nutr 7, 112.Google Scholar
De Marchi, M, Costa, A, Pozza, M et al. (2021) Detailed characterization of plant-based burgers. Sci Rep 11, 19.CrossRefGoogle ScholarPubMed
Kołodziejczak, K, Onopiuk, A, Szpicer, A et al. (2021) Meat analogues in the perspective of recent scientific research: a review. Foods 11, 105.CrossRefGoogle ScholarPubMed
Pointke, M & Pawelzik, E (2022) Plant-based alternative products: are they healthy alternatives? Micro- and macronutrients and nutritional scoring. Nutrients 14, 601.CrossRefGoogle ScholarPubMed
Rizzo, G, Laganà, AS, Rapisarda, AMC et al. (2016) Vitamin B12 among vegetarians: status, assessment and supplementation. Nutrients 8, 123.CrossRefGoogle ScholarPubMed
Neufingerl, N & Eilander, A (2022) Nutrient intake and status in adults consuming plant-based diets compared to meat-eaters: a systematic review. Nutrients 14, 29.CrossRefGoogle Scholar
Craig, WJ, Mangels, AR, Fresán, U et al. (2021) The safe and effective use of plant-based diets with guidelines for health professionals. Nutrients 13, 129.CrossRefGoogle ScholarPubMed
Harnack, LJ, Reese, MM & Johnson, AJ (2022) Are plant-based meat alternative products healthier than the animal meats they mimic? Nutr Today 57, 195199.CrossRefGoogle Scholar
Public Health England (2018) UK nutrient profiling model 2018 review. https://www.gov.uk/government/consultations/consultation-on-the-uk-nutrient-profiling-model-2018-review (accessed September 2022).Google Scholar
Jones, A, Thow, AM, Ni Mhurchu, C et al. (2019) The performance and potential of the Australasian health star rating system: a four-year review using the RE-AIM framework. Aust N Z J Public Health 43, 355365.CrossRefGoogle ScholarPubMed
Aguilera, JM (2019) The food matrix: implications in processing, nutrition and health. Crit Rev Food Sci Nutr 59, 36123629.CrossRefGoogle ScholarPubMed
Lane, MM, Davis, JA, Beattie, S et al. (2021) Ultraprocessed food and chronic noncommunicable diseases: a systematic review and meta-analysis of 43 observational studies. Obes Rev 22, 119.CrossRefGoogle ScholarPubMed
Mozaffarian, D, Fahimi, S, Singh, GM et al. (2014) Global sodium consumption and death from cardiovascular causes. N Engl J Med 37, 624634.CrossRefGoogle Scholar
Monteiro, CA, Cannon, G, Levy, RB et al. (2019) Ultra-processed foods: what they are and how to identify them. Public Health Nutr 22, 936941.CrossRefGoogle Scholar
Petrus, RR, do Amaral Sobral, PJ, Tadini, CC et al. (2021) The NOVA classification system: a critical perspective in food science. Trends Food Sci Technol 116, 603608.CrossRefGoogle Scholar
Szejda, K & Parry, J (2020) Strategies to accelerate consumer adoption of plant-based meat: recommendations from a comprehensive literature review. https://gfi.org/images/uploads/2020/02/NO-HYPERLINKED-REFERENCES-FINAL-COMBINED-accelerating-consumer-adoption-of-plant-based-meat.pdf (accessed September 2022).Google Scholar
Figure 0

Table 1. Definitions of key terminology referred to in the present review

Figure 1

Fig. 1. Key factors influencing individual plant-based food choice adapted from Szejda and Parry(188).