Glutamate and glutamine content of diet

Glutamine (C₅H₁₀N₂O₃) and glutamate (C₅H₉NO₄) are important for the neutralisation of acid via α-Ketoglutaric acid (C₅H₆O₅). Glutamate is a non-essential neutralising anionic amino acid whose metabolism consumes hydrogen ions to become neutral^{(Reference Passey25,Reference Adeva and Souto27,Reference Xiao, Zeng and Yao40)} :

$${\rm C}_ 5{\rm H}_{ 10}{\rm N}_ 2{\rm O}_ 3\to {\rm C}_ 5{\rm H}_ 9{\rm N}{\rm O}_ 4\to {\rm C}_ 5{\rm H}_ 6{\rm O}_ 5^{ 2-} {\rm} + {\rm 2N}{\rm H}_ 4^{\rm + \ } $$

$${\rm C}_ 5{\rm H}_ 6{\rm O}_ 5^{ 2-} {\rm} + 2{\rm H}^{\rm + \ }\to {\rm Glucose}$$

Diet is the major source of glutamine and glutamate^{(Reference Ma, Heianza and Huang41)}, and unprocessed plant proteins are usually richer than animal proteins in glutamate^{(Reference Adeva and Souto27)}. In cross-sectional studies, meat eaters thus had a lower glutamine intake than vegetarians and vegans^{(Reference Schmidt, Rinaldi and Scalbert28)}. Another prominent example with comparable findings is the INTERMAP study, demonstrating that individuals on a high plant protein/low animal protein diet consumed greater amounts of glutamic acid as compared with their high animal protein/low plant protein counterparts^{(Reference Elliott, Stamler and Dyer42)}. A reservation must be made that this section refers to unprocessed plant foods and not to processed vegan foods enriched with artificial flavours containing monosodium glutamate.

Phosphorus content of diet

Phosphorus and preservative phosphates (phosphoric acid, polyphosphates, etc.) are other important contributors to DAL^{(Reference Kahleova, McCann and Alwarith14)}. Phosphate salts are frequently added to bacon, sausages and other processed meats for their antibacterial properties and to condition the colour and flavour of products^{(Reference Delgado-Pando, Ekonomou and Stratakos43,44)} . In addition to that, phosphate additives are frequently found in cheese manufacture and milk products^{(Reference Lucey and Fox45,Reference Seth and Bajwa46)} .

Notably, their acidity does not depend on the phosphate anion itself^{(Reference Passey25)}. Instead, it depends on the cation to which the phosphate anion is attached and the pH of the food. Phosphoric acid (H₃PO₄), commonly found in many sodas and cola drinks, is acidic as H⁺ is released upon metabolisation^{(Reference Passey25)}.

$${\rm H}_ 3{\rm P}{\rm O}_ 4\to {\rm H}^{\rm + \ }{\rm} + {\rm H}_ 2{\rm P}{\rm O}_ 4^- $$

Moreover, some of the widely used preservative phosphates and additives are acidic and some are alkaline^{(Reference Passey25)}. A frequently encountered acidic phosphate-based additive is calcium pyrophosphate (CaH₂P₂O₇)^{(Reference Passey25)}, which is frequently found in quick breads and sweet bakery products^{(Reference Calvo, Moshfegh and Tucker47)}. Trisodium phosphate (Na₃PO₄), on the other hand, is alkaline and consumes 2 H+ ions upon metabolisation.

The extra burden from phosphorus coming from processed products alone might reach up to 737 mg/d^{(Reference León, Sullivan and Sehgal48)}. Glancing at the PRAL_R formula shows that phosphorus has the highest weighting factor of all micronutrients (0⋅037)^{(Reference Remer and Manz18)}. An extra intake of 250 mg of phosphorus per day will increase PRAL by more than 9 mEq/d.

It is important to understand the extra ‘DAL burden’ subsequent to a high phosphorus intake. Milk and dairy products account for more than 24 % of phosphorus intake in human diets^{(Reference Górska-Warsewicz, Rejman and Laskowski49)}, and phosphorus intake might increase substantially when other foods abundant in phosphate (e.g. soft drinks and canned fish) are consumed^{(Reference Ritz, Hahn and Ketteler50–Reference Barzel and Massey52)}. Table 2 shows the phosphorus content of selected foods^{(Reference Barril-Cuadrado, Puchulu and Sánchez-Tomero53)}. In this context, a reservation must be made, that the intestinal absorption of phosphorus from additives used in food manufacturing is substantially higher compared with phosphorus derived from unprocessed animal-based foods. Relativisation is thus necessary when evaluating different phosphorus sources.

Table 2. Phosphorus and protein content of commonly consumed foods of plant and animal origin

Phosphorous and protein content are expressed per 100 g of uncooked food, as typically provided in nutritional content labelling.

Orange colouring: animal-based foods, green colouring: plant-based foods.

Source data adapted from^{(Reference Barril-Cuadrado, Puchulu and Sánchez-Tomero53)}.

Plant foods (vegetables, legumes and seeds), on the other hand, contain phosphorus in the form of phytate, which has a significantly lower bioavailability and neglectable acidising effects^{(Reference Kahleova, McCann and Alwarith14,Reference Ravindran, Ravindran and Sivalogan54,Reference Lott, Ockenden and Raboy55)} . Instead, most plant-based foods have alkalising effects due to their high availability of potassium salts of organic anions^{(Reference Adeva and Souto27)}.

Potassium/organic anion content of diet

As a general rule, almost all fruits and vegetables display negative PRAL values, and the amount of potassium present in those foods reflects their alkalising ability^{(Reference Passey25,Reference Remer56,Reference Remer57)} . Organic anions may be considered as virtual precursors of KHCO₃ and can be metabolised to bicarbonate^{(Reference Demigné, Sabboh and Puel1,Reference Van den Berg, Hospers and Navis58)} .

Prominent examples include citric acid, malate and potassium citrate (C₆H₅K₃O₇)^{(Reference Passey25)}. Organic salts such as potassium citrate contain base ions but no hydrogen ions. They are thus capable of binding hydrogen ions during their metabolism to carbon dioxide and water.

$${\rm C}_ 6{\rm H}_ 5{\rm K}_ 3{\rm O}_ 7\to {\rm C}_ 6{\rm H}_ 5{\rm O}_ 7^{ 3-} {\rm} + 3{\rm K}^{\rm + \ }$$

$${\rm C}_ 6{\rm H}_ 5{\rm O}_ 7^{ 3-} {\rm} + 3{\rm H}^{\rm + \ }{\rm} + 4 .5{\rm O}_ 2\to {\rm 6C}{\rm O}_ 2{\rm} + 4{\rm H}_ 2{\rm O}$$

The consumption of hydrogen ions upon metabolisation has alkalising effects^{(Reference Osuna-Padilla, Leal-Escobar and Garza-García11,Reference Adeva and Souto27)} . Except for ripened and processed grains, most plant foods contain substantial quantities of organic anions, whereas they are scarce in animal-based foods^{(Reference Demigné, Sabboh and Puel1)}. Daily food supply of organic anions strongly depends on dietary patterns and ranges from 1 g/d (in low plant consumers) to 3–4 g/d in a diversified omnivorous diet. Vegetarians and vegan usually consume more than 5 g/d of organic anions^{(Reference Demigné, Sabboh and Puel1)}. Potassium content of selected foods is presented in Table 3, based on current data from the dietary guidelines for Americans and the US Department of Agriculture^(59,60) .

Table 3. Potassium and magnesium content of selected foods per standard portion

Orange colouring: animal-based foods, green colouring: plant-based foods.

Source data adapted from^(59,60) .

Another important source of organic anions is their production in the colon, mainly short-chain fatty acids (SCFA, including butyrate, acetate and propionate)^{(Reference Demigné, Sabboh and Puel1)}. SCFA are the end-products of microbial fermentation in the distal part of the digestive tract, using specific substrates such as fibre and carbohydrates. SCFA production is closely dependent on nutritional factors and faecal levels of those metabolites correlate positively with the consumption of vegetables, fruits and legumes^{(Reference Tomova, Bukovsky and Rembert61)}. Significant increases in SCFA production have been observed when omnivores consume a diet rich in fruits and vegetables^{(Reference De Filippis, Pellegrini and Vannini62)}, and it is now widely accepted that a plant-based vegan diet may increase SCFA production by modulation of the gut microbiota^{(Reference Sakkas, Bozidis and Touzios63,Reference Losno, Sieferle and Perez-Cueto64)} .

Magnesium content of diet

Magnesium is a key micronutrient in the PRAL-formula by Remer and Manz, with a relatively high weighting factor of 0⋅026^{(Reference Remer and Manz18)}. PBDs are much more abundant in magnesium than omnivorous diets^{(Reference Koebnick, Leitzmann and García65,Reference Craig66)} , and thus have a higher PRAL-lowering capacity. A Danish study revealed that vegan men consume – on average – more than 230 mg of magnesium more than the general population^{(Reference Kristensen, Madsen and Hansen67)}, potentially translating into a PRAL-lowering capacity of more than 8 mEq/d. Magnesium content of selected foods is presented in Table 3, based on current data from the US Department of Agriculture⁽⁵⁹⁾.

Type 2 diabetes

A high DAL has been associated with insulin resistance and an increased risk for type 2 diabetes (T2DM) in various large epidemiological cohort studies, including the Teheran Lipid and Glucose Study^{(Reference Moghadam, Bahadoran and Mirmiran76)}, the Nurses’ Health Study I and II and the Health Professionals’ Follow-up Study^{(Reference Kiefte-de Jong, Li and Chen77)}. Such associations have been found in both children/adolescents^{(Reference Caferoglu, Erdal and Hatipoglu78)} and adults^{(Reference Akter, Kurotani and Kashino79)}. A high DAL is not only associated with higher fasting blood glucose levels^{(Reference Lim, Chan and Ramachandran80)} but also with impaired insulin sensitivity^{(Reference Kahleova, McCann and Alwarith14,Reference Gæde, Nielsen and Madsen81)} . Notably, a high DAL may also adversely affect other clinical outcomes in individuals with T2DM. One example is a 2020 study, that demonstrated associations between higher DAL scores and impaired sleep quality and mental health disorders in said individuals^{(Reference Daneshzad, Keshavarz and Qorbani82)}.

On the other hand, a more alkaline diet has been shown to exert protective effects^{(Reference Williams, Kozan and Samocha-Bonet13)}. The particular mechanisms underlying the association between metabolic acidosis and insulin resistance are yet to be elucidated. Apart from DAL-induced increased hepatic gluconeogenesis and disrupted binding of insulin to the insulin receptor, inhibition of insulin signalling pathways may play a crucial role^{(Reference Williams, Kozan and Samocha-Bonet13)}. These factors may play an important role when glancing at other adverse clinical outcomes related to a high DAL, including hyperlipidaemia and the increased risk for cardiometabolic disorders.

Hyperlipidaemia and cardiometabolic disorders

In 2008, Murakami et al. reported the findings of a Japanese cross-sectional study comprising 1136 female Japanese students aged 18–22 years^{(Reference Murakami, Sasaki and Takahashi83)}. The authors reported positive associations of a high DAL with higher systolic and diastolic blood pressure as well as with total and LDL-cholesterol. Associations with hypertriglyceridaemia have been reported in a cross-sectional study including 357 Iranian elderly men^{(Reference Jafari, Ghanbari and Shahinfar84)}. Increasing cortisol production caused by mild metabolic acidosis could be the underlying mechanism^{(Reference Maurer, Riesen and Muser85)}, but additional research is warranted in this poorly understood field^{(Reference Murakami, Sasaki and Takahashi83)}. Other research suggesting potential associations between a high DAL and obesity^{(Reference Arisawa, Katsuura-Kamano and Uemura86–Reference Iwase, Tanaka and Kobayashi88)}, and hypertension^{(Reference Daneshzad, Haghighatdoost and Azadbakht89,Reference Zhang, Curhan and Forman90)} – where elevated cortisol levels also play an important role – support this hypothesis. Notably, a high DAL may not only increase the risk for cardiovascular disease^{(Reference Han, Kim and Hong91–Reference Sanz, Sergi and Colombari93)} but may also affect other organs, such as the liver (in the form of non-alcoholic fatty liver disease^{(Reference Emamat, Farhadnejad and Poustchi94,Reference Alferink, Kiefte-de Jong and Erler95)} ) and the kidneys.

Renal disorders

Numerous clinical and epidemiological studies associated elevated DAL scores with incident chronic kidney disease^{(Reference Mirmiran, Yuzbashian and Bahadoran96,Reference Rebholz, Coresh and Grams97)} and end-stage renal failure risk^{(Reference Van den Berg, Hospers and Navis58)}. A high DAL may contribute to a faster decline in glomerular filtration rate (GFR)^{(Reference Scialla, Appel and Astor98,Reference Banerjee, Crews and Wesson99)} , whereas dietary alkali treatment of metabolic disease in chronic kidney disease preserves GFR and reduce kidney angiotensin-II-activity^{(Reference Goraya, Simoni and Jo100)}. Renal hyperfiltration subsequent to a high DAL^{(Reference So, Song and Lee101)} plays a crucial role in the pathogenesis of glomerular disorders and its attenuation is considered a novel therapeutic target in diabetes and obesity-induced kidney disorders^{(Reference Chagnac, Zingerman and Rozen-Zvi102)}. This again demonstrates that the effects of a high DAL are not confined to a single organ but may involve the body as a whole.

Studies on the contribution of DAL to kidney disease have gained recognition. Fruit and vegetable treatment of chronic kidney disease-related metabolic acidosis is as effective as oral NaHCO₃ when it comes to GFR preservation but reduce cardiovascular risk better than sodium bicarbonate alone^{(Reference Goraya, Munoz-Maldonado and Simoni103,Reference Goraya, Simoni and Jo104)} . A committee of experts representing the workgroup of the Kidney Disease Outcomes Quality Initiative (KDOQI) from the National Kidney Foundation, USA, has recently published recommendations for the dietary management of DAL. These are as follows:

Musculoskeletal health and body composition

An elevated acid-load burden from dietary intakes has been associated with poor musculoskeletal health^{(Reference Chan, Leung and Woo106,Reference Hayhoe, Abdelhamid and Luben107)} and impaired bone health^{(Reference Alexy, Remer and Manz108)}. Data from a Japanese study also suggest associations of increased DAL with frailty (particularly weakness and slowness) in older women^{(Reference Kataya, Murakami and Kobayashi109)}. Faure et al. reported an inverse association between PRAL and the percentage of total lean body mass among senior women in a Swiss-based population, suggesting potentially beneficial effects of a more alkaline diet in said women^{(Reference Faure, Fischer and Dawson-Hughes110)}. Their cross-sectional study essentially confirmed the findings by Welch et al., who reported a positive association of a more alkaline PRAL with fat-free mass (%) among women between 18 and 79 years, independent of physical activity and smoking^{(Reference Welch, MacGregor and Skinner111)}. Notably, much additional research is warranted in this field as a recent study associated higher acid diet measures with higher muscle strength – contrary to the common acid hypothesis^{(Reference Mohammadpour, Ghorbaninejad and Shahavandi112)}.

Mental health

With regard to mental health, positive associations were found for depression and anxiety^{(Reference Milajerdi, Hassanzadeh Keshteli and Haghighatdoost113–Reference Tessou, Lemus and Hsu115)} as well as with emotional problems and hyperactivity in children^{(Reference Bühlmeier, Harris and Koletzko116)}. Systemic inflammation subsequent to a high DAL could play an important aetiological role here, yet the reservation must be made that the involved pathological mechanisms are subject to a controversial debate.

Cancer

Elevated DAL scores have been linked to low-grade inflammation (as indicated by elevated lipid accumulation product levels)^{(Reference Jafari, Ghanbari and Shahinfar84)}. It is now widely accepted that low-grade metabolic acidosis may induce peroxidation of biological structures^{(Reference Demigné, Sabboh and Puel1)}. An altered acid–base equilibrium may also modulate molecular activity including adrenal glucocorticoid, IGF-1 and adipocyte cytokine signalling, which contribute to dysregulated cellular metabolism and may play a role in cancer development^{(Reference Robey74)}.

DAL-induced low-grade mild metabolic acidosis promote tissue damage and inflammation^{(Reference Osuna-Padilla, Leal-Escobar and Garza-García11,Reference Williams, Kozan and Samocha-Bonet13,Reference Wu, Seaver and Lemus117,Reference Storz and Ronco118)} , which may initiate genomic instability on normal cells through the activation of cytokines, which may stimulate tumour invasion and metastases^{(Reference Moellering, Black and Krishnamurty119,Reference Gillies, Pilot and Marunaka120)} . Positive associations between a high DAL and various cancers have been reported, including breast cancer^{(Reference Park, Steck and Fung121,Reference Ronco, Martinez-Lopez and Mendoza122)} , prostate cancer^{(Reference Ronco, Storz and Martínez-López123)}, lung cancer^{(Reference Ronco, Martínez-López and Calderón124)}, colorectal cancer^{(Reference Jafari Nasab, Rafiee and Bahrami125)}, pancreatic cancer^{(Reference Shi, Wu and Hu126)}, gastric cancer^{(Reference Ronco, Martínez-López and Calderón127)}, oesophageal cancer^{(Reference Ronco, Martínez-López and Calderón128)} as well as head and neck cancers^{(Reference Ronco, Martínez-López and Calderón129)}. Two meta-analyses confirmed these associations: Keramati et al. and Bahrami et al. independently found higher odds for cancer in individuals with elevated DAL scores^{(Reference Keramati, Kheirouri and Musazadeh130,Reference Bahrami, Khalesi and Ghafouri-Taleghani131)} .

Observational studies

We identified four observational studies investigating DAL scores in plant-based individuals^{(Reference Storz and Ronco12,Reference Ströhle, Waldmann and Koschizke23,Reference Deriemaeker, Aerenhouts and Hebbelinck133,Reference Knurick, Johnston and Wherry134)} . Three studies investigated lacto-ovo-vegetarians^{(Reference Storz and Ronco12,Reference Deriemaeker, Aerenhouts and Hebbelinck133,Reference Knurick, Johnston and Wherry134)} and two studies also investigated vegans^{(Reference Ströhle, Waldmann and Koschizke23,Reference Knurick, Johnston and Wherry134)} . The study characteristics may be obtained in a chronological order from Table 4. All studies found negative PRAL values in individuals consuming a plant-based diet, indicating alkalising properties. The lowest PRAL_R-values were found in a study by Ströhle et al. investigating DAL scores in German vegans (Table 4)^{(Reference Ströhle, Waldmann and Koschizke23)}. Notably, the authors used a modified PRAL_R formula and omitted calcium in their calculations.

A Belgian study by Deriemaeker et al. also found negative PRAL_R scores in vegetarians (−10⋅9 ± 19⋅7 mEq/d)^{(Reference Deriemaeker, Aerenhouts and Hebbelinck133)}, however, their diets were less alkalising as compared with the vegans in Ströhle et al. ^{(Reference Ströhle, Waldmann and Koschizke23)}. Storz et al. performed a secondary data analysis using data from the National Health and Nutrition Examination Surveys^{(Reference Storz and Ronco12)}. The authors investigated DAL scores in self-identified vegetarians who admitted to occasionally consumed animal products^{(Reference Juan, Yamini and Britten135)}. Although median PRAL_R scores were much higher than in the aforementioned studies, they were still negative (−0⋅44 (−12⋅19 to 11⋅01) mEq/d), also indicating slight alkalising properties.

Generally speaking, vegan diets were associated with lower DAL scores than lacto-ovo-vegetarian diets in all retrieved studies (Table 4). One conceivable explanation is that lacto-ovo-vegetarian diets, which build around eggs, cheese and other dairy products, are usually richer in phosphorus and preservative phosphate (phosphoric acid, polyphosphates) than vegan diets^{(Reference Müller, Zimmermann-Klemd and Lederer132,Reference D'Alessandro, Piccoli and Cupisti136)} . Preservative phosphates are characterised by higher gastrointestinal absorption rates and therefore increase the acid load burden from diet^{(Reference Scialla and Anderson137)}. We purport that this is one potential factor why vegan diets contribute lower DAL scores than vegetarian diets. An additional difference between these diets is the amino acid composition from protein sources. Protein sources in vegetarian diets include dairy products and/or eggs, which have a greater abundance of sulphur-containing amino acids compared with plant-based protein.

Several large epidemiological investigations suggested that total protein intake is lower in vegan diets as compared with lacto-ovo-vegetarian diets^{(Reference Sobiecki, Appleby and Bradbury138)}. Vegan diets are not deficient in protein but contain significantly higher amounts of plant-based protein^{(Reference Allès, Baudry and Méjean139)}. One example is the French NutriNet-Santé Study, where vegans consumed on average 12⋅7 g more plant protein per day than vegetarians (46⋅5 g/d v. 33⋅8 g/d)^{(Reference Allès, Baudry and Méjean139)}. This translates into a substantially higher intake of vegetables, fruits and legumes, which generally have alkalising effects^{(Reference Müller, Zimmermann-Klemd and Lederer132)}. The higher the fruits and vegetable intake, the higher the supply of organic anions^{(Reference Demigné, Sabboh and Puel1)} and thus the higher the alkalising effect of the diet. A reservation must be made, that the protein intake difference between vegans and vegetarians reported in other studies^{(Reference Orlich and Fraser140)} was not as pronounced, possibly due to geographical and socioeconomic factors known to influence nutrition.

Clinical intervention studies

We also identified several clinical intervention studies that investigated the effects of various PBDs on DAL management^{(Reference Kahleova, McCann and Alwarith14,Reference Cosgrove and Johnston32,Reference Müller, Zimmermann-Klemd and Lederer132)} (Table 5). However, in light of the low number of studies in this field, and with regard to the high heterogeneity in diet composition and study designs, we refrained from performing a meta-analysis.

Cosgrove and Johnston examined the impact of adherence to a vegan diet on acid–base balance in health adults^{(Reference Cosgrove and Johnston32)}. In a randomised-controlled trial, they compared three different diets: a vegan diet for 2 d over 1 week (VEG2), a vegan diet for 3 d over 1 week (VEG3), and a vegan diet for 7 consecutive days (VEG7). With regard to the PRAL-lowering effect, the VEG7 diet performed best. After seven consecutive days on a strict vegan diet, mean PRAL values fell substantially from 23⋅7 ± 17⋅7 to −6⋅0 ± 12⋅8 mEq/d. Again, a strict vegan diet yielded alkalising effects. The effect of the other two dietary interventions (VEG2 and VEG3) was less pronounced.

Our group performed a secondary data analysis of a randomised-controlled trial where 45 omnivorous individuals were randomly assigned to either a vegan diet (n 23) or a meat-rich diet (n 22) for 4 weeks^{(Reference Müller, Zimmermann-Klemd and Lederer132)}. After 3 weeks, PRAL_R scores fell from −5⋅26 ± 4⋅45 to −23⋅57 (23⋅87) mEq/d in vegans. Comparable values were observed in week 4. Notably, the control group comprised individuals on a meat-rich diet, which demonstrated a significant increase in their DAL scores. PRAL_R scores rose from 3⋅26 ± 17⋅91 to 18⋅78 (21⋅04) mEq/d in individuals on a meat-rich diet. The isocaloric nature of the vegan diet (participants were instructed to avoid weight loss due to a decreased energy intake) deserves special consideration in this context and might have led to underestimations of the PRAL-lowering effect of vegan diets.

Another important study in the field has been conducted by Kahleova et al. in 2021^{(Reference Kahleova, McCann and Alwarith14)}. The authors performed a post-hoc analysis of a low-fat vegan dietary intervention that restricted processed foods and reduced fat intake to approximately 10 % of total energy. This diet included grains, legumes, vegetables and fruits and was characterised by a targeted macronutrient distribution of approximately 75 % of energy from carbohydrates, 15 % protein and 10 % fat. After 4 months, median PRAL_R scores and NEAP_F scores dropped significantly in the vegan group (−24⋅3 (−28 to −20⋅5) mEq/d and −25⋅1 (−29⋅1 to −21⋅1) mEq/d, respectively), whereas both scores remained almost identical in the control group (Table 4).

A vegan diet significantly reduced DAL scores in all three studies, however, results from these studies also suggest that dietary adherence is a crucial factor. The simple implementation of one or two ‘vegan days’ per week may be insufficient to achieve an alkalising diet.