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Postprandial plasma amino acid and appetite responses with ingestion of a novel salmon-derived protein peptide in healthy young adults

Published online by Cambridge University Press:  29 February 2024

Sophie Prosser ,
Mia Fava ,
Lucy M. Rogers ,
Bjørn Liaset  and
Leigh Breen Open the ORCID record for Leigh Breen [Opens in a new window]
Sophie Prosser
Affiliation:
School of Sport, Exercise and Rehabilitation Sciences, University of Birmingham, Birmingham B15 2TT, UK
Mia Fava
Affiliation:
School of Sport, Exercise and Rehabilitation Sciences, University of Birmingham, Birmingham B15 2TT, UK
Lucy M. Rogers
Affiliation:
School of Sport, Exercise and Rehabilitation Sciences, University of Birmingham, Birmingham B15 2TT, UK
Bjørn Liaset
Affiliation:
Biomega Group AS, Bergen, Norway
Leigh Breen*
Affiliation:
School of Sport, Exercise and Rehabilitation Sciences, University of Birmingham, Birmingham B15 2TT, UK MRC-Versus Arthritis Centre for Musculoskeletal Ageing Research, University of Birmingham, Birmingham, UK NIHR Biomedical Research Centre, Birmingham, UK
*
*Corresponding author: Leigh Breen, email l.breen@bham.ac.UK
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Abstract

This study assessed postprandial plasma aminoacidemia, glycemia, insulinemia and appetite responses to ingestion of a novel salmon-derived protein peptide (Salmon PP) compared with milk protein isolate (Milk PI). In a randomised, participant-blind crossover design, eleven healthy adults (M = 5, F = 6; mean ± sd age: 22 ± 3 years; BMI: 24 ± 3 kg/m2) ingested 0·3 g/kg/body mass of Salmon PP or Milk PI. Arterialised blood samples were collected whilst fasted and over a 240-min postprandial period. Appetite sensations were measured via visual analogue scales. An ad libitum buffet-style test meal was administered after each trial. The incremental AUC (iAUC) plasma essential amino acid (EAA) response was similar between Salmon PP and Milk PI. The iAUC plasma leucine response was significantly greater following Milk PI ingestion (P < 0·001), whereas temporal and iAUC plasma total amino acid (P = 0·001), non-essential amino acid (P = 0·002), glycine (P = 0·0025) and hydroxyproline (P < 0·001) responses were greater following Salmon PP ingestion. Plasma insulin increased similarly above post-absorptive values following Salmon PP and Milk PI ingestion, whilst plasma glucose was largely unaltered. Indices of appetite were similarly altered following Salmon PP and Milk PI ingestion, and total energy and macronutrient intake during the ad libitum meal was similar between Salmon PP and Milk PI. The postprandial plasma EAA, glycine, proline and hydroxyproline response to Salmon PP ingestion suggest this novel protein source could support muscle and possibly connective tissue adaptive remodelling, which warrants further investigation, particularly as the plasma leucine response to Salmon PP ingestion was inferior to Milk PI.

Keywords

Marine proteinRaw materialsPeptidesBioavailabilityEnergy intake
Type
Research Article
Information
British Journal of Nutrition , First View , pp. 1 - 13
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Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
The Author(s), 2024. Published by Cambridge University Press on behalf of the Nutrition Society

The intake of dietary protein increases rates of muscle protein synthesis (MPS)(Reference Biolo, Tipton and Klein1,Reference Rennie, Edwards and Halliday2) . The muscle anabolic response to protein ingestion is largely attributable to the postprandial rise in circulating essential amino acid (EAA) concentrations(Reference Tipton, Gurkin and Matin3,Reference Bohe, Low and Wolfe4) , particularly the branched-chain amino acid, leucine, as both signal and substrate for this process(Reference Rieu, Balage and Sornet5Reference Churchward-Venne, Breen and Di Donato7). Importantly, plasma aminoacidemia following protein ingestion is contingent on the constituent amino acid profile and digestive properties(Reference Gorissen, Trommelen and Kouw8). Combined, these characteristics are thought to underpin the ‘quality’ and muscle anabolic properties of a protein source(Reference Morgan, Harris and Marshall9Reference Boirie, Dangin and Gachon12), with implications for those seeking to optimise muscle adaptive remodelling (e.g. with exercise training). Typically, animal-derived proteins contain a higher proportion of EAA and display higher rates of digestibility than most plant-based proteins(Reference Pinckaers, Trommelen and Snijders13). However, there is a growing demand for alternative animal-derived proteins that are environmentally sustainable and efficacious for muscle anabolism(Reference Burd, McKenna and Salvador14,Reference Beal, Gardner and Herrero15) .

Fish is one of the largest global proteins consumed by humans, with over 184·6 million metric tons consumed in 2022 alone(16). Whilst fish constitutes about 17 % of global meat consumption, > 60 % of products produced from fish farms are discarded as waste(Reference Chalamaiah, Dinesh Kumar and Hemalatha17,Reference Coppola, Lauritano and Palma Esposito18) . Advances in food processing technology have made it possible to upcycle fish rest raw materials (e.g. heads, trimmings, skin, scales and backbones) into high-quality protein products and bioactive peptides for human consumption, which is both environmentally sustainable and economically efficient(Reference Coppola, Lauritano and Palma Esposito18). The content and plasma availability of EAA from fish-derived protein could support muscle anabolic processes. It was recently shown that the ingestion of a Nile tilapia-derived protein hydrolysate elicited similar plasma aminoacidaemia to a whey protein hydrolysate in young individuals following exercise(Reference Cordeiro, de Oliveira and Volino-Souza19). Furthermore, ex vivo treatment of myotubes with plasma obtained after blue whiting-derived protein hydrolysate and whey protein isolate ingestion evoked similar MPS stimulation(Reference Lees, Nolan and Amigo-Benavent20). In addition to potential muscle anabolic properties, fish by-products are typically rich in connective tissue and contain a significant amount of collagen(Reference Rajabimashhadi, Gallo and Salvatore21Reference Dave, Lu and Clalrk23). Collagen is rich in glycine, proline and hydroxyproline, which have purported benefits for connective tissue remodelling(Reference Holwerda and van Loon24,Reference Shaw, Lee-Barthel and Ross25) . However, the processing of raw fish rest materials and the subsequent recovery and production of protein varies considerably(Reference Elavarasan and Shamasundar26Reference Shahid, Srivastava and Sillanpää28) and influences the digestion and absorption properties of these products and their subsequent biological impact on human tissues. Hence, characterising the blood amino acid profile of emerging fish-derived proteins and peptides is crucial to understand their potential to support human muscle and connective tissue remodelling. Finally, given that the rise in circulating amino acids following protein ingestion may have implications for hunger and satiety, it is possible that the ingested protein source may influence these outcomes(Reference Braden, Gwin and Leidy29). As such, it is important to characterise the influence of novel fish-derived proteins on indices of appetite regulation and energy intake.

The present study aimed to assess postprandial plasma aminoacidemia following the ingestion of a novel salmon-derived protein peptide (Salmon PP), compared with a high-quality reference milk protein isolate (Milk PI). Given the potential for dietary protein ingestion to influence satiety(Reference Booth, Chase and Campbell30), we also determined the effect of Salmon PP and Milk PI on subjective indices of appetite regulation, subsequent meal energy intake and plasma insulin and glucose concentrations. We hypothesised that total and non-essential aminoacidemia would be greater in Salmon PP compared with Milk PI. Despite a lower content of EAA and leucine in Salmon PP compared with Milk PI, we hypothesised that the structural properties of Salmon PP would result in comparable essential aminoacidemia and leucinemia between supplements. Finally, we postulated that postprandial changes in appetite regulation, ad libitum energy intake and insulin and glucose would be similar between Salmon PP and Milk PI.

Methods

Participants

Five male and six female young healthy individuals volunteered to participate in this study (participant characteristics are presented in Table 1). Briefly, prospective participants were excluded based on the following criteria: aged < 18 or > 40 years, BMI < 18·5 or > 29·9 kg/m2, metabolic or respiratory disease or chronic illness, habitual smoker, known allergies or intolerances to study materials and supplements, and use of medications known to affect muscle protein metabolism. Participants were informed of the study purpose, experimental procedures and potential risks associated with participating before they provided written informed consent. Participants were not informed that ad libitum energy intake would be assessed as part of this study, since knowledge of this measurement may have influenced dietary behaviours. Instructions given to participants prior to the ad libitum buffet are described below. Ethical approval was obtained by the Science, Technology, Engineering and Mathematics Ethical Review Committee at the University of Birmingham (ERN_21-1508A), and all procedures were conducted in accordance with the Declaration of Helsinki (7th edition).

Table 1. Participant characteristics

Study design

The present study followed a randomised, participant-blind, crossover design with counterbalancing, where participants completed one preliminary visit and two experimental trials at the School of Sport, Exercise and Rehabilitation Science laboratories, University of Birmingham. The preliminary visit was conducted at least 1 week prior to the first experimental trial and involved eligibility screening, height and mass measurements, and completion of a general health history questionnaire. For each experimental trial, separated by at least 5 d, participants were asked to ingest 0·3 g/kg/body mass of Salmon PP or Milk PI. Trial order was randomised and counterbalanced between participants, to minimise any effect of trial order on study outcomes. The influence of trial order on subjective appetite perceptions and ad libitum energy intake confirms no influence of trial order in these outcomes. Following supplement ingestion, participants rested in the laboratory for repeat blood sampling and appetite sensation measurements over 4 hours, before consuming an ad libitum test meal. A schematic overview of the experimental design is presented in Fig. 1.

Fig. 1. Schematic of experimental trials. Trials were separated by > 5 d and involved ingestion of 0·3 g/kg/body mass salmon-derived peptide protein (Salmon PP) or milk protein isolate (Milk PI), arterialised blood sampling over 4 h and a buffet-style test meal for the assessment of ad libitum energy intake. VAS, visual analogue scales.

Diet and physical activity

One week prior to the first experimental trial, participants were instructed to complete self-report weighed food diaries for the assessment of habitual macronutrient and energy intake. Further, 24 h prior to the first experimental trial, participants were instructed to complete an additional food diary and a physical activity diary. Participants were asked to replicate these diary entries 24 h prior to the second and third experimental trials. Participants were also provided with a standardised food package for consumption on the evening before each experimental trial (413 kcal, about 56 % carbohydrate, about 22 % protein and about 22 % fat). To minimise intraindividual variability in physical activity on the morning of each experimental trial, participants were asked to record their means of commuting to the laboratory for their first trial and replicate this on the mornings of their subsequent experimental trials.

Experimental protocol

Participants arrived at the laboratory at about 07.00 h after an overnight fast having refrained from strenuous physical activity and abstained from alcohol consumption for the preceding 24 h period. Upon arrival, body mass and height were measured, and body composition was assessed via Bioelectrical Impedance Analysis (TANITA SC-331S). Participants then rested in a semi-recumbent position with their forearm placed under a heated blanket to arterialise venous blood. After 10 min, a cannula (BD VenflonTM) connected to a three-way stopcock (BD ConnectaTM) was inserted antegrade into an antecubital forearm vein and 15 ml of blood sample was drawn. The cannula was then flushed with 5 ml of sterile NaCl 0·9 % (BD PosiFlushTM) to maintain patency for repeated blood sampling (repeated at each blood sample). The blood sampled arm was warmed in a heated blanket to ensure blood samples were arterialised(Reference Abumrad, Rabin and Diamond31). Participants were then asked to complete a series of 0–100 mm visual analogue scales to assess fasted-state appetite sensations(Reference Flint, Raben and Blundell32): participants marked a line through the 100 mm scale to reflect how they felt in relation to the questions at the time of assessment. Three questions from this scale: ‘How hungry do you feel?’, ‘How full do you feel?’ and ‘How satisfied do you feel?’ were used. Following this, participants ingested 0·3 g/kg/body mass of Salmon PP or Milk PI, according to trial order randomisation (described below). Upon consumption a timer was started, where participants were asked to consume the beverage within 3 min. To ensure all residual protein was consumed, beverage containers were rinsed with a further 200 ml which participants also consumed. Blood samples were drawn every 15 min during the first hour, and every 30 min thereafter for the 4 h postprandial period. Appetite sensations were assessed via visual analogue scales at 5 min, 30 min and then hourly following protein ingestion for the remainder of the trial. At the hourly sampling time points, visual analogue scales were completed prior to arterialised blood sampling. Water intake was permitted ad libitum during the first 4 h trial and was recorded to ensure replication on subsequent trials. The cannula was removed following the 4-h postprandial period and a buffet-style test meal was administered to assess ad libitum energy intake, after which the trial was ceased. Participants later returned to the laboratory to complete a further experimental trial, which was identical, except for the type of protein supplement they were asked to consume. At the end of this final trial, participants completed an exit questionnaire to determine the success of blinding to trial order. No adverse events were experienced by participants in either experimental treatment trial.

Supplemental beverages

The nutritional composition of the protein supplemental beverages is displayed in Table 2. Beverages were volume-matched and contained similar energy, carbohydrate, fat, and fibre. The Milk PI protein was obtained from MyproteinTM and contained about 81 g of protein per 100 g. The Salmon PP was SalMe Peptides and contained about 93·5 g of protein per 100 g. Salmon PP was made from food grade salmon raw materials, with the use of commercial food grade, non-GMO proteases in a patented process at Biomega Norway AS. After enzymatic hydrolysis, all fractions were heated to > 85°C before the water-soluble content was separated from the fat and the non-soluble fractions by centrifugal force. Thereafter, the water-soluble fraction was ultra- and nano-filtered. The retentate from the nanofiltration was further concentrated in an evaporator, before being spray-dried. The final product consisted of a mixture of peptides and free amino acids, as well as other water-soluble nutrients. Participants ingested 0·3 g/kg/body mass of protein Salmon PP or Milk PI, which equated to 22·0 ± 4·9 g (range 16·2–30·1 g) of protein for both treatments, or 23·6 ± 5·3 g and 27·2 ± 6·1 g of supplement material for Salmon PP and Milk PI, respectively. Both supplements were unflavoured, but participants were permitted a choice of strawberry, vanilla or raspberry flavour drops (Myprotein) to add to each beverage to improve palatability and promote taste-matching between Salmon PP and Milk PI (same flavour was used in both trials). Supplements were dissolved in 300 ml of cold water and the resultant beverage served in identical opaque black shaker bottles to ensure participants were blind to beverage appearance. The energy content of Milk PI and Salmon PP supplements was determined independently by bomb calorimetry (Milk PI; Impact Solutions, Livingstone, Scotland, Salmon PP; Eurofins Food and Feed, Trondheim, Norway).

Table 2. Supplement composition

n.d, none detected; ∑ TAA, summed total of total amino acids; ∑ EAA, summed total of essential amino acids; ∑ NEAA, summed total of non-essential amino acids. Bold font highlights summed totals from the data presented in normal font.

Blood sampling and analysis

Arterialised blood samples were collected into tubes containing anti-coagulant K2EDTA (BD Vacutainer®) and were placed on ice for 30 min before centrifugation at 4000 g for 10 min at 4°C. Plasma was aliquoted in duplicate and immediately transferred to −80°C for storage until further analysis. Analysis of plasma amino acid concentrations was conducted using EZ: faast procedure according to the manufacturer’s instructions. In brief, 50 μl of plasma was combined with 50 μl of EZ: faast internal AA standard and 50 μl of DDH2O in a sample preparation vial. Samples were transferred slowly (1 min) through a sorbent tip attached to a 1·5 ml syringe. Then, 200 μl of wash solution (1-propanol and H2O) was added to sample preparation vials and transferred slowly through the sorbent tips into the syringe barrel. Liquid accumulated in the syringe barrel was then discarded. Then, 200 μl of freshly prepared elution medium (a NaOH-based solution) was added to the sample preparation vial. Using a 0·6 ml syringe, the eluting medium was transferred slowly through sorbent particles to the filter plug in the sorbent tip. After, the liquid and particles were ejected from the syringe into the sample preparation vial; this step repeated further two times. Then, 50 ml of derivatisation solution (a mixture of CHCl3, 2, 2, 4 trimethylpentane and propylchloroformate) was added to the sample preparation vial and vortexed for 10 s to emulsify. To separate the emulsion into two layers, 100 µl of acid solution (HCl-based) was added. The upper layer (containing derivatised AA) was transferred to an autosampler vial and analysed via Gas Chromatography (Agilent 6890W) fitted with a Flame Ionization Detector.

Plasma glucose concentrations were measured in duplicate using an automated analyser (Rx Daytona, Randox Laboratories). Plasma concentrations of insulin were measured in duplicate using ELISA kits (Mercodia), according to manufacturer instructions, where all samples for a participant were measured on the same plate or run.

Energy intake

Within-laboratory energy intake was assessed at each trial by provision of a buffet-style ad libitum test meal comprising water, cornflakes, semi-skimmed milk, white bread, margarine, raspberry jam, strawberry yogurt pot, bananas, apples, breakfast bars, scotch pancakes, baked beans, Cheddar cheese and porridge. To prevent any influence of external cues on eating behaviour, participants consumed the meal in isolation and were instructed to refrain from using their mobile phones throughout. Participants were instructed to ‘help themselves to the food items’ and to ‘eat as much or as little’ as they liked until comfortably full. Food items were weighed by the researcher before and after the test meal, and the weighted difference in food was recorded. Water intake was permitted ad libitum during the test meal. Both within-laboratory and habitual energy intakes were calculated from self-reported diet diaries using the following energetic values for each macronutrient: carbohydrate 3·75 kcal/g, fat 8·94 kcal/g and protein 4·02 kcal/g (Elia & Cummings, 2007).

Statistical analysis

A minimum sample size of 11 was calculated in order to detect an effect size of 0·95 with 80 % power (G * Power 3.1.9.7), based on the effect size in similar studies of postprandial aminoacidemia with ingestion of supplemental protein sources in healthy young individuals(Reference Burke, Winter and Cameron-Smith33Reference Alcock, Shaw and Tee35). Descriptive statistics were calculated using Microsoft Excel. Incremental AUC (iAUC) for postprandial metabolite and hormonal responses were calculated with the trapezoid method using the Time Series Response Analyser (Narang et al., 2020). Figures were produced and statistical analysis was performed in GraphPad Prism, where statistical significance was accepted at P ≤ 0·05. Time-dependent variables were analysed using two-way repeated-measures ANOVA, or mixed-effects models (depending on missing data points) with post hoc Bonferroni correction. Time-independent variables were analysed using one-way repeated-measures ANOVA, or mixed-effects models (depending on missing data points) with post hoc Bonferroni correction. Data are presented as mean ± sd for tables and mean ± sem for figures.

Results

Standardisation and blinding

Protein beverages were correctly identified on 54 % of occasions, where five of eleven participants failed to identify a single beverage correctly. Trial order was correctly identified by only six of eleven participants. The Salmon PP beverage was correctly identified on six occasions and the Milk PI beverage on six occasions.

Plasma glucose and insulin concentrations

Plasma glucose concentrations were modestly altered following protein ingestion (time effect; P = 0·0123: Fig. 2(a)). Plasma glucose concentration was increased above post-absorptive values at 15 min following Salmon PP ingestion only (P = 0·0123). There were no statistically significant differences in plasma glucose concentrations between Salmon PP and Milk PI at any time point (trial effect: P = 0·992; interaction effect: P = 0·918). Plasma insulin concentrations increased following protein ingestion (time effect; P < 0·001: Fig. 2(b)). Plasma insulin concentrations were increased above post-absorptive values at 30 and 60 min after ingestion of Salmon PP and Milk PI (P < 0·05 for all), returning to post-absorptive values by 90 min post-ingestion. There were no significant differences in plasma insulin concentration between Salmon PP and Milk PI at any time point (trial effect: P = 0·607; interaction effect: P = 0·664).

Fig. 2. Postprandial plasma insulin (a) and glucose (b) concentrations following ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey) in young healthy adults. n 11. Data are presented as mean ± sem. *A statistically significant difference from 0-min fasted-state time point for both groups (P < 0·05). #A statistically significant difference from 0-min fasted-state time point for Salmon PP only (P < 0·05).

Plasma total, essential and non-essential amino acid concentrations

Plasma total amino acid (TAA) concentrations increased following protein ingestion (time effect: P < 0·001; Fig. 3(a)), with a main effect of trial and an interaction effect detected (P < 0·001 for both). Plasma TAA concentrations were increased above post-absorptive values from 15 to 120 min following ingestion of Salmon PP and Milk PI (P < 0·05 for all) and 150 min following ingestion of Salmon PP only (P = 0·021). Plasma TAA concentrations were significantly greater following Salmon PP compared with Milk PI at 30, 45, 60 and 90 min post-ingestion (P < 0·05 for all). Peak TAA concentration was significantly greater for SPI compared with Milk PI (4841 ± 237 v. 3755 ± 159 μmol/l, respectively; P = 0·0017). Time-to-peak TAA concentration did not differ between Salmon PP and Milk PI (46·4 ± 3·6 v. 54·6 ± 5·96 min, respectively; P = 0·17). A significant main effect of trial was detected for plasma TAA iAUC over the 240-min postprandial phase, which was greater in Salmon PP compared with Milk PI (P = 0·001; Fig. 3(b)).

Fig. 3. Postprandial plasma amino acid responses to ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey) in young healthy adults. Time course and incremental AUC (iAUC) of plasma total amino acids (TAA; a, b), non-essential amino acids (NEAA; c, d), essential amino acids (EAA; e, f) and leucine (g, h) concentrations for n 11. Data are presented as mean ± sem and individual values. A statistically significant difference between Salmon PP and Milk PI (P < 0·05). *A statistically significant difference from 0-min fasted-state time point for both groups (P < 0·05). #A statistically significant difference from 0-min fasted-state time point for Salmon PP only (P < 0·05). $A statistically significant difference from 0-min fasted-state time point for Milk PI only (P < 0·05). EAA is the sum of histidine, threonine, lysine, methionine, valine, isoleucine, leucine and phenylalanine. NEAA is the sum of alanine, arginine, asparagine, citrulline, cysteine, glutamine, glutamic acid, glycine, ornithine, proline, taurine and tyrosine. iAUC, incremental AUC.

Plasma non-essential amino acid (NEAA) concentrations increased following protein ingestion (time effect: P < 0·001; Fig. 3(c)), with a main effect of trial (P < 0·0029) and an interaction effect detected (P < 0·001 for both). Plasma NEAA concentrations were increased above post-absorptive values from 15 to 120 min following ingestion of Salmon PP (P < 0·001 for all), whereas plasma NEAA concentrations were increased above post-absorptive values at 30–90 min post-ingestion of Milk PI (P < 0·05 for both). Plasma NEAA concentrations were significantly greater following Salmon PP compared with Milk PI at 15–120 min post-ingestion (P < 0·05 for all). Peak NEAA concentration was significantly greater for Salmon PP compared with Milk PI (3441 ± 189 v. 2403 ± 143 μmol/l, respectively; P = 0·0010). Time-to-peak TAA concentration did not differ between Salmon PP and Milk PI (45·0 ± 3·5 v. 53·2 ± 6·7 min, respectively; P = 0·258). A significant main effect of trial was detected for plasma NEAA iAUC over the 240-min postprandial phase, which was greater in Salmon PP compared with Milk PI (P < 0·001; Fig. 3(d)).

Plasma EAA concentrations increased following protein ingestion (time effect: P < 0·001; Fig. 3(e)), with no significant differences between trials (trial effect: P = 0·525; interaction effect: P = 0·770. Plasma EAA concentrations were increased above post-absorptive values from 15 to 150 min following ingestion of Salmon PP and Milk PI (P < 0·05 for all). Peak EAA concentration was not significantly different between Salmon PP and Milk PI (1466 ± 90 v. 1430 ± 41 μmol/l, respectively; P = 0·588). Time-to-peak EAA concentration was not significantly different between Salmon PP and Milk PI (50·5 ± 7·1 v. 51·8 ± 4·6 min, respectively; P = 0·870). Plasma EAA iAUC over the 240-min postprandial phase was not significantly different between Salmon PP and Milk PI (P = 0·912; Fig. 3(f)).

Plasma leucine concentrations increased following protein ingestion (time effect: P < 0·001; Fig. 3(g)), with a main effect of trial (P = 0·0124) and an interaction effect detected (P < 0·001). Plasma leucine concentrations were increased above post-absorptive values from 15 to 150 min following ingestion of Milk PI (P < 0·05 for all), whereas plasma leucine was increased from 15 to 60 min post-ingestion of Salmon PP (P < 0·05 for all). Plasma leucine concentrations were significantly greater following Milk PI compared with Salmon PP at 60–150 min post-ingestion (P < 0·05 for all). Peak leucine concentration was not significantly different between Salmon PP and Milk PI (264 ± 14 v. 273 ± 10 μmol/l, respectively; P = 0·525). Time-to-peak leucine concentration was significantly different between Salmon PP and Milk PI (34·1 ± 3·0 v. 51·8 ± 5·6 min, respectively; P = 0·011). A significant main effect of trial was detected for plasma leucine iAUC, which was greater in Milk PI compared with Salmon PP (P < 0·001; Fig. 3(h)).

Plasma glycine proline and hydroxyproline concentrations

Plasma glycine concentrations increased following protein ingestion (time effect: P < 0·001; Fig. 4(a)), with a main effect of trial (P < 0·001) and an interaction effect detected (P < 0·001). Plasma glycine concentrations were increased above post-absorptive values from 15 to 90 min following ingestion of Salmon PP (P < 0·05 for all), whereas plasma glycine was increased only at 60 min post-ingestion of Milk PI (P = 0·0475). Plasma glycine concentrations were significantly greater following Salmon PP compared with Milk PI from 30 to 150 min post-ingestion (P < 0·05 for all). Peak glycine concentration was significantly greater for Salmon PP compared with Milk PI (479 ± 45 v. 281 ± 15 μmol/l, respectively; P = 0016). Time-to-peak glycine concentration did not differ between Salmon PP and Milk PI (47·7 ± 2·0 v. 49·1 ± 5·1 min, respectively; P = 0·724). A significant main effect of trial was detected for plasma glycine iAUC, which was greater in Salmon PP compared with Milk PI (P = 0·0025; Fig. 4(b)).

Fig. 4. Postprandial plasma amino acid responses to ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey) in young healthy adults. Time course and incremental AUC (iAUC) of plasma glycine (a), (b), hydroxyproline (c), (d) and proline (e), (f) concentrations for n 11 (n 10 for proline iAUC due to missing data for one participant). Data are presented as mean ± sem and individual values. †A statistically significant difference between Salmon PP and Milk PI (P < 0·05).

Plasma hydroxyproline concentrations increased following protein ingestion (time effect: P < 0·001; Fig. 4(c)), with a main effect of trial and an interaction effect detected (P < 0·001 for both). Plasma hydroxyproline concentrations were increased above post-absorptive values from 30 to 240 min following ingestion of Salmon PP (P < 0·001 for all), whereas plasma hydroxyproline was increased at 45 min post-ingestion of Milk PI (P = 0·044). Plasma hydroxyproline concentrations were significantly greater following Salmon PP compared with Milk PI at 30–240 min post-ingestion (P < 0·01 for all). Peak hydroxyproline concentration was significantly greater for Salmon PP compared with Milk PI (74·9 ± 6·6 v. 28·3 ± 2·6 μmol/l, respectively; P < 0·001). Time-to-peak plasma hydroxyproline concentration did not differ between Salmon PP and Milk PI (68·2 ± 9·3 v. 55·0 ± 3·5 min, respectively; P = 0·563). A significant main effect of trial was detected for plasma hydroxyproline iAUC, which was greater in Salmon PP compared with Milk PI (P < 0·001; Fig. 4(d)).

Plasma proline concentrations increased following protein ingestion (time effect: P < 0·001; Fig. 4(e)), with a main effect of trial (P = 0·0412) and an interaction effect (P = 0·001) detected. Plasma proline concentrations were increased above post-absorptive values from 15 to 120 min following ingestion of Salmon PP (P < 0·05 for all) and from 15 to 150 min post-ingestion of Milk PI (P < 0·05 for all). Plasma proline concentrations were significantly greater following Salmon PP compared with Milk PI from 30–60 min post-ingestion (P < 0·05 for all). Peak proline concentration was significantly greater for Salmon PP compared with Milk PI (469 ± 29 v. 335 ± 25 μmol/l, respectively; P < 0·001). Time-to-peak plasma proline concentration did not differ between Salmon PP and Milk PI (40·9 ± 4·4 v. 49·1 ± 5·01 min, respectively; P = 0·192). Plasma proline iAUC over the 240-min postprandial phase was not significantly different between Salmon PP and Milk PI (P = 0·401; Fig. 4(f)).

Appetite and energy intake

Total energy, relative macronutrient intake and water intake over 24 h prior to Salmon PP and Milk PI trials was similar and did not differ from habitual values (Table 3), with the exception of water intake being lower in Salmon PP compared with habitual values (P = 0·032). Subjective ratings of post-absorptive and postprandial appetite sensations during Salmon PP and Milk PI trials are displayed in Fig. 5(a)–(c). There were no significant differences in the ratings of fullness, hunger or satisfaction between Salmon PP and Milk PI at any time point. Fullness increased above fasted values at 5 and 30 min post-protein for Salmon PP and Milk PI (P < 0·05 at all time points for both) and decreased below fasted values at 240 min post-protein (P = 0·017 and 0·010 for Salmon PP and Milk PI, respectively). Hunger increased above fasted values at 180 and 240 min post-protein for Salmon PP (P < 0·001 at both time points) and 120–240 min post-protein for Milk PI (P < 0·001 at all time points). Satisfaction increased above fasted values at 5 min post-protein for Salmon PP and Milk PI (P = 0·024 and 0·007, respectively) and decreased below fasted values at 180 and 240 min post-protein for Salmon PP (P = 0·028 and 0·034, respectively) and only 240 min post-protein for Milk PI (P = 0·013). Fullness, hunger and satisfaction iAUC were not significantly different between trials (P > 0·05 for all, data not reported). Ad libitum energy intake during the buffet-style breakfast meal did not differ between trials (Fig. 5(d); P = 0·910), nor did the relative consumption of carbohydrate, fat or protein (P > 0·05 for all; Table 3 and Fig. 5(e)). Trial order did not affect temporal or composite ratings of fullness, hunger or satisfaction (P > 0·05 for all), nor did trial order affect ad libitum energy intake with the breakfast meal (P = 0·673).

Table 3. Dietary intake analysis

Salmon PP, Salmon-derived peptide protein; Milk PI, milk protein isolate.

Data are presented as mean ± sd. Intake of macronutrients is expressed relative to participant body mass. A statistically significant difference in dietary variable from habitual values (P < 0·05).

Fig. 5. Postprandial perceptions of fullness (a), hunger (b) and satisfaction (c) following ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey), and ad libitum total energy (d) and macronutrient (e) intake at the breakfast test meal (consumed 240 mins after Salmon PP/Milk PI ingestion) in young healthy adults for n 11. Data are presented as mean ± sem and individual values (for breakfast energy intake only). *A statistically significant difference from 0-min fasted-state time point (P < 0·05). #A statistically significant difference from 0-min fasted-state time point for Salmon PP only (P < 0·05). $A statistically significant difference from 0-min fasted-state time point for Milk PI only (P < 0·05). VAS, visual analogue scales.

No adverse events were reported during the trial.

Discussion

The present study is the first to characterise the blood amino acid and appetite response to a novel protein peptide derived from salmon by-products (Salmon PP) in young healthy adults. Our findings show that ingestion of 0·3 g/kg/body mass of protein from Salmon PP, sufficient for maximal postprandial MPS stimulation in young adults(Reference Moore, Churchward-Venne and Witard36,Reference Witard, Jackman and Breen37) , resulted in higher postprandial plasma TAA concentrations and equivalent EAA concentrations to the same relative protein dose from Milk PI. The rise in plasma leucine was more rapid and transient, and overall leucine exposure is lower, in Salmon PP compared with Milk PI. Plasma glycine, proline and hydroxyproline concentrations were robustly increased after Salmon PP ingestion only. Ingestion of Salmon PP and Milk PI transiently altered self-reported hunger and appetite sensations, and glucose and insulin concentrations to a similar extent. Collectively, these data suggest that the postprandial amino acid blood profile following Salmon PP ingestion has the potential to support the remodelling of skeletal muscle and connective tissue.

There is growing interest in the development of alternative protein sources that are both environmentally sustainable and high-quality with respect to the profile and postprandial bioavailability of amino acids for human tissue remodelling(Reference van der Heijden, Monteyne and Stephens38). The amount of rest raw material from the fishing industry is estimated to be about two-thirds of the overall amount of fish, causing a huge economic and environmental concern(Reference Coppola, Lauritano and Palma Esposito18). It is now possible to produce materials with high added nutritional value from these fish rest raw materials, creating a sustainable strategy towards a circular bioeconomy(Reference Coppola, Lauritano and Palma Esposito18). Fish-derived proteins and peptides have the potential to support muscle and connective tissue adaptive remodelling through their content and postprandial blood profile of EAA, glycine, proline and hydroxyproline(Reference Holwerda and van Loon24). To date, there is limited information on the plasma amino acid response to ingestion of protein sources produced from fish rest raw material, which may vary considerably based on the source and processing of fish and the procedures used for protein recovery(Reference Liaset, Lied and Espe27). In the present study, the temporal and iAUC TAA response over a 4-h postprandial period was greater in Salmon PP than Milk PI, whereas the temporal and iAUC plasma EAA response was equivalent between supplements. Given that total protein provided was equal, and the EAA content was about 1·5-fold greater in Milk PI compared with Salmon PP, we speculate that the rapid digestive properties of Salmon PP may explain the comparable EAA and greater TAA blood profile. Indeed, the production of Salmon PP involved enzymatic hydrolysis, the peptides from which contain hydroxyproline and proline, proposed to resist peptidase action to be absorbed intact(Reference Kim, Kim and Sleisenger39). Extending on these findings, oro-ileal assays and intrinsically labelled protein methods could provide insight into the ‘true’ protein digestibility and amino acid bioavailability of Salmon PP and novel marine-derived proteins more generally. Notwithstanding, given the prominence of EAA for postprandial MPS stimulation and the potency of Milk PI on MPS stimulation in younger adults(Reference Mitchell, McGregor and D’Souza40,Reference Smeuninx, McKendry and Wilson41) , it is intuitive that the blood EAA profile achieved with Salmon PP ingestion would elicit a robust and perhaps maximal MPS response(Reference Burd, Gorissen and van Vliet42Reference Monteyne, Coelho and Porter44). In support of this notion, Lees and colleagues(Reference Lees, Nolan and Amigo-Benavent20) reported similar MPS stimulation in myotubes following ex vivo treatment with postprandial plasma obtained after ingestion of 0·33 g/kg/body mass blue-whiting and whey protein hydrolysates, despite lower plasma EAA and leucine with blue-whiting protein.

Leucine is known to upregulate intracellular signalling intermediates in the mechanistic target of rapamycin pathway for MPS stimulation(Reference Atherton, Smith and Etheridge45). Hence, the postprandial MPS response to protein ingestion has been largely attributed to the ingested dose and blood profile of leucine, such as the peak magnitude, rate of rise and total availability of plasma leucine(Reference West, Burd and Coffey46Reference Zaromskyte, Prokopidis and Ioannidis48). In the present study, despite a comparable plasma EAA response between supplements, the iAUC plasma leucine response to Salmon PP was lower than Milk PI ingestion. The discrepant plasma EAA and leucine iAUC responses may be due to the large > 2-fold difference in leucine content between Salmon PP and Milk PI, which was greater in magnitude than the difference in summed EAA (about 1·5-fold) between supplements. This discrepancy may also be explained by specific differences in the splanchnic extraction of divergent peptides between Salmon PP and Milk PI. Irrespective, the peak magnitude of plasma leucine did not differ between supplements, and the rate of rise (or time-to-peak) was more rapid in Salmon PP. Interestingly, recent evidence suggests that although the blood leucine profile may be a determinant of the MPS response to isolated protein sources, this may only be pertinent in older adults(Reference Zaromskyte, Prokopidis and Ioannidis48,Reference Wilkinson, Koscien and Monteyne49) . Moreover, a maximal postprandial MPS response to protein ingestion appears to be achievable in young individuals irrespective of leucine content of a protein source, or blood profile upon ingestion(Reference Wilkinson, Koscien and Monteyne49). Thus, whilst leucine content and ensuing blood variables may need to surpass a given threshold to maximise postprandial MPS stimulation, this may be lower (or saturated earlier) than first thought, particularly if abundant EAA are available to support MPS(Reference Burd, Gorissen and van Vliet42,Reference Monteyne, Coelho and Porter44) . As such, in healthy younger adults under non-exercised conditions, we suggest the EAA response to isolated supplemental Salmon PP and Milk PI would be the primary determinant for postprandial MPS, although this requires further investigation.

Fish rest raw materials used in protein production (e.g. heads, trimmings, skin, scales and backbones) are typically rich in connective tissue and contain a significant amount of collagen that can vary amongst fish species(Reference Jafari, Lista and Siekapen22,Reference Holwerda and van Loon24) . Whilst high-quality, rapidly digestible proteins are generally preferable for maximal MPS stimulation, initial studies suggest that connective tissue protein synthesis remains largely unaltered(Reference Trommelen, Holwerda and Senden50,Reference Babraj, Cuthbertson and Smith51) . This is an important consideration as muscle connective tissue (extracellular matrix) plays a crucial role in contractile force transmission to tendon and bone(Reference Holwerda and van Loon24) and is in a constant state of turnover that could be influenced by nutritional factors. Fish-derived proteins contain collagen, which is a rich source of glycine, proline and hydroxyproline with purported anabolic properties for connective tissue remodelling(Reference Paxton, Grover and Baar52,Reference Vieira, De Oliveira and Da Re Guerra53) . In the present study, the peak magnitude and total availability (iAUC) of glycine, proline and hydroxyproline were markedly increased following Salmon PP ingestion, and very low or completely absent following Milk PI ingestion. These findings are in agreement with earlier observations that oral ingestion of fish-derived collagen hydrolysates results in a dose-dependent rapid increase in hydroxyproline-containing peptide concentrations in plasma(Reference Ichikawa, Morifuji and Ohara54). The present study also expands on earlier characterisations of postprandial amino acid availability following fish-derived protein ingestion, where the blood responses of these NEAA were not considered(Reference Lees, Nolan and Amigo-Benavent20). The combined temporal and iAUC blood amino acid concentrations, and specific glycine, proline and hydroxyproline profiles reported herein, position Salmon PP as a novel sustainable ingredient with the potential to support muscle and connective tissue remodelling. In light of recent work demonstrating no effect of pure collagen supplementation (very low EAA content) on muscle connective tissue protein synthesis during acute recovery from resistance exercise(Reference Aussieker, Hilkens and Holwerda55), an important next step is to understand how Salmon PP ingestion might influence these parameters.

An increase in postprandial plasma amino acid concentrations has been linked to increased satiety with protein ingestion (through alterations in appetite hormones)(Reference Mellinkoff, Frankland and Boyle56). In animals, leucine can stimulate satiety and reduce food intake via a central mechanism(Reference Fromentin, Darcel and Chaumontet57). Therefore, differences in postprandial plasma TAA and leucine concentration between Salmon PP and Milk PI ingestion may influence satiety and subsequent energy intake, as shown in comparisons between other isolated protein sources with divergent AA profiles(Reference Mellinkoff, Frankland and Boyle56,Reference Hall, Millward and Long58,Reference Veldhorst, Nieuwenhuizen and Hochstenbach-Waelen59) . However, despite differences in TAA and leucine blood profiles with Salmon PP and Milk PI, changes in perceived appetite sensations and subsequent ad libitum energy (and macronutrient) intake were indistinguishable between Salmon PP and Milk PI, along with comparable insulin and glucose responses. The findings show that beverage blinding was successful and peak perceived appetite ratings were evenly balanced across trials (data not reported), suggesting that correct beverage identification on had little impact on subjective ratings. Congruent with these observations, others have failed to detect differences in perceived appetite or ad libitum energy intake between protein sources that elicit divergent postprandial plasma total, EAA and/or leucine profiles(Reference Dai, Lov and Martin-Arrowsmith60,Reference Bowen, Noakes and Trenerry61) . We acknowledge that by assessing ad libitum energy intake 240 min after protein ingestion, when high hunger levels had been reached, potential differences between protein sources may have been missed. Finally, the appetite-lowering effect of acute protein intake may differ in longer-term regimens, where changes in energy intake are multifaceted(Reference Kohanmoo, Faghih and Akhlaghi62). Therefore, the potential long-term influence of Salmon PP on appetite and energy intake warrants further investigation.

Whilst present study is the first to demonstrate blood aminoacidemia and appetite responses to a novel fish-derived protein peptide, there are several limitations that should be acknowledged. First, we were unable to analyse concentrations of appetite regulatory hormones to determine the mechanisms of Salmon PP- and Milk PI-induced satiety. This is important as the appetite-regulatory hormonal responses to ingestion of different protein sources are unclear and there is a reported discordance between appetite-regulatory hormone concentrations in blood and energy intake in humans(Reference Braden, Gwin and Leidy29). Second, in female participants, we did not monitor menstrual cycle phase, nor were trials scheduled to fall on the same menstrual cycle phase. Given that menstrual cycle phase has been suggested to influence subjective ratings of appetite and energy intake(Reference Brennan, Feltrin and Nair63), consideration of this variable is necessary in future studies. Similarly, it possible that the palatability of treatments may have influenced appetite outcomes(Reference Yeomans64), although this was not measured. However, our blinding protocol was successful, and treatments were indistinguishable, (described in results) suggesting there was no consistent and detectable fish aftertaste with Salmon PP that would influence appetite regulation and energy intake.

In conclusion, the findings of the present study suggest that the content and bioavailability of plasma EAA from a novel protein peptide developed from fresh salmon rest raw materials was equivalent to a high-quality Milk PI and has the potential to support skeletal muscle adaptive remodelling. This warrants further investigation as the net plasma leucine response to Salmon PP was lower than Milk PI, which may limit the capacity for maximal postprandial MPS stimulation in some scenarios. Additionally, the ingestion of Salmon PP only resulted in a robust increase in plasma glycine, proline and hydroxyproline, which may have implications for the adaptive remodelling of connective tissue. Finally, Salmon PP ingestion resulted in similar transient alterations in appetite sensations and ad libitum energy intake to Milk PI and may be a suitable protein source to support appetite regulation.

Acknowledgements

The authors wish to thank the participants for their time and effort.

The study was supported by funding from Biomega Group AS to L. B.

Conception or design of the work: L. B., L. M. R. and B. L.; acquisition, analysis or interpretation of data for the work: S. P., M. F., L. M. R., and L. B.; drafting the work or revising it critically for important intellectual content: S. P., M. F., L. M. R., B. L. and L. B.; final approval of the version to be published: all authors; agreement to be accountable for all aspects of the work: L. B..

B. L. is the Chief Scientific Officer of Biomega Group AS, funders of the research. The authors have no additional conflicts of interest to declare. B. L. played a role in the conceptualisation of the research and manuscript revisions but no active role in data collection or analysis.

Footnotes

Equal co-first author contribution

References

Biolo, G, Tipton, KD, Klein, S, et al. (1997) An abundant supply of amino acids enhances the metabolic effect of exercise on muscle protein. Am J Physiol 273, E122E129.Google ScholarPubMed
Rennie, MJ, Edwards, RH, Halliday, D, et al. (1982) Muscle protein synthesis measured by stable isotope techniques in man: the effects of feeding and fasting. Clin Sci (Lond) 63, 519523.CrossRefGoogle ScholarPubMed
Tipton, KD, Gurkin, BE, Matin, S, et al. (1999) Nonessential amino acids are not necessary to stimulate net muscle protein synthesis in healthy volunteers. J Nutr Biochem 10, 8995.CrossRefGoogle Scholar
Bohe, J, Low, A, Wolfe, RR, et al. (2003) Human muscle protein synthesis is modulated by extracellular, not intramuscular amino acid availability: a dose-response study. J Physiol 552, 315324.CrossRefGoogle Scholar
Rieu, I, Balage, M, Sornet, C, et al. (2006) Leucine supplementation improves muscle protein synthesis in elderly men independently of hyperaminoacidaemia. J Physiol 575, 305315.CrossRefGoogle ScholarPubMed
Anthony, JC, Anthony, TG, Kimball, SR, et al. (2001) Signaling pathways involved in translational control of protein synthesis in skeletal muscle by leucine. J Nutr 131, 856S860S.CrossRefGoogle ScholarPubMed
Churchward-Venne, TA, Breen, L, Di Donato, DM, et al. (2014) Leucine supplementation of a low-protein mixed macronutrient beverage enhances myofibrillar protein synthesis in young men: a double-blind, randomized trial. Am J Clin Nutr 99, 276286.CrossRefGoogle Scholar
Gorissen, SHM, Trommelen, J, Kouw, IWK, et al. (2020) Protein type, protein dose, and age modulate dietary protein digestion and phenylalanine absorption kinetics and plasma phenylalanine availability in humans. J Nutr 150, 20412050.CrossRefGoogle ScholarPubMed
Morgan, PT, Harris, DO, Marshall, RN, et al. (2021) Protein source and quality for skeletal muscle anabolism in young and older adults: a systematic review and meta-analysis. J Nutr 151, 19011920.CrossRefGoogle Scholar
Tang, JE, Moore, DR, Kujbida, GW, et al. (2009) Ingestion of whey hydrolysate, casein, or soy protein isolate: effects on mixed muscle protein synthesis at rest and following resistance exercise in young men. J Appl Physiol (1985) 107, 987992.CrossRefGoogle ScholarPubMed
Dangin, M, Boirie, Y, Garcia-Rodenas, C, et al. (2001) The digestion rate of protein is an independent regulating factor of postprandial protein retention. Am J Physiol Endocrinol Metab 280, E340E348.CrossRefGoogle ScholarPubMed
Boirie, Y, Dangin, M, Gachon, P, et al. (1997) Slow and fast dietary proteins differently modulate postprandial protein accretion. Proc Natl Acad Sci U S A 94, 1493014935.CrossRefGoogle ScholarPubMed
Pinckaers, PJM, Trommelen, J, Snijders, T, et al. (2021) The anabolic response to plant-based protein ingestion. Sports Med 51, 5974.CrossRefGoogle ScholarPubMed
Burd, NA, McKenna, CF, Salvador, AF, et al. (2019) Dietary protein quantity, quality, and exercise are key to healthy living: a muscle-centric perspective across the lifespan. Front Nutr 6, 83.CrossRefGoogle ScholarPubMed
Beal, T, Gardner, CD, Herrero, M, et al. (2023) Friend or foe? The role of animal-source foods in healthy and environmentally sustainable diets. J Nutr 153, 409425.CrossRefGoogle ScholarPubMed
FAO (2022) Global Fish Production from 2002 to 2022 (in Million Metric Tons), Chart. https://www.statista.com/statistics/264577/total-world-fish-production-since-2002/ (accessed June 2023)Google Scholar
Chalamaiah, M, Dinesh Kumar, B, Hemalatha, R, et al. (2012) Fish protein hydrolysates: proximate composition, amino acid composition, antioxidant activities and applications: a review. Food Chem 135, 30203038.CrossRefGoogle Scholar
Coppola, D, Lauritano, C, Palma Esposito, F, et al. (2021) Fish waste: from problem to valuable resource. Mar Drugs 19, 116.CrossRefGoogle ScholarPubMed
Cordeiro, EM, de Oliveira, GV, Volino-Souza, M, et al. (2020) Effects of fish protein hydrolysate ingestion on postexercise aminoacidemia compared with whey protein hydrolysate in young individuals. J Food Sci 85, 2127.CrossRefGoogle ScholarPubMed
Lees, MJ, Nolan, D, Amigo-Benavent, M, et al. (2021) A fish-derived protein hydrolysate induces postprandial aminoacidaemia and skeletal muscle anabolism in an in vitro cell model using ex vivo human serum. Nutrients 13, 647.CrossRefGoogle Scholar
Rajabimashhadi, Z, Gallo, N, Salvatore, L, et al. (2023) Collagen derived from fish industry waste: progresses and challenges. Polymers (Basel) 15, 544.CrossRefGoogle ScholarPubMed
Jafari, H, Lista, A, Siekapen, MM, et al. (2020) Fish collagen: extraction, characterization, and applications for biomaterials engineering. Polymers (Basel) 12, 2230.CrossRefGoogle Scholar
Dave, D, Lu, Y, Clalrk, L, et al. (2019) Availability of marine collagen from Newfoundland fisheries and aquaculture waste resources. Bioresour Technol Rep 7, 100271.CrossRefGoogle Scholar
Holwerda, AM & van Loon, LJC (2022) The impact of collagen protein ingestion on musculoskeletal connective tissue remodeling: a narrative review. Nutr Rev 80, 14971514.CrossRefGoogle ScholarPubMed
Shaw, G, Lee-Barthel, A, Ross, ML, et al. (2017) Vitamin C-enriched gelatin supplementation before intermittent activity augments collagen synthesis. Am J Clin Nutr 105, 136143.CrossRefGoogle ScholarPubMed
Elavarasan, K & Shamasundar, BA (2016) Effect of oven drying and freeze drying on the antioxidant and functional properties of protein hydrolysates derived from freshwater fish (Cirrhinus mrigala) using papain enzyme. J Food Sci Technol 53, 13031311.CrossRefGoogle ScholarPubMed
Liaset, B, Lied, E & Espe, M (2000) Enzymatic hydrolysis of by-products from the fish-filleting industry. J Sci Food Agric 80, 581589.3.0.CO;2-I>CrossRefGoogle Scholar
Shahid, K, Srivastava, V & Sillanpää, M (2021) Protein recovery as a resource from waste specifically via membrane technology—from waste to wonder. Environ Sci Pollut Res 28, 1026210282.CrossRefGoogle ScholarPubMed
Braden, ML, Gwin, JA & Leidy, HJ (2023) Protein source influences acute appetite and satiety but not subsequent food intake in healthy adults. J Nutr 153, 18251833.CrossRefGoogle Scholar
Booth, DA, Chase, A & Campbell, AT (1970) Relative effectiveness of protein in the late stages of appetite suppression in man. Physiol Behav 5, 12991302.CrossRefGoogle ScholarPubMed
Abumrad, NN, Rabin, D, Diamond, MP, et al. (1981) Use of a heated superficial hand vein as an alternative site for the measurement of amino acid concentrations and for the study of glucose and alanine kinetics in man. Metabolism 30, 936940.CrossRefGoogle Scholar
Flint, A, Raben, A, Blundell, JE, et al. (2000) Reproducibility, power and validity of visual analogue scales in assessment of appetite sensations in single test meal studies. Int J Obes Relat Metab Disord 24, 3848.CrossRefGoogle ScholarPubMed
Burke, LM, Winter, JA, Cameron-Smith, D, et al. (2012) Effect of intake of different dietary protein sources on plasma amino acid profiles at rest and after exercise. Int J Sport Nutr Exerc Metab 22, 452462.CrossRefGoogle ScholarPubMed
Brennan, JL, Keerati, URM, Yin, H, et al. (2019) Differential responses of blood essential amino acid levels following ingestion of high-quality plant-based protein blends compared to whey protein-a double-blind randomized, cross-over, clinical trial. Nutrients 11, 2987.CrossRefGoogle ScholarPubMed
Alcock, RD, Shaw, GC, Tee, N, et al. (2019) Plasma amino acid concentrations after the ingestion of dairy and collagen proteins, in healthy active males. Front Nutr 6, 163.CrossRefGoogle ScholarPubMed
Moore, DR, Churchward-Venne, TA, Witard, O, et al. (2015) Protein ingestion to stimulate myofibrillar protein synthesis requires greater relative protein intakes in healthy older v. younger men. J Gerontol A Biol Sci Med Sci 70, 5762.CrossRefGoogle Scholar
Witard, OC, Jackman, SR, Breen, L, et al. (2014) Myofibrillar muscle protein synthesis rates subsequent to a meal in response to increasing doses of whey protein at rest and after resistance exercise. Am J Clin Nutr 99, 8695.CrossRefGoogle ScholarPubMed
van der Heijden, I, Monteyne, AJ, Stephens, FB, et al. (2023) Alternative dietary protein sources to support healthy and active skeletal muscle aging. Nutr Rev 81, 206230.CrossRefGoogle ScholarPubMed
Kim, YS, Kim, YW & Sleisenger, MH (1974) Studies on the properties of peptide hydrolases in the brush-border and soluble fractions of small intestinal mucosa of rat and man. Biochim Biophys Acta 370, 283296.CrossRefGoogle ScholarPubMed
Mitchell, CJ, McGregor, RA, D’Souza, RF, et al. (2015) Consumption of milk protein or whey protein results in a similar increase in muscle protein synthesis in middle aged men. Nutrients 7, 86858699.CrossRefGoogle ScholarPubMed
Smeuninx, B, McKendry, J, Wilson, D, et al. (2017) Age-related anabolic resistance of myofibrillar protein synthesis is exacerbated in obese inactive individuals. J Clin Endocrinol Metab 102, 35353545.CrossRefGoogle ScholarPubMed
Burd, NA, Gorissen, SH, van Vliet, S, et al. (2015) Differences in postprandial protein handling after beef compared with milk ingestion during postexercise recovery: a randomized controlled trial. Am J Clin Nutr 102, 828836.CrossRefGoogle ScholarPubMed
Hermans, WJH, Fuchs, CJ, Hendriks, FK, et al. (2022) Cheese ingestion increases muscle protein synthesis rates both at rest and during recovery from exercise in healthy, young males: a randomized parallel-group trial. J Nutr 152, 10221030.CrossRefGoogle Scholar
Monteyne, AJ, Coelho, MOC, Porter, C, et al. (2020) Mycoprotein ingestion stimulates protein synthesis rates to a greater extent than milk protein in rested and exercised skeletal muscle of healthy young men: a randomized controlled trial. Am J Clin Nutr 112, 318333.CrossRefGoogle ScholarPubMed
Atherton, PJ, Smith, K, Etheridge, T, et al. (2010) Distinct anabolic signalling responses to amino acids in C2C12 skeletal muscle cells. Amino Acids 38, 15331539.CrossRefGoogle ScholarPubMed
West, DW, Burd, NA, Coffey, VG, et al. (2011) Rapid aminoacidemia enhances myofibrillar protein synthesis and anabolic intramuscular signaling responses after resistance exercise. Am J Clin Nutr 94, 795803.CrossRefGoogle ScholarPubMed
Norton, LE, Layman, DK, Bunpo, P, et al. (2009) The leucine content of a complete meal directs peak activation but not duration of skeletal muscle protein synthesis and mammalian target of rapamycin signaling in rats. J Nutr 139, 11031109.CrossRefGoogle Scholar
Zaromskyte, G, Prokopidis, K, Ioannidis, T, et al. (2021) Evaluating the leucine trigger hypothesis to explain the post-prandial regulation of muscle protein synthesis in young and older adults: a systematic review. Front Nutr 8, 685165.CrossRefGoogle Scholar
Wilkinson, K, Koscien, CP, Monteyne, AJ, et al. (2023) Association of postprandial postexercise muscle protein synthesis rates with dietary leucine: a systematic review. Physiol Rep 11, e15775.CrossRefGoogle ScholarPubMed
Trommelen, J, Holwerda, AM, Senden, JM, et al. (2020) Casein ingestion does not increase muscle connective tissue protein synthesis rates. Med Sci Sports Exerc 52, 19831991.CrossRefGoogle Scholar
Babraj, JA, Cuthbertson, DJ, Smith, K, et al. (2005) Collagen synthesis in human musculoskeletal tissues and skin. Am J Physiol Endocrinol Metab 289, E864869.CrossRefGoogle ScholarPubMed
Paxton, JZ, Grover, LM & Baar, K (2010) Engineering an in vitro model of a functional ligament from bone to bone. Tissue Eng Part A 16, 35153525.CrossRefGoogle Scholar
Vieira, CP, De Oliveira, LP, Da Re Guerra, F, et al. (2015) Glycine improves biochemical and biomechanical properties following inflammation of the achilles tendon. Anat Rec (Hoboken) 298, 538545.CrossRefGoogle ScholarPubMed
Ichikawa, S, Morifuji, M, Ohara, H, et al. (2010) Hydroxyproline-containing dipeptides and tripeptides quantified at high concentration in human blood after oral administration of gelatin hydrolysate. Int J Food Sci Nutr 61, 5260.CrossRefGoogle ScholarPubMed
Aussieker, T, Hilkens, L, Holwerda, AM, et al. (2023) Collagen protein ingestion during recovery from exercise does not increase muscle connective protein synthesis rates. Med Sci Sports Exerc 55, 17921802.CrossRefGoogle Scholar
Mellinkoff, SM, Frankland, M, Boyle, D, et al. (1956) Relationship between serum amino acid concentration and fluctuations in appetite. J Appl Physiol 8, 535538.CrossRefGoogle ScholarPubMed
Fromentin, G, Darcel, N, Chaumontet, C, et al. (2012) Peripheral and central mechanisms involved in the control of food intake by dietary amino acids and proteins. Nutr Res Rev 25, 2939.CrossRefGoogle Scholar
Hall, WL, Millward, DJ, Long, SJ, et al. (2003) Casein and whey exert different effects on plasma amino acid profiles, gastrointestinal hormone secretion and appetite. Br J Nutr 89, 239248.CrossRefGoogle ScholarPubMed
Veldhorst, MA, Nieuwenhuizen, AG, Hochstenbach-Waelen, A, et al. (2009) Dose-dependent satiating effect of whey relative to casein or soy. Physiol Behav 96, 675682.CrossRefGoogle ScholarPubMed
Dai, J, Lov, J, Martin-Arrowsmith, PW, et al. (2022) The acute effects of insect v. beef-derived protein on postprandial plasma aminoacidemia, appetite hormones, appetite sensations, and energy intake in healthy young men. Eur J Clin Nutr 76, 15481556.CrossRefGoogle Scholar
Bowen, J, Noakes, M, Trenerry, C, et al. (2006) Energy intake, ghrelin, and cholecystokinin after different carbohydrate and protein preloads in overweight men. J Clin Endocrinol Metab 91, 14771483.CrossRefGoogle ScholarPubMed
Kohanmoo, A, Faghih, S & Akhlaghi, M (2020) Effect of short- and long-term protein consumption on appetite and appetite-regulating gastrointestinal hormones, a systematic review and meta-analysis of randomized controlled trials. Physiol Behav 226, 113123.CrossRefGoogle Scholar
Brennan, IM, Feltrin, KL, Nair, NS, et al. (2009) Effects of the phases of the menstrual cycle on gastric emptying, glycemia, plasma GLP-1 and insulin, and energy intake in healthy lean women. Am J Physiol Gastrointest Liver Physiol 297, G602610.CrossRefGoogle ScholarPubMed
Yeomans, MR (1996) Palatability and the micro-structure of feeding in humans: the appetizer effect. Appetite 27, 119133.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Participant characteristics

Figure 1

Fig. 1. Schematic of experimental trials. Trials were separated by > 5 d and involved ingestion of 0·3 g/kg/body mass salmon-derived peptide protein (Salmon PP) or milk protein isolate (Milk PI), arterialised blood sampling over 4 h and a buffet-style test meal for the assessment of ad libitum energy intake. VAS, visual analogue scales.

Figure 2

Table 2. Supplement composition

Figure 3

Fig. 2. Postprandial plasma insulin (a) and glucose (b) concentrations following ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey) in young healthy adults. n 11. Data are presented as mean ± sem. *A statistically significant difference from 0-min fasted-state time point for both groups (P < 0·05). #A statistically significant difference from 0-min fasted-state time point for Salmon PP only (P < 0·05).

Figure 4

Fig. 3. Postprandial plasma amino acid responses to ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey) in young healthy adults. Time course and incremental AUC (iAUC) of plasma total amino acids (TAA; a, b), non-essential amino acids (NEAA; c, d), essential amino acids (EAA; e, f) and leucine (g, h) concentrations for n 11. Data are presented as mean ± sem and individual values. A statistically significant difference between Salmon PP and Milk PI (P < 0·05). *A statistically significant difference from 0-min fasted-state time point for both groups (P < 0·05). #A statistically significant difference from 0-min fasted-state time point for Salmon PP only (P < 0·05). $A statistically significant difference from 0-min fasted-state time point for Milk PI only (P < 0·05). EAA is the sum of histidine, threonine, lysine, methionine, valine, isoleucine, leucine and phenylalanine. NEAA is the sum of alanine, arginine, asparagine, citrulline, cysteine, glutamine, glutamic acid, glycine, ornithine, proline, taurine and tyrosine. iAUC, incremental AUC.

Figure 5

Fig. 4. Postprandial plasma amino acid responses to ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey) in young healthy adults. Time course and incremental AUC (iAUC) of plasma glycine (a), (b), hydroxyproline (c), (d) and proline (e), (f) concentrations for n 11 (n 10 for proline iAUC due to missing data for one participant). Data are presented as mean ± sem and individual values. †A statistically significant difference between Salmon PP and Milk PI (P < 0·05).

Figure 6

Table 3. Dietary intake analysis

Figure 7

Fig. 5. Postprandial perceptions of fullness (a), hunger (b) and satisfaction (c) following ingestion of salmon-derived peptide protein (Salmon PP; black) and milk protein isolate (Milk PI; grey), and ad libitum total energy (d) and macronutrient (e) intake at the breakfast test meal (consumed 240 mins after Salmon PP/Milk PI ingestion) in young healthy adults for n 11. Data are presented as mean ± sem and individual values (for breakfast energy intake only). *A statistically significant difference from 0-min fasted-state time point (P < 0·05). #A statistically significant difference from 0-min fasted-state time point for Salmon PP only (P < 0·05). $A statistically significant difference from 0-min fasted-state time point for Milk PI only (P < 0·05). VAS, visual analogue scales.