Advances in separation and analysis of aromatic amino acids in food

doi:10.3724/SP.J.1123.2022.04011

Abstract

Abstract:

Amino acids are important building blocks of proteins in the human body, which are involved in many metabolic pathways. Patients with metabolic diseases such as phenylketonuria, tyrosinemia, and hepatic encephalopathy are genetically defective and cannot metabolize aromatic amino acids (AAA) in food; hence, a regular diet may lead to permanent physiological damage. For this reason, it is necessary to restrict the intake of AAA in their daily diet by limiting natural protein intake, while ensuring normal intake of low protein foods and supplementation with low-AAA protein equivalents. Sources of low-AAA protein equivalents currently rely on free amino acid complex mixtures and low-AAA peptides (also known as high-Fischer-ratio peptides), which have better absorption availability and palatability. AAA separation and analysis techniques are essential for the preparation and detection of low-AAA peptides. Researchers in this field have explored a variety of efficient adsorption materials to selectively remove AAA from complex protein hydrolysates and thus prepare low-AAA peptide foods, or to establish analysis strategies for AAA. Covering more than 70 publications on AAA removal and separation in the last decade from Web of Science Core Collection and China National Knowledge Infrastructure, this review analyzes the structural characteristics and physicochemical properties of AAA, and summarizes the technological progress of AAA removal based on adsorbents such as activated carbon and resin. The applications of two-dimensional nanomaterials, molecular imprinting, cyclodextrins, and metal-organic frameworks in AAA adsorption and analysis from three dimensions, i. e., sample pretreatment, chiral separation and adsorption sensing, are also reviewed. The mainstream adsorbents for AAA removal, such as activated carbon, still suffer from poor specificity and cause environmental pollution during post-use treatment. Existing AAA separating materials show impressive selective adsorption capability in food samples and chiral mixtures as well as high sensitivity in adsorption sensing. The development of an efficient detection technology for AAA may help in detecting trace AAA in food and in evaluating chiral AAA adulteration in food samples. By exploring the advantages and disadvantages of each type of technology, we provide support for the advancement of the removal and analysis techniques for AAA.

Key words: aromatic amino acids, adsorption, removal, separation, review

CLC Number:

O658

LU Chenhui, ZHANG Yi, SU Yujie, WANG Wenlong, FENG Yongwei. Advances in separation and analysis of aromatic amino acids in food[J]. Chinese Journal of Chromatography, 2022, 40(8): 686-693.

Figures/Tables 5

References

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Raw materials	Proteases	Adsorbents	Fischer ratio	Reference
Corn	alkaline protease, neutral protease	activated carbon	21.92	[7]
Corn	bacillus natto alkaline protease	modified activated carbon	21.80	[8]
Crude corn peptides	α-chymotrypsin, carboxypeptidase A	activated carbon (different type)	41.87	[9]
Tuna	pepsin, flavor protease	activated carbon (200 mesh)	30.33	[10]
Chlamys farreri	compound protease, flavor protease	activated carbon (200 mesh)	34.73	[11]
Antarctic krill	alkaline protease, flavor protease	activated carbon	21.12	[12]
Minced squid	pepsin, flavor protease	activated carbon (50 mesh)	/	[13,14]
Yeast	α-chymotrypsin, carboxypeptidase A	modified activated carbon	30.00-40.00	[15]
Soy protein	alkaline protease, flavor protease	activated carbon (different type)	18.90	[16]
Grass carp	pancreatin, papain	activated carbon (different type)	/	[17]
Pearl oyster	pancreatin	activated carbon	24.58	[18]
Goat milk	pepsin, flavor protease	activated carbon (200 mesh)	26.32	[19]

Raw materials	Proteases	Adsorbents	Fischer ratio	Reference
Corn	alkaline protease, neutral protease	activated carbon	21.92	[7]
Corn	bacillus natto alkaline protease	modified activated carbon	21.80	[8]
Crude corn peptides	α-chymotrypsin, carboxypeptidase A	activated carbon (different type)	41.87	[9]
Tuna	pepsin, flavor protease	activated carbon (200 mesh)	30.33	[10]
Chlamys farreri	compound protease, flavor protease	activated carbon (200 mesh)	34.73	[11]
Antarctic krill	alkaline protease, flavor protease	activated carbon	21.12	[12]
Minced squid	pepsin, flavor protease	activated carbon (50 mesh)	/	[13,14]
Yeast	α-chymotrypsin, carboxypeptidase A	modified activated carbon	30.00-40.00	[15]
Soy protein	alkaline protease, flavor protease	activated carbon (different type)	18.90	[16]
Grass carp	pancreatin, papain	activated carbon (different type)	/	[17]
Pearl oyster	pancreatin	activated carbon	24.58	[18]
Goat milk	pepsin, flavor protease	activated carbon (200 mesh)	26.32	[19]

Application	Target	Sample	Adsorbent	Analytical method	Reference
Sample	L-AAA	protein hydrolysate	MOFs	HPLC	[39]
pretreatment	AAA	lily	MWCNTs and MOFs composite	HPLC	[40]
	L-Trp	black sesame seed	GO@SiO₂	HPLC	[41]
	AAA	AAA aqueous solution	ZIF-8@β-CDPs	/	[42]
Chiral	L-Phe	D,L-Phe; D,L-Trp	L-Phe-imprinted cryogel cartridge	FPLC	[43]
separation	L-AAA	D,L-AAA mixture	surface functionalized magnetic nanoparticles	HPLC	[44]
	D-Phe	D,L-Phe mixture	D,L-Ala-CD/SiO₂	absorption spectroscopy	[45]
Adsorption-	L-Phe	artificial plasma	L-Phe imprinted SPR sensor	SPR	[46]
sensing	Phe, Tyr	standard solution	Ni@CNFs@Au	SERS	[47]
	Phe	AAA aqueous solution	pyrene@2βCD	absorption spectroscopy	[48]
	L-AAA	milk	bi-enzyme nanocomposite film-based biosensor	amperometric measurements	[49]

Application	Target	Sample	Adsorbent	Analytical method	Reference
Sample	L-AAA	protein hydrolysate	MOFs	HPLC	[39]
pretreatment	AAA	lily	MWCNTs and MOFs composite	HPLC	[40]
	L-Trp	black sesame seed	GO@SiO₂	HPLC	[41]
	AAA	AAA aqueous solution	ZIF-8@β-CDPs	/	[42]
Chiral	L-Phe	D,L-Phe; D,L-Trp	L-Phe-imprinted cryogel cartridge	FPLC	[43]
separation	L-AAA	D,L-AAA mixture	surface functionalized magnetic nanoparticles	HPLC	[44]
	D-Phe	D,L-Phe mixture	D,L-Ala-CD/SiO₂	absorption spectroscopy	[45]
Adsorption-	L-Phe	artificial plasma	L-Phe imprinted SPR sensor	SPR	[46]
sensing	Phe, Tyr	standard solution	Ni@CNFs@Au	SERS	[47]
	Phe	AAA aqueous solution	pyrene@2βCD	absorption spectroscopy	[48]
	L-AAA	milk	bi-enzyme nanocomposite film-based biosensor	amperometric measurements	[49]