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BUFFALO MEAT QUALITY, PROCESSING, AND MARKETING:

HARNESSING ITS BENEFITS AND NUTRACEUTICAL POTENTIAL

Calidad, procesamiento y comercialización de la carne de búfalo:

aprovechando sus benecios y potencial nutracéutico

Sebastiana Failla

Consiglio per la Ricerca in Agricoltura e l’Analisi dell’Economia Agraria (CREA), Research Centre for Animal Production and

Aquaculture, Monterotondo, Rome, Italy.

Corresponding e-mail: Failla, Sebastiana (sebastiana.failla@crea.gov.it)

ABSTRACT

Bu󰀨alo meat production is growing in di󰀨erent countries also

because bu󰀨alo products exhibit some positive characteristics

for human health compared to red meats from other species.

However, meat quality is also dened by organoleptic aspects.

This review aims to highlight the distinctive characteristics of

bu󰀨alo meat. The principal problems of bu󰀨alo meat production

are related to the low yield and an abundant layer of subcuta-

neous fat deposition when the animal is older than 14 months.

This last trait, which may seem negative, allows us to carry out

prolonged aging time (PAT) without compromising the shelf life

and improving meat tenderness, one of the organoleptic char-

acteristic’s consumers desires. Another organoleptic character-

istic that guides consumer choice is color. This trait depends

mainly on the amount and state of myoglobin, a species-spe-

cic sarcoplasmic heme protein, and bu󰀨alo presents a di󰀨er-

ent molecule than beef. Furthermore, this bright red molecule

in the oxidized state transforms into metmyoglobin or deoxy

myoglobin in the absence of oxygen, giving a dark color to the

meat, which consumers associate with poor quality from old

animals. The presence or absence of oxygen shows advantag-

es and disadvantages by acting on the one hand, on the bright

meat color and, on the other, on the oxidation of lipids. The best

compromise between the two situations is given by skin pack-

aging, which preserves the meat in an anaerobic environment.

Keeping the high nutritional quality over time is imperative to

maintain the numerous nutritional properties of bu󰀨alo meat. In

this regard, bu󰀨alo meat presents numerous distinctive charac-

teristics among the di󰀨erent groups of fatty acids. Among the

saturated one, the abundance of odd and branched fatty acids

compared to the bovine breed should be highlighted; for the

unsaturated ones, this meat is characterized by the abundance

of biohydrogenation products by rumen bacteria such as trans

vaccenic and conjugated linoleic acid (CLA), best known for its

anti-carcinogenic properties. In comparison, the endogenous

pathway of fatty acid formation through the liver or adipose tis-

sue allows us to enhance the elongation capacity of polyun-

saturated n3 fatty acids, vital for human health as precursors

of anti-inammatory prostaglandins. Finally, bu󰀨alo meat is an

essential source of N-acetylneuraminic sialic acid (Neu5Ac),

a nine-carbon molecule located in the terminal ends of glyco-

proteins and glycolipids, an essential nutrient for brain devel-

opment and function. This molecule can also counteract the

intestinal absorption of N-glycolyl sialic acid (Neu5Gc) exoge-

nous for humans, abundant in red meat, with high inammato-

ry action. In addition to being marketed as fresh meat, Bu󰀨alo

meat can also be transformed into semi-processed or cured

products with peculiar characteristics. Lean products could be

well integrated into the modern diet, with clear advantages to

consumers and breeders. The nutritional and technological po-

tential of bu󰀨alo meat is considerable, and it is necessary to

communicate this to the consumer, creating an e󰀩cient and

dynamic market for bu󰀨alo meat-based products.

Keywords: bu󰀨alo meat, dry aging, oxymyoglobin, nutraceuti-

cal compounds, fatty acids.

RESUMEN

La producción de carne de búfalo está creciendo en diferentes

países también porque los productos de búfalo presentan al-

gunas características positivas para la salud humana en com-

paración con las carnes rojas de otras especies. Sin embar-

go, la calidad de la carne también viene denida por aspectos

organolépticos. Esta revisión tiene como objetivo resaltar las

características distintivas de la carne de búfalo. Los principales

problemas de la producción de carne de búfalo están relacio-

nados con el bajo rendimiento y una abundante capa de grasa

subcutánea cuando el animal tiene más de 14 meses. Este últi-

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mo rasgo, que puede parecer negativo, nos permite realizar un

tiempo de envejecimiento prolongado (PAT) sin comprometer

la vida útil y mejorando la terneza de la carne, una de las carac-

terísticas organolépticas que desea el consumidor. Otra carac-

terística organoléptica que orienta la elección del consumidor

es el color. Este rasgo depende principalmente de la cantidad

y el estado de la mioglobina, una proteína hemo sarcoplásmica

especíca de cada especie, y el búfalo presenta una molécula

diferente a la de la carne de res. Además, esta molécula de

color rojo brillante en estado oxidado se transforma en metmio-

globina o desoximioglobina en ausencia de oxígeno, dando un

color oscuro a la carne, que los consumidores asocian con la

mala calidad de los animales viejos. La presencia o ausencia

de oxígeno presenta ventajas e inconvenientes al actuar, por

un lado, sobre el color brillante de la carne y, por otro, sobre la

oxidación de los lípidos. El mejor compromiso entre ambas si-

tuaciones lo proporciona el envasado tipo “skin”, que conserva

la carne en un ambiente anaeróbico. Mantener la alta calidad

nutricional en el tiempo es imperativo para mantener las nume-

rosas propiedades nutricionales de la carne de búfalo. En este

sentido, la carne de búfalo presenta numerosas características

distintivas entre los distintos grupos de ácidos grasos. Entre

los saturados cabe destacar la abundancia de ácidos grasos

impares y ramicados respecto a los vacunos; para las insatu-

radas, esta carne se caracteriza por la abundancia de produc-

tos de biohidrogenación por bacterias ruminales como el trans

vaccénico y el ácido linoleico conjugado (CLA), más conocido

por sus propiedades anticancerígenas. En comparación, la vía

endógena de formación de ácidos grasos a través del hígado

o el tejido adiposo nos permite potenciar la capacidad de elon-

gación de los ácidos grasos poliinsaturados n3, vitales para la

salud humana como precursores de las prostaglandinas an-

tiinamatorias. Finalmente, la carne de búfalo es una fuente

esencial de ácido siálico N-acetilneuramínico (Neu5Ac), una

molécula de nueve carbonos ubicada en los extremos termi-

nales de las glicoproteínas y glicolípidos, un nutriente esencial

para el desarrollo y la función del cerebro. Esta molécula tam-

bién puede contrarrestar la absorción intestinal del ácido N-gli-

colil siálico (Neu5Gc) exógeno al ser humano, abundante en

las carnes rojas, con elevada acción inamatoria. Además de

comercializarse como carne fresca, la carne de búfalo también

puede transformarse en productos semielaborados o curados

con características peculiares. Los productos magros podrían

integrarse bien en la dieta moderna, con claras ventajas para

los consumidores y los criadores. El potencial nutricional y tec-

nológico de la carne de búfalo es considerable y es necesario

comunicarlo al consumidor, creando un mercado eciente y di-

námico para los productos a base de carne de búfalo.

Palabras clave: carne de búfalo, maduración en seco, oximio-

globina, compuestos nutracéuticos, ácidos

grasos.

INTRODUCTION

In the last decade, Bu󰀨alo (Bubalus bubalis L.) meat has

reported an increase in population head livestock as in tonnes

of meat production. According to FAO Stat data1, the world buf-

falo population in 2021 was 203.940 million bu󰀨alo head, about

more than 9.860 million head compared to 2010. TABLE I

shows the bu󰀨alo animals slaughtered in 2021 and the quantity

of meat produced. On average, each bu󰀨alo head produces

151kg of meat, which is low weight if we consider the slaughter

of adults. This data highlights that even in 2021, many male

calves are slaughtered very young. Furthermore, only around

14% of the world’s bu󰀨alo population is slaughtered, and most

of these are spent animals.

These data highlight consumer disa󰀨ection for this type

of product, even though it is clear that bu󰀨alo meat has positive

characteristics for human health. However, improving knowl-

edge on meat quality and meat processing of bu󰀨aloes is slow-

ly bringing about a consumption positive trend because bu󰀨alo

meat could represent a considerable economic and nutritional

source [2]. The principal problems of bu󰀨alo meat production

are related to the low yield and an abundant layer of subcuta-

neous fat deposition when the animal is older than 14 months.

The di󰀨erent breeds, age, breeding, and pre-and

post-slaughter technologies result in great variability in carcass

and meat characteristics, leading to poor quantitative and qual-

itative performances [2, 3]. Meat quality is dened by di󰀨erent

parameters concerning carcass, organoleptic, and nutritional

characteristics of meat. For increasingly health-conscious con-

sumers, the last two aspects cannot be separated to satisfy

their needs.

ORGANOLEPTIC QUALITY OF BUFFALO MEAT

Color and tenderness are the principal organoleptic

characteristics because they direct consumers’ choices during

buying and eating [4]. Both characteristics depend on pre- and

post-mortem processes during slaughtering on meat aging and

enzymatic proteolysis [5]. At the same time, color is also linked

to oxidation processes that occur during aging but also retail

and domestic storage [6]. The color of meat depends mainly on

the amount and oxidation state of myoglobin (Mb), a sarcoplas-

mic protein with an iron molecule in the center surrounded by

a tetrapyrrole ring called heme. Meat color for each species is

typical because the chemistry of myoglobin is species-specic

[7].

The molecular mass of bu󰀨alo Mb is 86.20 Da higher

than the bovine Mb. This is conrmed by analyzing its primary

structure. Comparing the amino acid sequences of both Mbs,

we found three amino acid di󰀨erences out of 153 amino acid

residues [7]; only one of these substitutions is made by a thre-

onyl amino acid that is a destabilizing β-branched residue.

These observations indicate that the structural architecture

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of the heme pockets in the two Mbs is similar, with the same

functional properties, but with di󰀨erent behavior during oxida-

tion, due also to higher myoglobin content in bu󰀨alo meat as

reported by [8]. Even if the Mb quantity depends on age and

muscle type, the range is very high, from 2.70 to 9.40 mg/g [9].

Moreover, bu󰀨alo meat is richer in iron (1.83 mg/100g) than

other species like beef and sheep (1.53 mg/100g on average).

The most immediate way to analyze meat color is given by the

CieLab system (TABLE II), which considers lightness (L*), red-

ness (a*), and yellowness (b*).

Bu󰀨alo meat increases in lightness during aging, while it

decreases during oxidation. The old animals show di󰀨erent col-

ors, particularly for major concentrations in Mb (+ an index) and

intramuscular fat (+ b indexes), as found for grazing animals,

which have meat richer in pigments [10]. However, the bu󰀨alo

cannot accumulate large percentages of carotenoids in the ad-

ipose tissue; in fact, this tends to be white even in the carcass

of adult animals [11].

In the function of heme oxidation, the myoglobin changes

in color; the bright red molecule in the oxidized state (oxymyo-

globin) transforms into metmyoglobin due to the oxidation of

iron from ferrous to ferric state or into deoxy myoglobin in the

absence of oxygen as in vacuum packaged meat, giving a dark

color to the meat and consumers associate it with poor quality

from old animals [16]. Di󰀨erent packaging technologies try to

solve this very pronounced problem in bu󰀨alo meat due to the

excessive presence of iron [17]. Among the technologies that

improve the marketing and shelf life of bu󰀨alo meat, the follow-

ing are highlighted: modied or protective atmosphere packag-

ing (MAP), whose atmosphere blown inside consists mainly of

80% oxygen (O2) and 20% carbon dioxide (CO2); vacuum pack-

aging and skin packaging, storage in the absence of oxygen

and edible lm. These types of packaging can be supported by

using absorbent pads and lms activated with antimicrobial and

antioxidant substances [18, 5]. The presence or absence of ox-

ygen shows advantages and disadvantages by acting on the

one hand on oxymyoglobin formation and the bright meat color

TABLE I

CONSISTENCY OF BUFFALO SLAUGHTERED AND TONNES OF MEAT PRODUCT IN 2021

2021 Bu󰀨alo heads Bu󰀨alo slaughtered heads Meat production

(tonnes per year)

Meat yields pro head

slaughtered

World 203,939,158 28,601,802 4,322,190.48 151.1

Asia 200,182,688 27,870,440 4,107,873.87 147.4

India 11,786,188 11,769,252 1,635,506.69 139.0

China 27,022,807 4,526,052 658,617.77 145.5

Africa 1,263,128 507,634 166,744.50 328.5

Americas 2,010,831 115,779 26,047.91 225.0

Europe 482,334 110,949 21,277.00 191.8

Italy 409,410 107,949 20,691.24 191.6

Data: FAO [1]

TABLE II

COLOR (CIELAB PARAMETERS) OF MEAT BUFFALO IN

DIFFERENT CONDITIONS

Type Lightness L* Redness a* Yellowness b*

Musles [12]

LD 44.33b16.35b13.01b

GB 49.45a17.32ab 15.82a

CLOTB 46.04b18.11a15.02a

Aging period* [13]

24 hours 36.5c17.12a13.27

48 hours 39.0b16.54ab 13.34

168 hours 42.9a16.10b13.91

Aging period*[14]

7 days 44.65 20.22a8.21b

21 days 44.13 19.74b8.04b

35 days 44.61 19.43b10.53a

Storage time*[12]

15 days 45.53a18.98b13.98a

90 days 42.99ab 17.36c10.03c

180 days 41.12b20.03a11.69b

Age at slaughter*[15]

10 months 43.95a19.24b15.72

14 months 41.69b20.22b15.79

18 months 39.79c21.41a16.22

Feeding system*[10]

Mais silage 46.81a18.10b14.53a

Hay 42.46b19.65a12.60ab

Pasture 41.10b19.92a10.93b

LD=Longissimus dorsi; GB=Gluteos biceps; CLOTB=Caput longuum

tricipite brachii; *=LD. Di󰀨erent letters on column indicate signicant

di󰀨erences per p<0.05

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13th World Bu󰀨alo Congress ~ 13er Congreso Mundial de Búfalos / Lectures / Bualo's Products & Industry _________________________

on the other on the oxidation of lipids. The best compromise

between the two situations is given by skin packaging, which

preserves the meat in an anaerobic environment, producing all

the positive e󰀨ects of the vacuum. However, it does not allow

the dripping liquids from the meat, signicantly improving and

extending the shelf life [19].

Nonetheless, this technology is still costly and is used

for small portions of raw meat, grounded meat, or meat prepa-

rations, which could be purchased in retail. The main problem

of meat packaging, besides the need to enhance e󰀩ciency in

terms of shelf life, is to lower the production cost and limit plas-

tic pollution. An answer to these problems could be given by

edible lm and coat using hydrocolloid and lipid components.

The bu󰀨alo slaughter produces many residues, such as

skin, blood, bones, meat trimmings, and fatty tissues, which

represent a risk to the environment because they are often dis-

carded as waste without being used. These biowastes contain

biopolymers and other compounds such as proteins, polysac-

charides, and fat with good biological properties capable of pro-

ducing sustainable food packaging (both active lm or coating),

which could be edible, biodegradable, and act as carriers of

biobased active agents such as antimicrobials, antioxidants,

and health-promoting compounds. The di󰀨erence between

lms and coatings consists in their manufacture and applica-

tion. Edible lms are dried, preformed thin sheets, while edible

coatings are applied as a liquid of varying viscosity onto the

surface of muscle by spraying or dipping [20].

In addition to active and edible packaging, intelligent sys-

tems were tested on bu󰀨alo meat based on sensors with bro-

mophenol blue sensitive to total volatile basic nitrogen released

from bu󰀨alo meat during prolonged refrigerated storage [21].

However, preserving time for the high nutritional quality

of bu󰀨alo meat is imperative in order not to lose the numerous

nutritional properties like antioxidant compounds such as Q10,

glutathione, vitamins, minerals such as iron, zinc, and seleni-

um, essential amino acids in particular branch amino acids and

polyunsaturated fatty acids.

If color is the rst parameter consumers use for buying

meat, tenderness is the rst attribute that consumers use to

evaluate the organoleptic quality during eating. Generally, the

bu󰀨alo meat obtained from young animals is tender compared

to beef at the same age and breeding system. Meat tenderiza-

tion depends on various factors that occur mainly in the peri-

od around slaughter and are linked both to the animal and to

technological tenderization systems like variation in tempera-

ture/time of aging, electrical stimulation, di󰀨erent suspension

methods, and use of exogenous enzymes. These factors a󰀨ect

the glycolytic and proteolytic enzymatic activity, acting on pH,

ability to retain liquids, and myobrillar degradation processes.

Therefore, meat tenderization is a delicate multifactorial pro-

cess during aging [22].

The e󰀨ect of aging is time-dependent; some rst-quality

cuts, in particular loin, usually receive a prolonged aging time

(PAT), but in order to avoid rancidity and microbial proliferation,

various preservation techniques have been implemented. The

most common ones are classied into: “dry aging” and “wet

aging” [23].

Dry aging includes maturation in a controlled environ-

ment (+2°C of temperature and 78% of relative humidity) or

protected maturation with lms that ensure oxygen penetration

and the losses of liquids and allow an antimicrobial barrier [24].

This process can last for weeks or even months. The anatomi-

cal cuts for prolonged aging time must generally be signicant

and have an abundant subcutaneous fat layer to prevent liquid

loss and excessive oxygen penetration, blocking lipid oxidation.

At the same time, proteolysis continues due to the enzymatic

activity. Usually, bu󰀨alo loin has an abundant adipose pannicu-

lus that is well suited to this process [25], ensuring tenderness,

avor, and formation of bioactive peptides. The chunk of meat

dries outside, making the “crust,” after a few weeks, starts the

ber contraction, preventing the deterioration of meat.

The crust will be removed before consumption, with con-

siderable product losses [26].

Among the wet aging processes, we have vacuum-packed

meat maturation, or meat maturation with marinate, improving

overall acceptability (TABLE III). The vacuum-packed meat

remains in contact with liquids, giving blood and metal taste,

but using calcium chloride marination (FIG. 1), the tenderness

TABLE III

SENSORY EVALUATION OF LONGISSIMUS THORACIS ET LUMBORUM OF BUFFALO DURING WET AGING [14]

Aging (Days) Odor Flavor Intensity Overall Tenderness Juiciness Overall Acceptability

06.12 ± 0.45 5.78 ± 0.60 6.25 ± 0.73f5.48 ± 0.61 5.42 ± 0.62c

7 6.08 ± 0.50 5.75 ± 0.53 6.66 ± 0.57e5.54 ± 0.59 5.44 ± 0.59c

14 6.05 ± 0.19 6.69 ± 0.56 6.97 ± 0.65d5.59 ± 0.81 5.50 ± 0.81c

21 6.00 ± 0.26 5.72 ± 0.72 7.32 ± 0.69c5.65 ± 0.73 5.67 ± 0.56b

28 5.97 ± 0.35 5.76 ± 0.51 7.47 ± 0.67b5.64 ± 0.83 5.69 ± 0.28b

35 5.99 ± 0.31 6.82 ± 0.42 7.86 ± 0.40a5.66 ± 0.52 5.79 ± 0.57a

Hedonic scale on 8-point, where 8 = excellent, while 1 = extremely bad. Di󰀨erent letters on column indicate signicant di󰀨erences per p<0.05.

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improves during aging time [27]. The avor can be improved

with the addition of brines and spices, which also show an anti-

bacterial and antioxidant function, catching iron and improving

color [23, 14].

NUTRITIONAL QUALITY

The proximate composition of bu󰀨alo meat is not di󰀨er-

ent from little marbled bovine meat if we consider both species

have the same muscle, just as the percentage of collagen is

not di󰀨erent to beef at the same age and breeding conditions.

Bu󰀨alo meat has a lower percentage of cholesterol than beef,

but this di󰀨erence is related to the bovine breed used in com-

parison; in fact, Di Stasio and Brugiapaglia [3] consider only

eight bibliographic sources report cholesterol values that range

from 32.20 to 123.79 mg/100g of bu󰀨alo meat.

Fatty acids are most important to dene the nutritional

quality of meat because the quantity and the structure of fatty

acids impact human health. In this regard, bu󰀨alo meat pres-

ents numerous distinctive characteristics in the di󰀨erent groups

of fatty acids (TABLE IV) if compared with other species fed

and bred similarly. Among the saturated ones, the abundance

of branched fatty acids compared to the bovine breed should

be highlighted because these fatty acids have a nutraceutical

function in the human diet [28]. For the monounsaturated ones,

this meat enhances its characteristics thanks to the abundance

of oleic acid and products of the biohydrogenation of rumen

bacteria such as trans vaccenic (18:1 trans 11), trans palmi-

toleic (16:1 trans 9), and so on. Also, some polyunsaturated

fatty acids come from the rumen activity as conjugated linoleic

acids (CLA), best known for their anti-carcinogenic properties

[29], are signicantly more abundant in bu󰀨alo than beef and

yak [30].

The endogenous pathway of fatty acid formation through

the liver or adipose tissue allows us to enhance the elonga-

tion capacity of polyunsaturated n3 fatty acids, vital for human

health as precursors of anti-inammatory prostaglandins. Also,

if the composition of n6 and n3 fatty acids is principally diet-de-

pendent, the elongation capacity of PUFA is partly due to ge-

netic e󰀨ects [31]. The inability of humans to produce linoleic

acid (C18:2n6) and linolenic acid (C18:3n3) means that their

presence in the diet is vital. Although many vegetables help

us overcome this deciency, we need animal products to get

long-chain n3 PUFAs such as eicosapentaenoic acid (EPA),

docosahexaenoic acid (DHA), and Docosapentaenoic acid

(DPA). These are precursors of lipoxins, prostaglandins, and

leukotrienes with anti-inammatory action and are abundantly

present in sh. If we consider DPA instead, with its numerous

FIGURE 1. SHEAR FORCE OF LONGISSIMUS THORACIS

ET LUMBORUM OF BUFFALO MARINATED WITH CaCl2

[27]

TABLE IV

FATTY ACID (% OF TOTAL FAME) ON LONGISSIMUS THORACIS OF DIFFERENT SPECIES

Bu󰀨alo Beef Yak RMSE

∑ SFA 45.28a45.50a42.15b3.27

∑MUFA 40.23 41.64 40.12 3.58

∑PUFA 14.49b12.87c17.73a1.42

∑CLA 0.71a0.53b0.64ab 0.11

BCFA 1.25a1.04b1.17ab 0.18

MUFA trans 1.35a1.37a0.85b0.36

∑ PUFA n6 12.10b11.07c13.91a0.99

∑ PUFA n3 2.39b1.80c3.82a0.57

∑ UFA/∑SFA 1.21 1.20 1.37 0.32

∑n6/∑n3 5.06ab 6.14a3.64b1.50

FAME = fatty acid methyl ester; SFA=saturated fatty acids; MUFA=monounsaturated fatty acids; PUFA=polyunsaturated fatty acids; UFA= unsaturated

fatty acids. Di󰀨erent letters on row indicate signicant di󰀨erences per p<0.05

Data: CREA not published

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metabolic functions that inuence the decrease in serum adi-

ponectin and hepatic lipogenesis [32], this is highly present in

meat (TABLE V).

Bu󰀨alo meat DPA showed an intermediate content if

compared with beef and yak. Recently, numerous studies have

highlighted the capability of DPA to be converted into EPA and

DHA as needed and, therefore, can be considered a source

of long-chain n3 storage thanks to its remarkable ability to re-

sist oxidation. Furthermore, if we feed the bu󰀨aloes with a diet

based on grass or added axseeds and algae, we can enrich

the products of animal origin with DPA and functional elements

for humans.

Finally, bu󰀨alo meat is an essential source of N-acetyl-

neuraminic sialic acid (Neu5Ac), a nine-carbon molecule lo-

cated in the terminal ends of glycoproteins and glycolipids, an

essential nutrient for brain development and function [33]. This

molecule can counteract the intestinal absorption of N-glico-

lilneuramic acid (Neu5Gc) exogenous sialic acid for humans,

which is abundant in red meat, and it has high inammatory

action, also considered one of the leading causes of colon can-

cer. As reported in Kawanishi [34], a dietary intake of Neu5Ac

ve times higher than Neu5Gc was su󰀩cient to eliminate the

incorporation of Sialic acids (Sia) foreign forms in human cell

membranes.

In this case, to reduce the inammation caused by ex-

ogenous Sias, reducing red meat consumption would not be

necessary, but increasing consumption of animal products with

a higher quantity of Neu5Ac, as bu󰀨alo meat showed Neu5Ac

6.2 times greater than Neu5Gc. The sialic acid in bu󰀨alo meat

can provide functional molecules and block the absorption of

exogenous sialic acid that harms humans.

To avoid inammation potentially caused by meat,

switching to a vegetarian diet is inconsistent because it lacks

iron, vitamin B12, essential amino acids, and long-chain es-

sential fatty acids. A promising alternative is an increase in the

weekly consumption of meat with higher amounts of Neu5Ac,

which can prevent the accumulation of exogenous sialic acid in

human cells.

SEMI-PROCESSED AND CURED PRODUCTS:

A BRIEF REVIEW

In addition to being marketed as fresh meat suitably

packaged to extend its shelf life, Bu󰀨alo meat can also be

transformed into semi-processed products or various cured

products [35, 36].

An exciting review was published by Maheswarappa [37]

where grounded or emulsion bu󰀨alo meat products were list-

ed: patties, sausages, burgers, restructured meat di󰀨erently

[38] also using sodium alginate and carrageenan [39], enrobed

meat. Natural emulsiers, conservatives, and polyphenols were

used in these products to extend the shelf life and consumer

TABLE V

LONG CHAIN PUFA N3 FATTY ACIDS (% OF TOTAL FAME)

ON LONGISSIMUS THORACIS OF DIFFERENT SPECIES

Bu󰀨alo Beef Yak RMSE

C20:5n3 EPA 0.347b0.304b0.814a0.301

C22:5n3 DPA 0.942b0.557c1.425a0.323

C22:6n3 DHA 0.097 0.087 0.117 0.081

Di󰀨erent letters on row indicate signicant di󰀨erences per p<0.05.

Data: CREA not published

TABLE VI

CONTENT IN NEU5GC AND NEU5AC ON LONGISSIMUS

THORACIS OF DIFFERENT SPECIES [33]

Species Neu5Gc

µg/g protein

Neu5Ac

µg/g protein

Neu5Ac/

Neu5Gc

Beef 228.3a432.5b1.8b

Bu󰀨alo 82.7c512.6a6.2a

Yak 145.7b508.5a3.5b

RMSE 51.4 103.5 2.3

Di󰀨erent letters on column indicate signicant di󰀨erences per p<0.05

acceptability [40]. Shelf-stable, ready-to-eat, spiced pickle-type

bu󰀨alo meat was also produced [41].

The addition of fat to these products brings an improve-

ment in juiciness and palatability. Of all the fats, pork appears

to respond better to the technological transformations of bu󰀨alo

meat.

Bu󰀨alo meat can also be used for numerous prepara-

tions involved in the drying and salting processes. These cured

products can be obtained with whole cuts of meat and derived

from ground meat supplemented with pork fat. By way of exam-

ple, we report some processed products obtained in Italy with

bu󰀨alo meat:

Bresaola

Bresaola of bu󰀨alo meat, like beef meat GPI product

(EEC 1263/96), a typical product of Valtellina (north Italy), is

produced by salting and curing di󰀨erent cuts of hindquarters. A

strict trimming process is essential to give a unique avor.

Legs of beef are defatted and seasoned with a dry rub

of salt and spices, such as juniper berries, cinnamon, and nut-

meg. They are then left to cure for a few days. The drying pe-

riod is between one and three months. The meat loses up to

40% of its original weight during aging.

Carne salada

Carne salada is obtained with the topside of adult ani-

mals. The cuts, cleaned of all fat and tendinous parts, are sprin-

kled with a mixture of salt and other ingredients and placed in a

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container where they will remain from 2 to 5 weeks, depending

on the size of the individual pieces. During the entire matura-

tion period, the carne salada must be kept in a dark room at a

maximum temperature of +12 °C and massaged at least every

2/3 days.

Slacci

Slacci is a typical product of the Veneto region, usually

obtained with horse meat, but bu󰀨alo meat also has excellent

qualitative performances. The strips of accid meat are pre-

pared with very lean meat cut into thin slices along the ber. It is

put in brine for about 15 days, seasoned for about one month,

and nally beaten. The meat bers separate, forming dry la-

ments of a deep red color.

CONCLUSION

Bu󰀨alo meat has valuable organoleptic and nutritional

characteristics. Scientic information must be disseminated,

informing consumers that this product is lean and could be in-

tegrated into the modern diet, with obvious health advantages.

The nutritional and technological potentiality of bu󰀨alo

meat is considerable; it is necessary to create an e󰀩cient and

dynamic market for both fresh and cured products, bringing ad-

vantages to breeders who are in this way encouraged to sup-

port and spread a meat production chain just as the production

of mozzarella and dairy products has spread in many countries.

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