Proposing standard cutting and fabrication concepts for the Korean goat industry: Anatomical, practical, and industrial perspectives

Son, Woo-Young; Hwang, Jun; Na, Yu-Jeong; Youn, Ju-Hui; Choi, Joon-Hwan; Wi, Cheon-Hwang; Kang, Geun-Ho; Kang, Sun-Moon; Yang, Han-Sul; Kim, Hyun-Wook

doi:10.5851/fl.2500030

Food Life 2026(1):23-31

eISSN: 2714-0865

DOI: https://doi.org/10.5851/fl.2500030

Review Article

Proposing standard cutting and fabrication concepts for the Korean goat industry: Anatomical, practical, and industrial perspectives

Woo-Young Son¹

, Jun Hwang¹

, Yu-Jeong Na¹

, Ju-Hui Youn¹

, Joon-Hwan Choi¹

, Cheon-Hwang Wi¹

, Geun-Ho Kang²

, Sun-Moon Kang²

, Han-Sul Yang³

, Hyun-Wook Kim¹^,⁴^,^*

Author Information & Copyright ▼

¹Division of Animal Bioscience & Integrated Biotechnology, Gyeongsang National University, Jinju 52828, Korea

²Animal Products Utilization, National Institute of Animal Science, Rural Development Administration (RDA), Wanju 55365, Korea

³Division of Applied Life Science (BK21Four), Gyeongsang National University, Jinju 52828, Korea

⁴Department of GreenBio Science, Gyeongsang National University, Jinju 52725, Korea

^*Corresponding author : Hyun-Wook Kim. Division of Animal Bioscience & Integrated Biotechnology, Gyeongsang National University, Jinju 52828, Korea. Tel: +82-55-751-3261, Fax: +82-55-751-3267, E-mail: hwkim@gnu.ac.kr

© Copyright 2026 Korean Society for Food Science of Animal Resources. This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Received: Nov 02, 2025; Revised: Dec 30, 2025; Accepted: Jan 15, 2026

Published Online: Mar 31, 2026

Abstract

The Korean native black goat industry is transitioning from the use of black goats for traditional medicinal purposes to meat production, driven by rising consumer demand for low-fat, high-protein, and health-oriented foods. However, standardized carcass cutting and fabrication systems are currently lacking, limiting industrial development. In this review we outline the anatomical and industrial characteristics of native Korean black goats (Capra hircus coreanae) and propose a framework for establishing species-specific cutting standards. Direct application of beef or pork cutting systems is not suitable for black goats due to their small carcass size and distinct muscle distribution. Currently, domestic carcass division is limited to three major parts–the forequarter, middle body, and hindquarter–without unified guidelines, leading to inconsistencies in classification, pricing, and distribution. Major goat-producing countries including Australia and New Zealand have adopted standardized carcass grading and cutting systems to improve product quality, consistency, and market competitiveness. Therefore, we recommend a three-primal cutting and ten-subprimal fabrication framework, reflecting the anatomical and market characteristics of Korean native black goats. Implementing standardized fabrication criteria will enhance carcass utilization, ensure transparent trade, and strengthen domestic and global competitiveness of the Korean goat industry.

Keywords: Korean native black goat; carcass cutting and fabrication standardization; anatomical and structural characteristics

Introduction

The Korean goat industry is at a turning point owing to the rapid expansion of production scale and consumer demand for goat meat, with its production value increasing nearly three-fold, from 59.5 billion Korean Won (KRW) in 2018 to 187.7 billion KRW in 2023 (Statistics Korea, 2023). This trend is mirrored in slaughter statistics, which increased from 284,121 head in 2015 to 572,305 head in 2019, and remained relatively high at 423,430 head in 2023 (MAFRA, 2024). Traditionally, goat meat in Korea has been consumed as a medicinal food, typically in the form of hot water extracts with herbal ingredients (Choi et al., 2022). Following the COVID-19 pandemic, its consumption as a health-promoting supplement has further increased, reflecting growing public interest in immune system-enhancing products. In Korea, goat meat has recently gained attention as a low-fat, high-protein meat resource, leading to the increased demand for fresh lean cuts (Kim et al., 2019a).

In the meat industry, traceability systems, carcass quality grading standards, and standardized cutting and fabrication criteria collectively constitute a fundamental framework for ensuring safe distribution, fair trade, transparency, industrial efficiency, and consumer confidence in meat products (Kongsro et al., 2026). In Korea, livestock product management is primarily regulated through national systems that oversee slaughter inspection, hygiene control, and distribution traceability, including mandatory animal identification, slaughterhouse inspection, and product labeling requirements. While these systems effectively ensure food safety and traceability, they are mainly designed around carcass grading and sanitary management, with limited emphasis on standardized cutting and fabrication criteria for minor livestock species such as goats. After slaughter, livestock carcasses are partitioned according to the established cutting and fabrication methods based on their anatomical and physiological characteristics, including muscle structure and location and distribution of fat and connective tissue, that directly influence the eating quality attributes of meat (Listrat et al., 2016). Furthermore, the muscle fiber profile and connective tissue density are closely related to meat tenderness and processing characteristics, making them key factors in determining the appropriate cutting and fabrication criteria. Therefore, establishing standardized cutting and fabrication criteria must reflect these intrinsic quality differences, which can maximize the economic and informational value of each cut, while facilitating systematic distribution and rational pricing throughout the market.

From a consumer perspective, standardized cutting and fabrication criteria affect purchase decisions and shape the perception of meat quality (Glitsch, 2000). Specific and consistent names and classification of cuts directly influence market demand by improving product transparency and consumer perception clarity. Moreover, standardization systems considering each country’s culinary culture and cooking style enhance product acceptance and promote trust in the domestic and international markets (Tibebu et al., 2024).

In Korea, however, standardized cutting and fabrication criteria, which serve as fundamental guidelines for the efficient distribution and utilization of fresh goat meat, are currently lacking, limiting industrial growth. Therefore, establishing standardized cutting and fabrication systems specifically tailored to both intrinsic and extrinsic characteristics will enhance product consistency, consumer trust, and industrial competitiveness. This review proposes a conceptual framework that integrates anatomical, technological, consumer, and industrial perspectives to guide practical and applicable standardized cutting and fabrication criteria for Korean goat meat.

Overview of Korean Native Black Goats

Korean native black goats (Capra hircus coreanae) are indigenous breeds that have been maintained for centuries to adapt to the Korean living environment. Their external appearance is characterized by black hair, curved horns, and small body size, with an average mature weight of 30–50 kg, lower than that of Boer goats and other commercial meat breeds (Kim et al., 2019a). Four distinct regional lineages of black goats, Dangjin, Jangsu, Gyeongsang National University, and Tongyeong, have been identified, each reflecting adaptation to specific local ecological and feeding conditions (Kang et al., 2023). Although relatively small in body size, Korean native black goats exhibit strong disease resistance, efficient feed utilization, and high survival in mountainous and low-input farming systems, making them valuable genetic resources for sustainable production (Park et al., 2025).

Genetic analyses have shown the development of genetic introgression in exotic breeds, such as Boer and Saanen (Kim et al., 2019a). Partial introgression is also detectable in certain farm-raised populations, reflecting ongoing efforts to enhance growth performance and production efficiency under practical farming conditions. Moreover, Korean native black goats have cultural and economic significance. Traditionally consumed as a medicinal food for its high protein and mineral content, recently goat meat is increasingly valued as a low-fat, high-protein source suitable for fresh meat production (Choi et al., 2023; Kim et al., 2022). To encourage consumer preference for healthier and more sustainable meat products, it is essential to establish standardized cutting and fabrication criteria that reflect the anatomical characteristics and practical applications of this indigenous breed, thereby facilitating its broader adoption in modern meat markets. Recent statistics also show a clear rise in demand for black goat meat in Korea, with the domestic black goat population increasing by more than 70% from 2012 to 2021 and imports growing substantially in recent years, reflecting consumers’ heightened interest in healthier and more sustainable protein sources (Statistics Korea, 2023). Although the differences among regional lineages are relatively small, variations in body size, growth rate, and muscle development may lead to subtle changes in carcass yield and intramuscular fat distribution. These characteristics suggest that such lineage-based differences should be considered when establishing more refined and evidence-based cutting standards in the future.

Anatomical Characteristics of Korean Native Black Goats

Korean native black goats are ruminants, and their overall skeletal structure follows the anatomical arrangement observed in cattle. The axial skeleton, composed of the spine, ribs, scapula, and limb bones, is similar to that of other ruminant species (Lee et al., 2025; Singh, 2017). However, the proportional development of individual body parts and the overall carcass size are more comparable to those of pigs than to cattle, which is an important consideration when designing slaughtering, cutting, and fabrication systems, making the direct adoption of beef or pork cutting standards not applicable (Son, 1999). By contrast, beef tenderloins typically weigh approximately 2.7–3.2 kg (primarily steers, aged 18–24 months), pork tenderloins weigh approximately 1.2 kg (primarily barrows, aged 22–26 weeks), and goat tenderloins typically weigh approximately 0.71 kg (primarily steers, aged 5–6 months; Chao et al., 2024; Segura et al., 2023; Wang et al., 2025). Therefore, systematic anatomical assessment is required to clarify the morphological characteristics of Korean native black goats for the development of species-specific cutting and fabrication criteria.

Korean native black goats possess 13 pairs of ribs, similar to most goat and pig species, which serve as crucial reference points for delineating the forequarter, middle body (including the ribs, loin, and belly), and hindquarter regions of the carcass (Constantinescu, 2001). Owing to their relatively small carcass size and lower weight compared with cattle, segmented division and simplified fabrication units are preferable, particularly when defining the loin and abdominal sections. The forelimb region exhibits a distinct muscular configuration around the scapula, providing a clear anatomical reference for establishing cutting lines. In the loin and abdominal regions, the junction between the lumbar vertebrae and iliac bones marks the primary boundary for carcass division, whereas in the hind limb, well-developed femoral and gluteal muscle groups necessitate finer segmentation for practical processing (Ali et al., 2021). These anatomical distinctions underscore why cattle-based fabrication schemes are not directly applicable to Korean native black goats. In particular, the junction between the lumbar vertebrae and the ilium in Korean native black goats is shorter than that of cattle and narrower and less robust than that of pigs, which may increase the risk of excessive muscle loss when applying cattle-based cutting lines. Furthermore, the fascial structure around the scapular region is relatively complex compared with cattle, making it difficult to obtain anatomically clear boundaries when existing bovine cutting schemes are directly applied.

In summary, although Korean native black goats share a ruminant skeletal framework with cattle, their overall body size (approximately 50–60 kg live weight) is far smaller than that of beef cattle (typically >600 kg live weight) and is closer to that of commercial pigs (approximately 100–120 kg live weight), resulting in regional muscle development patterns that resemble pigs rather than large-bodied cattle (Uyen et al., 2023). Therefore, the development of species-specific cutting and fabrication standards for Korean native black goats should appropriately balance the anatomical characteristics common to both cattle and pigs (Brassard et al., 2024).

Current Practices and Challenges in Carcass Cutting of Korean Native Black Goats

Despite increased demand for goat meat, a standardized carcass cutting and fabrication system is lacking, revealing the industrial limitations of the domestic retail sector (Anneke et al., 2025; Moon et al., 2021). Goat carcasses in Korea are typically separated into three primary sections—the forequarter, middle body (ribs, loin, and belly), and the hindquarter— followed by partial deboning before distribution to restaurants, health food stores, and general households (Anneke et al., 2025). As illustrated in Fig. 1, which depicts the proposed carcass sectioning scheme, the forequarter is generally separated at the 5th to 6th attached ribs; the middle body section comprises the loin, ribs, and belly; and the hindquarter is obtained by disarticulating the femur joint and removing the lower shank. This simplified cutting approach considers the small carcass size of black goats but presents several structural limitations (Saengsuk et al., 2024). From a consumer perspective, the lack of standardized retail cuts restricts selection diversity and creates confusion among producers, distributors, and consumers due to inconsistent names and cutting shapes (Choi, 2023), hindering accurate price estimation and quality comparison, consequently limiting the consumption of traditional dishes such as bulgogi (Korean soy sauce-marinated meat), hot pots, and soups (Park et al., 2020).

Fig. 1. Proposed cuts of goat carcass. The carcass is divided into three main sections (forequarter, middle body, and hindquarter) with corresponding wholesale cuts. Data from .

Download Original Figure

Major goat-producing countries such as Australia and New Zealand have standardized carcass division and fabrication systems comparable to those used for beef and lamb. Although Australia’s AUS-MEAT system defines standardized primal cuts for large, export-oriented goat carcasses, direct application to Korean black goats is limited by their smaller carcass size and domestic market orientation. Nevertheless, because Korean black goats share a ruminant skeletal framework with cattle, the AUS-MEAT primal structure (Table 1) can serve as an anatomical reference, while practical implementation in Korea requires simplified, locally adapted cutting strategies. Moreover, alternate fabrication formats—including whole carcasses and six-way cuts—have been implemented according to the specifications of key trading partners including the United States, Korea, China, and Canada (Fig. 2). Furthermore, fat-trimming levels and packaging requirements are customized according to market demand, providing flexibility, thus strengthening export competitiveness. Since 2018, imports of goat meat from Australia and New Zealand have consistently increased, with Australian products accounting for approximately 98.8% of the total imports to Korea, largely due to tariff reductions following the Korea–Australia and Korea–New Zealand Free Trade Agreements (Lee, 2025).

Table 1. Major primal cuts of goat carcass with their common names and corresponding Handbook of Australian Meat (HAM) code numbers standardized for international trade

Common name	Cutting name	HAM number
Shank	Foreshank	5,030
Shank	Hindshank	5,031
Tenderloin	Tenderloin butt off	5,082
Tenderloin	Butt tenderloin	5,081
Loin	Backstrap	5,109
	Eye of loin	5,150
	Rack	4,932
	Rack cap on	4,756
	Rack cap off	4,764
Leg	Chump on	4,800
	Chump off	4,820
	Leg chump on (ABR)	4,801
	Leg shank bone	4,821
	Square cut shoulder	4,990
	Shoulder-oyster cut	4,980
	Shoulder-banjo cut	4,995
Neck	Neck	5,020
Flank	Breast and flap	5,010

Download Excel Table

Fig. 2. Export value of Australian goat meat to the top four global markets (United States, Korea, China, and Canada) from 2017 to 2023. Data from .

Download Original Figure

Current Utilization of Korean Native Black Goats in the Food Service Sector

In Korea, native black goats have long been recognized as a traditional health food valued for their nutritional properties, including high levels of protein, amino acids, and iron, which are associated with various health-promoting effects (Kim et al., 2019b). In the past, native black goat consumption in Korea showed distinct regional characteristics (Son, 1999). Based on an online survey conducted by the authors (including restaurant menus, franchise websites, and regional food-related online sources), clear regional differences were identified in consumption patterns and preferred cuts of Korean native black goat meat.

In Jeolla Province, Korean native black goat meat has traditionally been utilized across a wide range of cuts, including ribs, loins, legs, and offal, reflecting a cuisine-oriented approach that emphasizes grilling, pan-frying, and seasoned dishes. The development of restaurant franchises originating from this region has contributed to the nationwide dissemination and commercialization of these preparation styles, positioning Jeolla cuisine as a key driver in the modernization of black goat meat consumption.

Although Chungcheong Province hosts a large number of black goat farms, its utilization patterns remain relatively limited in terms of region-specific dishes. Goat meat produced in this region is primarily processed and distributed to other provinces, reinforcing its role as a raw material supply base rather than a center of culinary innovation.

In Gyeongsang Province, farm-based restaurants commonly employ a diversified utilization strategy, applying different cuts to boiling, grilling, raw meat dishes, and processed products. The active use of secondary cuts and by-products in this region reflects a practical, whole-carcass utilization approach that enhances menu diversity and economic efficiency.

Gangwon Province, characterized by mountainous terrain suitable for goat farming, emphasizes health-oriented preparations, including soups, stews, and grilled dishes often combined with local medicinal ingredients. This regional pattern highlights the close association between black goat meat consumption and wellness-focused culinary traditions.

In the capital region, where regional food cultures converge, Korean native black goat meat is utilized in both traditional health-focused dishes and modern fusion menus. This trend reflects urban consumer preferences for convenience, variety, and novel culinary applications, supported by advanced distribution and food service infrastructures.

Taken together, these regional utilization patterns demonstrate that, while culinary expressions differ, the fundamental use of carcass components remains broadly similar across regions. The gradual convergence toward standardized menus and centralized processing underscores the growing importance of unified cutting and fabrication criteria to support consistent quality, pricing, and product development in the expanding goat meat market.

Recommendation on Cutting Method for Korean Native Black Goat

Based on the anatomical characteristics and relatively small carcass size of Korean native black goats, a half-carcass division incorporating a three-primal cutting and ten-subprimal fabrication system is recommended to improve the processing efficiency and market utilization (Fig. 1). The boundaries between primal and sub-primal cuts were defined using reproducible anatomical landmarks, including rib count, vertebral transitions, major joint structures, and natural fascial planes, to ensure consistent fabrication while minimizing muscle loss and improving applicability compared with cattle-based cutting schemes. According to the compositional data presented in Fig. 1, the forequarter exhibits a fat content ranging from approximately 1.9% to 4.02%, which can be categorized as medium-to-low-fat. Within this section, most muscles have between 1.9% and 2.9% fat content, whereas the foreshank contains relatively more connective tissue and a slightly elevated fat level (4.02%), contributing to the upper limit of the range. The middle body contains 1.74%–4.10% fat content, with most muscles displaying intermediate fat levels, whereas the belly (flap) represents a localized high-fat area with approximately 4.35% fat. In contrast, the hindquarter shows a distinctly low-fat profile of 1.44% to 2.45% (Saengsuk et al., 2024). These classifications were used to describe the relative fat distribution and guide the recommended culinary applications for each primal region.

Forequarter: This section includes the shoulder, neck, and anterior ribs (up to the 5th–6th rib). Muscles in this region contain a moderate amount of connective tissue and medium-to-low fat, making them suitable for boiling, stewing, or slicing.

Middle body: This section extends from the posterior ribs to the lumbar vertebrae, and contains the ribeye, loin, and belly muscles. It is characterized by intermediate to high fat content and good tenderness, making it ideal for grilling.

Hindquarter: This section includes the leg and hip regions, primarily composed of the femoral and gluteal muscle groups. These muscles are low in fat and slightly tougher but flavorful, making them suitable for slicing, marinating, or processing into value-added products such as sausages or ready-to-cook meat.

Each primal section can be further divided into smaller sub-primal cuts according to muscle structure, cooking method, and market preference. For example, the hind legs can be separated into the semimembranosus, semitendinosus, and biceps femoris muscles to produce various product types. Establishing this standardized cutting framework will increase carcass yield and price transparency, and facilitate the development of diverse goat meat products that reflect consumer preferences and culinary styles.

Research Perspectives on the Future Development of the Korean Goat Industry

To ensure further growth and competitiveness, future research should adopt a multidisciplinary approach that connects animal science, food technology, and policy innovation. In Korea, where black goats are mainly raised for medicinal purposes, recent research has begun to focus more on meat-oriented breeding and industrial applications, especially in areas such as carcass standardization, quality grading, and value-added product development (Abhijith et al., 2023).

From a technological viewpoint, future studies should aim to establish data-driven cutting and fabrication systems supported by anatomical, biochemical, and imaging analyses. Computed tomography (CT) and 3D carcass modeling can provide precise structural information. Combining these approaches with molecular and proteomic techniques will deepen our understanding of factors that influence meat tenderness, flavor, and functional properties, thereby supporting scientifically validated differentiation among proposed cuts (Anderson et al., 2015). In addition, sustainable production systems such as smart farming technologies and resource-efficient management remain important, but their relevance lies primarily in providing uniform animals and production conditions, which in turn enhances the reliability of standardized cutting and grading systems (Teixeira et al., 2020).

Taken together, research that effectively links scientific innovation, industrial practices, and institutional standardization will aid the advancement of the Korean goat industry. These multidisciplinary approaches will enable the coordinated evolution of production, processing, and marketing systems, while enhancing export potential through compatibility with international carcass and cut classification frameworks such as AUS-MEAT and IMPS, thereby supporting global competitiveness and sustainability in the meat industry.

Conclusion

The Korean native black goat industry is transforming from its traditional medicinal role to a modern meat production system. However, commercially raised goats in Korea show substantial genetic heterogeneity due to extensive crossbreeding, leading to marked variability in carcass traits and highlighting the need to establish fixed and reproducible carcass characteristics as a prerequisite for effective standardization and industrial development. Also, the lack of standardized cutting and fabrication criteria limit industrial development. This review highlights that species-specific anatomical characteristic necessitate three-primal cutting and ten-subprimal fabrication concepts comprising the forequarter (shoulder loin, front rib, shoulder, and foreshank), middle body (loin, rib, and belly), and the hindquarter (round, hind leg, and hindshank) to ensure efficient processing, fair trade, and transparent product classification. Establishing such a standardized system would enhance consumer confidence, improve carcass utilization, and strengthen the overall industry competitiveness. Future advancements will rely on the integration of scientific innovation with institutional support, particularly in the development of carcass grading, labeling, and pricing systems suited for improved goat strains. Moving toward a unified and evidence-based standard will increase domestic self-sufficiency and position Korean goat meat as a globally recognized, high-quality, and sustainable protein source.

Conflicts of Interest

The authors declare no potential conflict of interest.

Acknowledgments

This study was supported by the Cooperative Research Program for Agricultural Science and Technology Development (Project No. RS-2025-02216992) of the Rural Development Administration, Republic of Korea.

Ethics Approval

This article does not require IRB/IACUC approval because there are no human and animal participants.

Author Contributions

Conceptualization: Kang G, Kang SM, Yang HS, Kim HW.

Data Curation: Son WY, Hwang J, Youn J, Choi J, Wi C.

Methodology: Kang G, Kang SM, Yang HS, Kim HW.

Software: Son WY.

Validation: Kim HW.

Investigation: Kang G, Kang SM, Yang HS, Kim HW.

Writing-original draft: Son WY, Kim HW.

Writing-review & editing: Son WY, Hwang J, Na Y, Youn J, Choi J, Wi C, Kang G, Kang SM, Yang HS, Kim HW.

References

Abhijith A, Warner RD, Dunshea FR, Leury BJ, Ha M, Chauhan SS. 2023. A review of some aspects of goat meat quality: Future research recommendations. Anim Prod Sci 63:1361-1375.

Ali M, Choi YS, Nam KC. 2021. Physicochemical attributes, free amino acids, and fatty acids of the five major cuts from Korean native black goat. Anim Ind Technol 8:23-33.

Anderson F, Pethick DW, Gardner GE. 2015. The correlation of intramuscular fat content between muscles of the lamb carcass and the use of computed tomography to predict intramuscular fat percentage in lambs. Animal 9:1239-1249.

Anneke, Sujiwo J, Jang A. 2025. Korean native black goat: A review on its characteristics and meat quality. Food Sci Anim Resour 45:329-352.

Brassard MÈ, Chouinard PY, Tremblay GF, Gervais R, Pouliot É, Tessier L, Cinq-Mars D. 2024. Growth performance, carcass characteristics, and meat quality in meat and dairy goat kids fed a concentrate-based diet or allotted to an intensive rotational grazing system. Can J Anim Sci 104:488-502.

Chao MD, Ma D, Jeneske H, Pokharel S, Moallem JT, Stephens LN, Debus AD, Reynolds E, Kang I. 2024. Skin-on and skin-off processing methods affect processing efficiency, product yield and meat quality of goat carcass. Int J Food Sci Technol 59:7053-7062.

Choi DM, Kang KM, Kang SM, Kim HY. 2023. Physicochemical properties of black Korean goat meat with various slaughter ages. Animals 13:692.

Choi Y, Jeong JY, Gu M, Jeon DH, No Y, Park JY, Nam KC. 2022. Survey of actual consumption conditions and consumer perception of black goat. Proceedings of the 2022 Korea Academia-Industrial Cooperation Society, Jeju, Korea. pp. 467-469.

Constantinescu GM. 2001. Guide to regional ruminant anatomy based on the dissection of the goat. John Wiley & Sons, Hoboken, NJ, USA.

10.

Glitsch K. 2000. Consumer perceptions of fresh meat quality: Cross-national comparison. Br Food J 102:177-194.

11.

Kang HC, Kim EH, Myung CH, Kim JY, Song SH, Yang DY, Sun CW, Lim HT. 2023. A study on conservation value evaluation of native black goat using microsatellite (MS) marker information. J Anim Breed Genom 7:37-44.

12.

Kim HJ, Kim HJ, Jang A. 2019a. Nutritional and antioxidative properties of black goat meat cuts. Asian-Australas J Anim Sci 32:1423-1429.

13.

Kim HJ, Kim HJ, Kim KW, Lee J, Lee SH, Lee SS, Choi BH, Shin DJ, Jeon KH, Jeon JY, Jang A. 2022. Effect of feeding alfalfa and concentrate on meat quality and bioactive compounds in Korean native black goat loin during storage at 4°C. Food Sci Anim Resour 42:517-535.

14.

Kim JY, Jeong S, Kim KH, Lim WJ, Lee HY, Kim N. 2019b. Discovery of genomic characteristics and selection signatures in Korean indigenous goats through comparison of 10 goat breeds. Front Genet 10:699.

15.

Kongsro J, Skramstad TEB, Alvseike O. 2026. Carcass and meat quality and innovation in fresh meat industry. Meat Sci 231:109960.

16.

Lee ED, Tomple BM, Kim GE, Kim DK, Choi BH, Kim KW. 2025. Evaluation of morphological and growth characteristics among three Korean native black goat strains. J Anim Plant Sci 35:602-611.

17.

Lee M. 2025. Goat meat imports increase fivefold in 10 years; self-sufficiency rate drops. Rural Development Administration (RDA). Available from: https://nongsaro.go.kr/portal/ps/psx/psxs/newsMainView.ps?newsSeqNo=128784&menuId=PS65437. Accessed at Sep 10, 2025.

18.

Listrat A, Lebret B, Louveau I, Astruc T, Bonnet M, Lefaucheur L, Picard B, Bugeon J. 2016. How muscle structure and composition influence meat and flesh quality. Sci World J 2016:3182746.

19.

Ministry of Agriculture, Food and Rural Affairs [MAFRA]. 2024. Livestock statistics and policy information. MAFRA. Available from: https://www.mafra.go.kr. Accessed at Nov 22, 2025.

20.

Moon SH, Yun YS, Kim NY, Chung S, Zhang QM, Tang Y, Lee SH, Lee J, Sung SH, Oh M. 2021. Determination of maintenance energy requirements for fattening castrated Korean black goats (Capra hircus coreanae). Animals 11:1543.

21.

Park GS, Kwon WJ, Seo BJ, Kim C. 2025. Infectious disease challenges in Korean native black goats (KNBGs): Current status, control needs and strategic approaches. J Infect Dis Diagn 10:308.

22.

Park JY, Lee SY, Choi YS, Nam KC. 2020. Quality characteristics of low-fat black goat sausage using loquat leaf. J Agric Life Sci 54:59-65.

23.

Saengsuk N, Sangsawad P, Paengkoum P, Pongsetkul J. 2024. Lipid and volatile profiles of various goat primal cuts: Aspects of nutritional value and flavor/taste attributes. Foods 13:492.

24.

Segura J, Aalhus JL, Prieto N, Zawadski S, Scott H, López-Campos Ó. 2023. Prediction of primal and retail cut weights, tissue composition and yields of youthful cattle carcasses using computer vision systems; whole carcass camera and/or ribeye camera. Meat Sci 199: 109120.

25.

Singh B. 2017. Dyce, Sack, and Wensing's textbook of veterinary anatomy. 5^th ed. Saunders, St. Louis, MO, USA.

26.

Son YS. 1999. Production and uses of Korean native black goat. Small Rumin Res 34:303-308.

27.

Statistics Korea. 2023. Agricultural and livestock products statistics. Korean Statistical Information Service (KOSIS). Available from: https://kosis.kr/statHtml/statHtml.do?orgId=114&tblId=DT_114_2014_S0003&conn_path=I2. Accessed at Sep 9, 2025.

28.

Statistics Korea. 2025. Customs service export & import trade statistics. Korea Customs Service. Available from: https://tradedata.go.kr/cts/index.do. Accessed at Sep 10, 2025.

29.

Teixeira A, Silva S, Guedes C, Rodrigues S. 2020. Sheep and goat meat processed products quality: A review. Foods 9:960.

30.

Tibebu A, Tamrat H, Bahiru A. 2024. Review: Impact of food safety on global trade. Vet Med Sci 10:e1585.

31.

U.S. Department of Agriculture, Agricultural Marketing Service. 2001. Institutional Meat Purchase Specifications (IMPS): Fresh goat series 11. Available from: https://www.ams.usda.gov/sites/default/files/media/GoatIMPS%5B1%5D.pdf. Accessed at Oct 22, 2025.

32.

Uyen NT, van Cuong D, Thuy PD, Son LH, Ngan NT, Quang NH, Tuan ND, Hwang IH. 2023. A comparative study on the adipogenic and myogenic capacity of muscle satellite cells, and meat quality characteristics between Hanwoo and Vietnamese yellow steers. Food Sci Anim Resour 43:563-579.

33.

Wang Y, Bush J, Bohrer BM. 2025. Meat quality attributes and sensory characteristics for pork tenderloins (m. psoas major). Meat Muscle Biol 9:20244.

34.

Webb EC. 2014. Goat meat production, composition, and quality. Anim Front 4:33-37.

35.

Yang L, Li S, Hou J, Tang Z, Shi B, Luo Y, Wang J, Zhao F. 2025. Variation in intramuscular fat deposition of goats and sheep and its correlation with gut microbiota. Foods 14:1885.