2.1. Sample Collection and Preparation
2.1.1. Product Collection
Product sampling was designed to be representative of the United States (U.S.) supply merchandised in retail markets. Retail packages of raw beef heart, liver, kidney, tongue, honeycomb tripe, oxtail, and marrow bones were obtained from three different processing facilities (Texas, Nebraska, and Kansas) in the United States, to provide national representation of retail-ready beef offal items. Beef testicles were obtained from a single supplier in Colorado. Edible beef blood was obtained from a single processing facility in Pennsylvania.
Item name, description, and International Meat Purchasing Specifications (IMPS) identifier for each item are found in
Table 1. From each of the three suppliers, beef heart, liver, kidney, tongue, honeycomb tripe, oxtail, and marrow bones were collected on two separate days, at least seven days apart. A minimum of four packages per collection date were procured of heart, liver, kidney, tongue, honeycomb tripe, and oxtail for a total of eight packages per item. Eight packages of vacuum sealed retail-ready marrow bone slices were obtained from the Kansas facility; femur bones were obtained from the Texas and Nebraska facilities and were sliced and vacuum sealed at the Colorado State University (CSU) Meat Lab to match the specifications of those collected from Kansas. Beef heart, liver, kidney, tongue, honeycomb tripe, oxtail, and marrow bones were maintained at 0–4 °C during transportation to the CSU Meat Laboratory. Upon arrival, packages were inspected for packaging integrity, and any packages with lack of a preserved seal were vacuum sealed immediately. All packages and containers were stored in a dark environment at 0–4 °C for 7 days post-production prior to being frozen at −20 °C for a minimum of 48 h, until dissection.
Three separate containers (4.0 kg each) of defibrinated edible beef blood were utilized, all from the Pennsylvania supplier. Three packages of testicles were used, all from a single supplier in Colorado. Beef blood and testicles were frozen to below 0 °C at each processing facility, maintained a temperature of below 0 °C during transport to the CSU Meat Laboratory, and stored at −20 °C upon arrival at the CSU Meat Laboratory until dissection.
2.1.2. Dissection
Beef offal items were tempered in a single layer at 0–4 °C for 24–72 h, depending on item thickness, until the internal temperature reached 0–4 °C. After thawing, each individual sample was weighed with the packaging to the nearest 0.1 g, then removed from the package, and weighed to the nearest 0.1 g. The sample was blotted to remove any surface moisture and weighed again to the nearest 0.1 g. The internal temperature and start dissection time were recorded for each sample. The entire piece or pieces within a package were utilized for dissection. Post-dissection separable component weights and end dissection times and temperatures were recorded for each item. Dissections were performed using standard methods, including limited exposure to light, and use of powder-free nitrile gloves to protect nutrients from degradation. Dissections were performed by CSU personnel in a 5–7 °C environment using disposable stainless-steel scalpels (Integra Miltex, York, PA, USA) to yield separable components.
Separable components were defined as follows: separable lean tissue included any lean muscle or organ tissue, intramuscular fat, and light connective tissue deemed edible; external fat included adipose tissue located on the outer surface of the cut; internal fat, also known as seam fat, included adipose tissue deposited between lean tissue; refuse included all waste, comprised primarily of bone and heavy inedible connective tissue. For liquid items and items requiring no dissection (tripe, testicles, blood), separable lean tissue was used to describe the total sample. A yield tolerance of 97.0–100.0% was established prior to dissection. Any samples not meeting yield tolerance were removed from the study and replaced with a new sample of the same item, origin, and collection date. For dissected items, a total of three packages of each item from a single origin and collection date were used for homogenization, after meeting yield tolerance. Each of the separable components from each sample, excluding refuse, were homogenized individually immediately following dissection. Honeycomb tripe was procured following specification criteria of being practically devoid of external fat resulting in no dissection. Any tripe samples not meeting this criterion were trimmed at the CSU Meat Lab prior to homogenization. The testicles were devoid of fat, and the outer membrane of the testicle was removed at the processing facility; therefore, no dissection was necessary. Due to the liquid and homogeneous nature of the blood, the item was not altered prior to being frozen.
2.1.3. Homogenization
For non-liquid items (heart, liver, kidney, tongue, oxtail, bone marrow, tripe, testicles), each separable component derived from a single package was homogenized; resulting in one lean sample per package, in addition to one external fat and one internal fat sample for each package, if present. Standard methods of homogenization were adhered to, including homogenizing with the use of powder-free nitrile gloves and in the absence of direct light to protect samples from contamination and nutrient degradation [
11]. Separable lean tissue from each package was cut into 2.5 cm
3 pieces and placed into a stainless steel strainer inside a stainless steel bowl containing liquid nitrogen until all pieces were completely frozen. The pieces were transferred into a 6.62-L Robot Coupe BLIXER 6V (Robot Coupe USA Inc., Ridgeland, MS, USA). Samples were blended for approximately 10 s at 1500 rpm and 30 s at 3500 rpm until a fine-powder consistency was reached. Immediately following homogenization, each sample was placed into a 710 mL Whirl-Pak bag using a stainless-steel spoon that was dipped in liquid nitrogen for 10 s before use. Each sample bag was placed into a −20 °C freezer immediately. External and internal fat samples were frozen following the same procedures as with lean tissue. After samples were frozen, samples were placed into a 3.79-L Robot Coupe BLIXER 4V (Robot Coupe USA Inc., Ridgeland, MS, USA) and blended into a finely powdered consistency under the same time and speed protocols as with lean homogenization. Fat samples were immediately placed into 532-mL Whirl-Pak bags using a stainless-steel spoon dipped in liquid nitrogen for 10 s before use. Sample bags were immediately placed into a −20 °C freezer.
Edible beef blood was homogenized using the same technique. One full container of blood, as procured, was blended in a 3.79-L stainless steel blender (Waring, Stamford, CT, USA). After blending, a stainless-steel ladle was drawn through the liquid from the bottom of the blender upward, and a 60 mL syringe (Medtronic, Minneapolis, MN, USA) was used to extract the liquid from the ladle. The syringe was used to create droplets that were dropped into a fine mesh strainer inside a stainless-steel bowl filled with liquid nitrogen. This procedure was repeated until at least 300 g of the sample was frozen as droplets. Samples were immediately placed into 710-mL Whirl-Pak bags using a stainless-steel spoon that was dipped in liquid nitrogen for 10 s before use. Each sample bag was immediately placed into a −20 °C freezer.
After samples were prepared each day, samples were double bagged and transferred from a −20 °C freezer into a −80 °C freezer until compositing and analysis occurred.
2.1.4. Lean Compositing
For heart, liver, kidney, tongue, tripe, oxtail, and bone marrow, all homogenates of separable lean tissue of the same item and origin were combined in equal parts by weight to create three lean composites per item (one from each supplier). For testicles, three composites were created, one from each of three packages of product. Three composites of blood were created, one from each of three bottles of blood obtained. All compositing procedures occurred by combining lean homogenates, blending composites in a 6.62-L Robot Coupe BLIXER 6V (Robot Coupe USA Inc., Ridgeland, MS, USA), and aliquoting into Whirl-Pak bags in the presence of liquid nitrogen. All samples analyzed at an on-site laboratory were immediately placed back into a −80 °C freezer until analysis occurred. All samples analyzed at off-site laboratories were placed into a −80 °C freezer before being shipped in insulated boxes with dry-ice and gel ice packs via overnight shipping.
2.1.5. Fat Compositing
For items containing separable fat (heart, kidney, tongue, oxtail), fat homogenates of the same item and fat type were combined in equal parts in weight. For oxtail, equal parts by weight of each fat type were then combined for a single composite. Oxtail was the only item containing external and internal fat. All compositing procedures occurred by combining fat homogenates, blending composites in a 3.79-L Robot Coupe BLIXER 4V (Robot Coupe USA Inc., Ridgeland, MS, USA), and aliquoting into Whirl-Pak bags in the presence of liquid nitrogen. All samples analyzed at an on-site laboratory were immediately placed back into a −80 °C freezer until analysis occurred. All samples analyzed at off-site laboratories were placed in a −80 °C freezer prior to being shipped in insulated containers with dry-ice and gel ice packs via overnight shipping.
2.2. Nutrient Analysis
Nutrient analysis occurred at United States Department of Agriculture (USDA) Agricultural Research Service (ARS)-approved laboratories, including CSU and commercial laboratories.
For beef heart, liver, kidney, and tongue, the following analyses were conducted: proximate analysis (protein, ash, moisture, fat), fatty acid profile, cholesterol, B vitamins (thiamin, niacin, riboflavin, pantothenic acid, vitamin B6, vitamin B12), vitamin A, vitamin E, vitamin D, 25-hydroxy vitamin D, vitamin K, calcium, copper, iron, magnesium, manganese, phosphorus, potassium, sodium, and zinc. The same nutrient analyses, excluding measurement of B vitamins, were performed for beef tripe, oxtail, bone marrow, testicles, and blood.
National Institute of Standards and Technology (NIST) standard reference material 1849a Adult/Infant Nutritional Supplement (Gaithersburg, MD, USA) and standard materials (Beech Nut Brand Beef and Chicken baby food, ground beef standard, pork and egg standard, beef bologna standard, and salmon standard) obtained from the Food Analysis Laboratory Control Center (Virginia Polytechnic Institute and State University; Blacksburg, VA, USA), were utilized to validate nutrient determinations to ensure the accuracy and precision of generated data among all laboratories. All standard materials were obtained from the Food Analysis Laboratory Control Center (FALCC; Virginia Polytechnic Institute and State University, Blacksburg, VA, USA). Ground beef and beef bologna standard materials were analyzed with each analysis group to ensure values existed within the acceptable range established by the FALCC for proximate analysis (protein, ash, fat, and dry matter). Mineral analyses were validated with use of NIST Adult/Infant Nutritional Supplement and beef bologna standard material. Beechnut beef baby food was used to validate thiamin, niacin, riboflavin, pantothenic acid, vitamin B6, and vitamin B12 assays. Beechnut chicken baby food was used for validation of the vitamin E assay. For cholesterol, vitamin B12, and fatty acid profile assays, ground beef standard material was utilized. Pork and egg standards were used to validate vitamin D, 25-hydroxy vitamin D analyses total thiamin, and vitamin K analyses. A salmon standard was utilized for validation of the amino acid profile and vitamin A assays. Chemical analyses were considered valid when the standard value generated was within the standard error of the certified value.
2.2.1. Proximate Analysis
Proximate analysis was conducted to determine protein, ash, moisture, and fat content for all lean tissue composites for each item from each origin. Proximate analysis was conducted for fat composites for each item that contained separable fat (heart, kidney, tongue, oxtail).
Protein Analysis
Crude protein was determined following the AOAC Official Method 992.15 [
13] using a nitrogen determinator (Leco TruSpec CN or Leco FP-2000; Leco Corporation, St. Joseph, MI and Rapid N Cube, Elementar, Hanau, Germany). The total percentage of nitrogen was multiplied by a factor of 6.25 to calculate percent protein. The protein content was determined at CSU.
Ash Analysis
The ash content was determined using the method described by AOAC 923.03 and 920.153 [
14]. Approximately 1 g of sample was placed into a pre-weighed, dry crucible prior to placing the crucible into a box furnace (Thermolyne, Thermo Scientific, Waltham, MA, USA) at 600 °C for 18 h. The percent ash was calculated by dividing the ash weight by the initial sample weight and multiplying by 100. Ash analysis was conducted at CSU.
Moisture Analysis
The moisture content was determined using the oven drying method described in AOAC 950.46 and 934.01 [
15]. Approximately 1 g of sample was weighted into aluminum tins prior to placing the tins into a forced air drying oven for 24 h at 100 °C. The percent moisture content was determined from the formula below. The moisture content was analyzed at CSU.
Fat Analysis
The fat content was determined using the chloroform:methanol method described by Folch, Lees, and Stanley (1957) [
16]. Approximately 1 g of sample was homogenized in 2:1 chloroform:methanol solution prior to placement in an orbital shaker at room temperature for 20 min. The sample was filtered through ashless filter paper, and 4 mL of 0.9% NaCl was added before being refrigerated for 24 h. Upon phase separation of the filtrate, aspirated low phase content was placed into a pre-weighed scintillation vial and dried under N
2 gas, followed by vial air drying under a hood for 2 h. Vials were placed into a forced air drying oven for 12 h at 100 °C. The total fat content was analyzed at CSU. The percent total fat was calculated from the formula:
2.2.2. Fatty Acid Analysis
Fatty acid methyl esters (FAMES) were prepared as described by Parks and Goins (1994) [
17]. Analysis of FAMES occurred by liquid chromatography using an Agilent Model 6890 Series II (Avondale, PA, USA) gas chromatograph-fixed with a Series 7683 injector and flame ionization detector in addition to being equipped with a 100-m × 0.25-mm fused silica capillary column (SP-2560 Supelco Inc., Bellefonte, PA, USA). Fatty acid percentages were calculated based on the total FAME analyzed. Fatty acid analysis was conducted at CSU [
18].
2.2.3. Mineral Analysis
Mineral analyses were determined for Ca, Mg, K, Na, Fe, Zn, Cu, Mn, and P using inductively coupled plasma mass spectrometry methods described by the AOAC Official Methods 2011.19 and 993.14 [
14] and USDA wet ash procedure. Mineral determination was conducted at Covance Laboratories (Madison, WI, USA).
2.2.4. Cholesterol Analysis
Cholesterol analysis was performed using saponification, extraction, evaporation, and derivatization as described by AOAC Official Method 994.10 [
14]. The cholesterol content was analyzed at Covance Laboratories (Madison, WI, USA).
2.2.5. B-Vitamin Analysis
Analysis was conducted for thiamin, niacin, riboflavin, pantothenic acid, vitamin B
6 and vitamin B
12 using methods described as follows: total thiamin—AOAC Official Method 942.23, 953.17, 957.17; niacin—AOAC 944.13 and 960.46; riboflavin—AOAC 960.46 and 940.33; pantothenic acid—AOAC 945.74, 992.07, 960.46; vitamin B
6—AOAC 961.15; vitamin B
12—AOAC 952.20 and 960.46 [
14]. Analysis of B-vitamins was conducted at Covance Laboratories (Madison, WI, USA).
2.2.6. Fat-Soluble Vitamin Analysis
Vitamin A analysis was performed using HPLC with UV detection of retinol with external calibration, and internal standard recovery post analysis. This method is adapted from AOAC Official Method 2001.13 [
14]. Vitamin A analysis was conducted by Craft Technologies Laboratory (Wilson, NC, USA). Vitamin D analysis was conducted by Covance Laboratories (Madison, WI, USA). Analysis was conducted for vitamin D
2, D
3, and 25-Hydroxy vitamin D
3; the content was determined using the chromatography-mass spectrophotometry method described in AOAC Official Method 2011.11 [
14]. Vitamin E analysis was conducted using high performance liquid chromatography (HPLC) with ultraviolet (UV) detection, with external calibration and internal standard recovery post-analysis. Vitamin E analysis was conducted by Craft Technologies Laboratory (Wilson, NC, USA). The vitamin K content was analyzed using HPLC with fluorescence detection after post-column reduction. Vitamin K analyses were performed at the Vitamin K Laboratory within the Jean Mayer USDA Human Nutrition Research Center on Aging (HNRCA) at Tufts University (Medford, MA, USA).