Video image analysis as a potential grading system for Uruguayan beef carcasses.

A study was conducted in 2 phases to evaluate the effectiveness of 1) the VIAscan Beef Carcass System (BCSys; hot carcass system) and the CVS BeefCam (chilled carcass system), used independently or in combination, to predict Uruguayan beef carcass fabrication yields; and 2) the CVS BeefCam to segregate Uruguayan beef carcasses into groups that differ in the Warner-Bratzler shear force (WBSF) values of their LM steaks. The results from the meat yield phase of the present study indicated that the prediction of saleable meat yield percentages from Uruguayan beef carcasses by use of the BCSys or CVS BeefCam is similar to, or slightly better than, the use of USDA yield grade calculated to the nearest 0.1 and was much more effective than prediction based on Uruguay National Institute of Meat (INAC) grades. A further improvement in fabrication yield prediction could be obtained by use of a dual-component video image analysis (VIA) system. Whichever method of VIA prediction of fabrication yield is used, a single predicted value of fabrication yield for every carcass removes an impediment to the implementation of a value-based pricing system. Additionally, a VIA method of predicting carcass yield has the advantage over the current INAC classification system in that estimates would be produced by an instrument rather than by packing plant personnel, which would appeal to cattle producers. Results from the tenderness phase of the study indicated that the CVS BeefCam output variable for marbling was not (P > 0.05) able to segregate steer and heifer carcasses into groups that differed in WBSF values. In addition, the results of segregating steer and heifer carcasses according to muscle color output variables indicate that muscle maturity and skeletal maturity were useful for segregating carcasses according to differences in WBSF values of their steaks (P > 0.05). Use of VIA to predict beef carcass fabrication yields could improve accuracy and reduce subjectivity in comparison with use of current INAC grades. Use of VIA to sort carcasses according to muscle color would allow for the marketing of more consistent beef products with respect to tenderness. This would help facilitate the initiation of a value-based marketing system for the Uruguayan beef industry.

Using reflectance spectroscopy to predict beef tenderness.

A study was conducted to determine if reflectance measurements made in the near-infrared region of the spectrum were additive to reflectance measurements made in the visible region of the spectrum for predicting Warner-Bratzler shear force (WBSF) values. Eighty seven strip loins were collected following fabrication over 3d at a commercial beef processing facility from heifer carcasses with Slight or Traces marbling scores. Spectroscopic measurements were made at approximately 50h postmortem using a Hunter-Lab UltraScan. Subsequently, all strip loins were aged for 14d, cooked to an internal temperature of 70°C, and sheared to obtain WBSF values. Reflectance measurements obtained in the near-infrared region of the spectrum were correlated with WBSF values, however, these measurements were not additive to the predictive ability of reflectance measurements (R(2) values did not differ) made in the visible portion of the spectrum when the use of broad-band wavelength filters were simulated. It was therefore determined, that both the visible and near-infrared spectra measure reflectance and that both methods are acceptable methods of tenderness prediction.

An evaluation of central nervous system cross-contamination due to carcass splitting in commercial beef-packing plants.

Four experiments were conducted in commercial beef-packing facilities The objectives of these experiments were to: (i) determine and validate a carcass sampling technique and location to determine if central nervous system (CNS) cross-contamination exists/occurs; (ii) determine if residual CNS tissue contamination remains on splitting saws after sanitation procedures; (iii) determine the prevalence of CNS cross-contamination in commercial slaughter facilities; (iv) determine whether washing treatments reduce or eliminate CNS tissue presence in carcass-splitting saws; (v) determine the effectiveness of commercial spray-washing systems in removing CNS tissue from beef carcasses; and (vi) compare residual CNS tissue levels on the blade and in the housings of the Jarvis Buster IX and Buster IV carcass-splitting saws. CNS tissue remained, albeit at very low levels, in the housings and on the blades of carcass-splitting saws after carcass splitting and operational sanitation. Additionally, after splitting carcasses, CNS tissue remaining in the splitting saw housings and on saw blades was found to cross-contaminate subsequent carcasses during splitting. Most splitting saw operational sanitation procedures reduced the amount of CNS tissue remaining in the splitting saw housings and on splitting saw blades, but no treatment eliminated CNS tissue from either to levels below the detection limit of the assay (6 ng/100 cm2). Washing in carcass spray-washing cabinets at three of the five commercial beef-packing facilities reduced, but did not eliminate, presence of CNS tissue in the aitch bone area of carcasses. Carcass spray washing in cabinets at three of the five facilities reduced (P < 0.05) the concentration of CNS tissue in the fourth thoracic vertebra area. While extremely low concentrations of CNS tissue remained in the splitting saw housings, on the splitting saw blades, and on carcasses, it is unknown whether these levels would pose a human food safety risk because the exact amount of bovine spongiform encephalopathy-infected spinal cord capable of transmitting the disease to humans is dependent on the infectivity titer, which is not readily known.

Central nervous system tissue in meat products: an evaluation of risk, prevention strategies, and testing procedures.

Since the outbreak of bovine spongiform encephalopathy (BSE) in the United Kingdom in 1986 and its subsequent link to the human neurological disorder variant Creutzfeldt-Jakob disease (vCJD), presence of tissues from the central nervous system (CNS) in meat products has been considered a public health concern and, thus, has been banned from entering the human food chain in many countries. Despite this, potential can exist during harvesting to contaminate or cross-contaminate edible meat products with CNS tissue that is designated as a specified risk material (SRM) in many countries. Methods used to detect CNS tissue in meat products vary greatly in their sensitivity, specificity, cost, labor and expertise needed, ease of completion, and type of results given (qualitative vs quantitative) and, within these constraints, appropriate testing methods must be selected to monitor or verify that meat products system controls are effective in removing CNS tissue from the human food chain. The extent to which monitoring procedures are needed should be based on the public health risk of CNS tissue in meat products as determined by each sovereign nation and/or third-party international organizations such as the World Organization for Animal Health (OIE). Risk associated with consumption of CNS tissue should be estimated by sovereign nations by establishing prevalence of BSE within their borders. Using this information, science-based decisions may guide international policy and trade. Using available scientific information, appropriate testing methods for monitoring or verification, and prevalence information, nations can estimate and reduce, to the extent deemed necessary, the public health risk of vCJD.