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RESEARCH ARTICLE (Open Access)
Contents Vol 49(6)

Economic effects of alternate growth path, time of calving and breed type combinations across southern Australian beef cattle environments: feedlot finishing at the New South Wales experimental site

B. L. Davies A B , A. R. Alford A C and G. R. Griffith A C D
+ Author Affiliations
- Author Affiliations

A Cooperative Research Centre for Beef Genetic Technologies, University of New England, Armidale, NSW 2351, Australia.

B New South Wales Department of Primary Industries, Paterson, NSW 2421, Australia.

C New South Wales Department of Primary Industries, Armidale, NSW 2351, Australia.

D Corresponding author. Email: garry.griffith@dpi.nsw.gov.au

Animal Production Science 49(6) 535-541 https://doi.org/10.1071/EA08265
Submitted: 29 October 2009  Accepted: 5 February 2009   Published: 13 May 2009

Abstract

The ‘Regional Combinations’ project and its biophysical outcomes have been described in several other papers in this special edition. The information provided in these papers allows an evaluation of the most profitable beef cattle production systems across different environments in southern Australia. In this paper, the focus is on the New South Wales experimental site where the trial animals were finished in a feedlot. The data identified liveweight gain as the biggest driver of profitability of production. Between growth treatments, there was a large difference in the gross margins before feedlot entry between the ‘fast’ and ‘slow’ treatments favouring the fast-grown animals, even after accounting for the higher cost of producing pasture capable of sustaining faster growth. However, the slow growth treatments consistently outperformed the fast growth treatments in the feedlot. In terms of breeds, the European breed types consistently outperformed the Wagyu breeds. There were no time-of-calving experiments in New South Wales.


Acknowledgements

The financial and in-kind support of the Cooperative Research Centre for Cattle and Beef Quality and its partner agencies Meat and Livestock Australia, New South Wales Department of Primary Industries and the University of New England is gratefully acknowledged. Thanks also to the many staff of these agencies that assisted in field operations, data collection and processing, biometrics and administrative support. The generous support in cash and kind of the commercial cooperator, AgReserves Australia is gratefully acknowledged, as is the individual support of all the field staff and management of this organisation. The cooperation and assistance of Cargill Beef Australia at the finishing and processing stages of the experiments is also acknowledged. The economics team pays a special tribute to the NSW overall project management team of Bill McKiernan, John Wilkins and Jim Walkley who provided support, data and other assistance, whenever asked. Stuart Mounter and Kirrily Pollock provided valuable comments on an earlier draft of this paper.


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1 The 120 ha included 20 ha of irrigated lucerne and 10 ha of winter fodder crop.

2 At the NSW site the breed types included were Angus selected for high RBY, Angus selected for high IMF, Angus selected for both high RBY and high IMF, Charolais, Limousin, Black Wagyu and Red Wagyu. The growth paths selected were a high growth path to achieve 0.7–1.0 kg per day from weaning to feedlot entry, and a moderate/slow (or conventional) growth path to achieve 0.5–0.6 kg per day from weaning to feedlot entry.

3 The slow growth enterprise allowed for greater deficits because of the lower growth rates required for the steers and the fact that there is no irrigated summer pastures assumed for this enterprise.

4 Feed deficits for fast growth options were calculated as follows: 116 head × 1.3 kg deficit per day × 30.4 days per month = 4584 kg of allowable feed deficit ÷ 120 ha = 38 kg per ha deficit allowed for March. Deficits for slow growth options were 67 head × 1.3 kg deficit per day × 30.4 days per month = 2648 kg ÷ 150 ha = 18 kg/ha allowed for February and March.

5 A mixed model cubic smoothing spline analysis (Verbyla et al. 1999) was used to both describe the growth paths and to predict live and carcass weights where various corrections were required. In particular, a set of data was generated to predict the performance of steers if each growth treatment × sire type group was set to a mean 380 kg feedlot induction weight. The ‘extra days’ taken (compared with the fastest group) for groups of steers to achieve this 380 kg mean was also part of the data generated from this procedure.

6 Although not reported, this advantage also shows in the return per $100 of livestock capital because, with faster growth, there is less money tied up in stock on hand.