Background: Cashew nut shell liquid (CNSL) is an agricultural byproduct containing alkylphenols that has been shown to favorably change the rumen fermentation pattern only under experimentally fixed feeding conditions. Investigation of CNSL potency in rumen modulation under a variety of feeding regimens, and evidence leading to the understanding of CNSL action are obviously necessary for further CNSL applications. The objective of this study was to evaluate the potency of CNSL for rumen modulation under different dietary conditions, and to visually demonstrate its surfactant action against selected rumen bacteria.
Methods: Batch culture studies were carried out using various diets with 5 different forage to concentrate (F:C) ratios (9:1, 7:3, 5:5. 3:7 and 1:9). Strained rumen fluid was diluted with a buffer and incubated with each diet. Gas and short chain fatty acid (SCFA) profiles were characterized after 18 h incubation at 39 °C. Monensin was also evaluated as a reference additive under the same conditions. Four species of rumen bacteria were grown in pure culture and exposed to CNSL to determine their morphological sensitivity to the surfactant action of CNSL.
Results: CNSL supplementation decreased total gas production in diets with 5:5 and 3:7 F:C ratios, whereas the F:C ratio alone did not affect any gas production. Methane decrease by CNSL addition was more apparent in diets with 5:5, 3:7, and 1:9 F:C ratios. An interactive effect of CNSL and the F:C ratio was also observed for methane production. CNSL supplementation enhanced propionate production, while total SCFA production was not affected. Monensin decreased methane production but only in a diet with a 1:9 F:C ratio with increased propionate. Studies of pure cultures indicated that CNSL damaged the cell surface of hydrogen- and formate-producing bacteria, but did not change that of propionate-producing bacteria.
Conclusion: CNSL can selectively inhibit rumen bacteria through its surfactant action to lead fermentation toward less methane and more propionate production. As CNSL is effective over a wider range of dietary conditions for such modulation of rumen fermentation in comparison with monensin, this new additive candidate might be applied to ruminant animals for various production purposes and at various stages.

1 Callaway TR, "The ability of"low G + C gram-positive"ruminal bacteria to resist monensin and counteract potassium depletion" 39 : 226-230, 1999

2 Toral PG, "Tannins as feed additives to modulate ruminal biohydrogenation: effects on animal performance, milk fatty acid composition and ruminal fermentation in dairy ewes fed a diet containing sunflower oil" 164 : 199-206, 2011

3 McDougall EI., "Studies on ruminant saliva. 1. The composition and output of sheep's saliva" 43 : 99-109, 1948

4 Kubo I, "Structural-antibiotic activity relationships of anacardic acids" 41 : 1016-1019, 1993

5 Macy JM, "Pathway of succinate and propionate formation in Bacteroides Fragilis" 134 : 84-91, 1978

6 Patra AK, "Oils affect populations of some rumen bacteria in vitro as revealed by microarray(RumenBactArray)analysis" 6 : 297-, 2015

7 Beauchemin KA, "Nutritional management for enteric methane abatement : a review" 48 : 21-27, 2008

8 Shinkai T, "Mitigation of methane production from cattle by feeding cashew nut shell liquid" 95 : 5308-5316, 2012

9 Hook SE, "Methanogens: methane producers of the rumen and mitigation strategies" 945785-, 2010

10 McGuffey RK, "Ionophores for dairy cattle:current status and future outlook" 84 : E194-E203, 2001

11 Calsamiglia S, "Invited review : essential oils as modifiers of rumen microbial fermentation" 90 : 2580-2595, 2007

12 Watanabe Y, "In vitro evaluation of cashew nut shell liquid as a methaneinhibiting and propionate-enhancing agent for ruminants" 93 : 5258-5267, 2010

13 Oh S, "Ginkgo fruit extract as an additive to modify rumen microbiota and fermentation and to mitigate methane production" 100 : 1923-1934, 2017

14 Latham MJ, "Fermentation of cellulose by Ruminococcus flavefaciens in the presence and absence of Methanobacterium ruminantium" 34 : 297-301, 1977

15 Guan H, "Efficacy of ionophores in cattle diets for mitigation of enteric methane" 84 : 1896-1906, 2006

16 Devant M, "Effects of plant extract supplementation on rumen fermentation and metabolism in young Holstein bulls consuming high levels of concentrate" 137 : 46-57, 2007

17 Flythe MD, "Effects of hops (Humulus Lupulus L.) extract on volatile fatty acid production by rumen bacteria" 109 : 1169-1176, 2010

18 이성실, "Effects of Non-ionic Surfactants on Enzyme Distributions of Rumen Contents, Anaerobic Growth of Rumen Microbes, Rumen Fermentation Characteristics and Performances of Lactating Cows" 아세아·태평양축산학회 16 (16): 104-115, 2003

19 Chen M, "Effect of monensin and lasalocid-sodium on the growth of methanogenic and rumen saccharolytic bacteria" 38 : 72-77, 1979

20 Russell JB, "Effect of ionophores on ruminal fermentation" 55 : 1-6, 1989

21 Baldwin RL, "Conversion of lactate-C14 to propionate by the rumen microflora" 83 : 907-913, 1962

22 Menon ARR, "Cashew nut shell liquidits polymeric and other industrial products" 44 : 324-338, 1985

23 Chow JM, "Binding of radiolabeled monensin and lasalocid to ruminal microorganism and feed" 70 : 1630-1635, 1994

24 Kubo I, "Antibacterial action of anacardic acids against methicillin resistant Staphylococcus aureus(MRSA)" 51 : 7624-7628, 2003

25 Miller TL, "Anaerobic biocenversion of cellulose by Ruminococcus albus, Methanobrevibacter smithii, and Methanosarcina backeri" 54 : 494-498, 2000

26 Liu Y, "Advances in nutritional manipulation rumen functions of surfactants" 7 : 1451-1458, 2013