Chemical compositions and termiticidal activities of the heartwood from Calophyllum inophyllum L.

Kadir, Roszaini; Awang, Khairul; Khamaruddin, Zaitihaiza; Soit, Zaini

doi:10.1590/0001-3765201520140041

Abstracts

Wood extractives from heartwood of Callophylum inophyllum (bintangor) were obtained by shaker method and analyzed for their constituents by gas chromatography-mass spectrometry (GC-MS). Ten compounds were identified by ethanol (EtOH) solvents, fourteen by methanol (MeOH) and only nine by petroleum ether (PETETHR). Major compounds were contributed by monoterpenes (75.11%, 53.75%) when extracted with EtOH and PETETHR solvents. The anti-termitic assay of the wood extracts was also investigated against Coptotermes curvignathus. The level of concentration for anti-termite activity may be an indication of the dose application of the wood extracts for new development of termiticide.

Calophyllum inophyllum; chemical compositions; ethanol; methanol; petroleum ether; termiticide

Extratos de madeira de cerne de Calophyllum inophyllum (bintangor) foram obtidos pelo método de agitação e os seus componentes analisados por cromatografia em fase gasosa-espectrometria de massa (GC-MS). Dez compostos foram identificados pelo emprego de solvente etanol (EtOH), e catorze por metanol (MeOH) e apenas nove por éter de petróleo (PETETHR). Os principais compostos dessas frações foram identificados como monoterpenos (75,11%, 53,75%), quando extraídos com os solventes EtOH e PETETHR. O ensaio anti-cupins dos extratos da madeira também foram investigados contra Coptotermes curvignathus. O nível de concentração necessário para a atividade anti-fungica pode ser uma indicação da dose de aplicação dos extratos de madeira para o novo experimento da ação termiticida.

Calophyllum inophyllum; composições químicas; etanol; metanol; éter de petróleo; termiticidas

INTRODUCTION

Calophyllum inophyllum Linnaeus, (Clusiaceae) which is commonly referred to as 'bintangor' (in Malaysia) is a medium to large evergreen tree. It is widely distributed in tropical areas and tolerates varied kinds of soil, coastal sand, clay or even degraded soil (Dweck and Meadowst 2002DWECK AC AND MEADOWST T. 2002. Tamanu (Calophyllum inophyllum) - The African, Asian, Polynesian and Pacific Panacea. Int J Cosmetic Sci 24: 1-8.). The fruits and leaves of C. inophyllum are very poisonous (Austin 1998AUSTIN DF. 1998. Poisonous plants of southern Florida, 9 p. http://www.fau.edu/divdept/science/envsci/poison-pl.html.
http://www.fau.edu/divdept/science/envsc... ). The extracted oil from the fruit is used as a remedy for sciatica, shingles, neuritis, leprous neuritis and rheumatism, ulcers and skin diseases while and the oil from this tree's seed is reported to have medicinal and healing properties (Cribb and Cribb 1981CRIBB AB AND CRIBB JW. 1981. Wild medicine in Australia. William Collins, Pty, Ltd, Sydney, 300 p.). Other uses included gum for treatment of wounds and ulcers, bark for vaginal discharge after childbirth, passing of blood and gonorrhea (Burkhil 1994BURKHIL HM. 1994. The useful plants of west tropical Africa, 2nd ed., Vol. 2. Families E-I. XX Royal Botanic Gardens Kew, 522 p.), antiseptic, disinfectant, internal haemorrhages (Nadkarni and Nadkarni 1999NADKARNI KM AND NADKARNI AK. 1999. Indian material medica with ayurvedic, unani-tibbi, siddha, allophatic, homoopathic, naturopathic and home remedies, vol. 2, Popular Prakashan Private Ltd. Bombay, India.), soulattrolide (pyranocoumarins) from latex are active against HIV (Patil et al. 1993PATIL AD ET AL. 1993. The inophyllums, novel inhibitors of HIV-1 reverse transcriptase isolated from the Malaysian tree, Calophyllum inophyllum Linn. J Med Chem 36: 4131-4138.) and Calocoumarin-A as an anti-cancer agent (Hathurusingha and Ashwath 2007HATHURUSINGHA HMSD AND ASHWATH N. 2007. Beauty leaf (Calophyllum inophyllum L.) tree: A tree with great economic potential. In: Proceedings of 12th International Forestry and Environmet Symposium, Kalutara, Sri Lanka, 20 p.). The Javanese believed the tree had diuretic properties but in Samoa, the whole tree is considered a virulent poison (Dweck and Meadowst 2002DWECK AC AND MEADOWST T. 2002. Tamanu (Calophyllum inophyllum) - The African, Asian, Polynesian and Pacific Panacea. Int J Cosmetic Sci 24: 1-8.). Recently, C. inophyllum has been identified as the most suitable feedstock for future generation biodiesel (Jahirul et al. 2012JAHIRUL MI, BROWN JR, SENADERA W, ASHWATH N, LAING C, LESKI-TAyLOR J AND RASUL MG. 2012. Optimisation of bio-oil extraction process from Beauty Leaf (Calophyllum inophyllum) oil seed as a second generation biodiesel source. In: Proceedings of the 5th BSME International Conference on Thermal Engineering, Sadrul AKM (Ed), Bangladesh Society of Mechanical Engineers, Dhaka, Bangladesh.).

On the other hand, previous studies (Scheffrahn 1991SCHEFFRAHN RH. 1991. Allelochemical resistance of wood to termites. Sociobiol 19: 257-282., Escoubas et al. 1995ESCOUBAS P, LAJIDE L AND MITZUTANI J. 1995. Termite antifeedant activity in Afromomum melegueta. Phytochem 40: 1097-1099., Nakayama et al. 2000NAKAYAMA FS, CHOW P, BAJWA DS, YOUNGQUIST JA, MUEHL JH AND KRYZIK AM. 2000. Preliminary investigation of the natural durability of Guayale (Parthenium argentatium) based wood products. The International Research Group on Wood Preservation. 31st Annual meeting Kona Hawaii USA, 14th - 19th May 2000., Peralta et al. 2004PERALTA RCG, MENEZES EB, CARVALHO AD AND AGUIAR-MENEZES EL. 2004. Wood consumption rate of forest species by subterranean termites (Isoptera) under field conditions. Rev Arvore 28: 1-12., Ragon et al. 2008ROSZAINI K, NOR AZAH MA, MAILINA J, ZAINI S AND MOHAMMAD FARIDZ Z. 2013. Toxicity and antitermite activity of the essential oils from Cinnamomum camphora, Cymbopogon nardus, Melaleuca cajuputi and Dipterocarpus sp. against Coptotermes curvignathus. Wood Sci Technol 47(6): 1273-1284.) found that wood extractives possessed promising protection/prevention characteristics against termites. They claimed that the protection characteristics came from phenolic compounds like terpenes, flavonoids, quinoids, alkaloids, stilbenes and tannins (Ohmura et al. 2000OHMURA W, DOI S, AOYAMA M AND OHARA S. 2000. Antifeedant activity of flavonoids and related compounds against the subterranean termite Coptotermes formosanus. Holzforschung 53: 569-554., Morisawa et al. 2002MORISAWA J, KIM CS, KASHIWAGI T, TEBAYASHI SI AND HORIIKE M. 2002. repellents in the Japanese cedar Cryptomeria japonica against the Pill-bug, Armadillidium vulgare. Biosci Biotechn Biochem 66(11): 2424-2428., Ganapaty et al. 2004GANAPATY S, THOMAS PS, FOTSO S AND LAATSCH H. 2004. Antitermitic quinines from Diospyros sylvatica. Phytochem 65: 1265-1271., Watanabe et al. 2005WATANABE Y, MIHARA R, MITSUNAGA T AND YOSHIMURA T. 2005. Termite repellent sesquiterpenoids from Callitris glaucophylla heartwood. J Wood Sci 51(5): 514-419., Coelho et al. 2006COELHO aam, pAULA je AND eSPINDOLA ls. 2006. insecticidal activity of cerrado plant extracts on Rhodnjus milesi Carcavallo, Rocha, Galvao and Juberg (Hemiptera: Reduviidae) under laboratory conditions. Neotrop Entomol 35: 133-138., Morimoto et al. 2006MORIMOTO M, FUKUMOTO H, HIRATANI M, CHAVASIRI W AND KOMAI K. 2006. Insect antifeedants, pterocarpol, in heartwood of Pterocarpus macrocarpus Kruz. Biosci Biotechn Biochem 70: 1864-1868., Little et al. 2010LITTLE NS, SCHULTZ TP AND NICHOLAS DD. 2010. Termite-resistant heartwood. Effect of antioxidants on termite feeding deterrence and mortality. Holzforschung 64: 395-398.). In addition, wood extracts which are organic based preservatives are easier to detoxify are considered low hazard and are easier to dispose of without adverse environmental effects (Barnes 1992BARNES HM. 1992. Wood protecting chemicals from the 21st century. International Research Group on Wood Preservation. 24th Annual Conference Meeting at Orlando, Florida, USA. IRG/WP 93-30018, 29 p., Chen et al. 2004CHEN K, OHMURA W, DOI S AND AOYAMA M. 2004. Termite feeding deterrent from Japanese larch wood. Bioresour Technol 95(2): 129-134.).

However, to the best of our knowledge, a study of the wood extracts of C. inophyllum species from Malaysia, or any other country, has not been reported to date. A few studies focus on the medicinal properties (Dweck and Meadowst 2002DWECK AC AND MEADOWST T. 2002. Tamanu (Calophyllum inophyllum) - The African, Asian, Polynesian and Pacific Panacea. Int J Cosmetic Sci 24: 1-8., Misha et al. 2010MISHA US, MURTHY PN, CHOUDHURY PK, PANIGRAHI G, MOHAPATRA S AND PRADHAN P. 2010. Antibacterial and analgesic effects of the stem barks of Calophyllum inophyllum. Int J Chem Technol Res 2(2): 973-979.) rather than on wood preservatives. The aim of this study was to evaluate the C. inophyllum heartwood extracts for antitermitic activity against subterranean termite, Coptotermes curvignathus.

MATERIALS AND METHODS

PLANT MATERIAL

A 25 years old disc of Calophyllum inophyllum Linnaeus (bintangor) was cut from felled trees stored at FRIM log yard. A disc was cut from the basal portion of one tree.

TERMITE

Asian subterranean termites, Coptotermes curvig nathus Holmgren (Isoptera: Rhinotermitidae), was collected from active field colonies at the Forest Research Institute Malaysia (FRIM) campus using a method described before (Roszaini et al. 2009ROSZAINI K, RAFEADAH R AND MOHD DAHLAN J. 2009. Durability of Malaysian timbers against the Asian subterranean termite Coptotermes gestroi Wasmann. J Inst Wood Sci 19: 16-21.).

EXTRACTION

The heartwood of each timber species was ground to fine sawdust powder, passed through a 250 mesh sieve before extraction. About 5 g of wood powder was extracted with 200 mL of absolute ethanol, absolute methanol and petroleum ether on a shaker for 8h at room temperature. Then the solutions were filtered through Whatman no. 1 filter paper. The filtrate was then evaporated in a rotary vapour at 40°C (Ordoñez et al. 2006ORDOñEZ AAL, GOMEZ JD, VATTUONE MA AND ISLA MI. 2006. Antioxidant activities of Sechlum edule (Jacq.) swart extracts. Food Chem 97: 452-458.) and the extraction yield was determined. The oven-dried cubic samples (25 mm x 25 mm x 6.5 mm) were also prepared from the heartwood of each timber species and were extracted with each of the solvents using the same technique as stated before.

BIOASSAY TEST AGAINST SUBTERRANEAN TERMITE

The un-extracted and extracted samples were subjected to no choice feeding tests according to ASTM D3345-74 (ASTM 1988ASTM - AMERICAN SOCIETy FOR TESTING AND MATERIALS. 1988. Standard test method of laboratory evaluation of wood and other cellulosic materials for resistance to termites (D3345-74). In: ASTM Annual Book of Standards Vol. 4.10 Wood West Conshohocken, PA, Vol. 4.10, p. 430-432.) standard methods slightly modified. Screw-top bottles of 8 cm in diameter by 13 cm height were filled with 200 g of sterilized sand and 30 ml distilled water. The bottles were left overnight to equilibrate to laboratory conditions before test initiation. One block of each timber species was placed on the surface of the damp sand and 400 termites (360 workers and 40 soldiers) were added to each bottle. Each tests contained 5 replicates. All bottles were stored in an incubator maintained at 22°C and 70 ± 5% relative humidity for 28 days. Within this period, if it was found that all termites appeared dead, the bottle would be taken out and the number of days until 100% mortality would be recorded. At the end of the fourth week the blocks were removed, cleaned, dried overnight and reweighed. The remaining live termites were weighed and recorded for each of the bottles. As detailed in the standard, the condition of the test blocks were rated visually using a 0-10 scale where 0 was total failure and 10 was sound.

TERMITE ASSAYS

The toxicity of C. inophyllym wood extract was determined according to previous methods (Sharma and Raina 1998SHARMA RN AND RAINA RM. 1998. Evaluating chemicals for eco-friendly pest management-I: Terpenoids and fatty acids for building termites. J Sci Ind Res 57: 306-309.) with slight modification. Samples of 5 mL, 10 mL, 20 mL, 40 mL and 80 mL of wood extracts were dissolved in analytical grade acetone separately, to obtain solutions of 5%, 10%, 20%, 40% and 80%, respectively. Then the solutions were applied to a 9.0 cm in diameter of filter paper samples (Advantec and 1.5 mm thickness) and dried in a laminar flow for 1h. The filter paper weights were measured before and after treatment process. Untreated filter paper and treated filter paper with acetone were use as a controls and each of the tests contained 3 replicates. Fifty active termite (3^rd instar) (45 workers and 5 soldiers) of C. curvignathus were introduced onto each Petri dish (9 cm diameter and 1.6 cm height). A few drops of water were added periodically to the bottom of each Petri dish. All the Petri dishes with covers were placed into an incubator which was maintained in darkness at 26°C ± 2°C and 65% ± 5% relative humidity and the mortality of the termites was counted and recorded every 24h for 25 days.

CHEMICAL ANALYSIS

The extracts were analyzed by GC-MS (Siti Humeirah et al. 2010SITI HUMEIRAH AG, NOR AZAH MA, MAILINA J, MUHAJIR H AND PUAD A. 2010. Chemical composition of three Xylopia leaf essential oils from Pasoh Forest Reserve, Negeri Sembilan, Malaysia. J Trop For Sci 22(1): 1-4.) [Agilent Technologies GC-MS 7890A/5975C Series; mass selective detector (MSD), EI mode (70eV direct inlet). GC: Hewlett-Packard 5MS; silica capillary column (30 m × 0.25 mm; 0.25 μm film thick ness]. Temperature program: 75°C → 230°C at 3°C min^-1 and finally held at 230°C for 5 min. Injector temperature: 270°C. Carrier gas: He 1 ml min^-1. Injected volume: 1.0 μl. Each extract was analyzed by GC twice. The GC peak areas were integrated and the component identification was done by comparing the MS with standards and with a library search (National Institute of Standards and Technology, NIST).

STATISTICAL ANALYSIS

One way analysis of variance (ANOVA) was performed on all data to determine the significance of variation in extractive compounds and antitermitic between wood species as well as between samples using MINITAB 15 computer programme. Values of P<0.05 were considered statistically significant.

RESULTS AND DISCUSSION

EXTRACTVIE YIELD

Extraction of the air dry heartwood of C. inophyllum gave dark brown extracts in 3.89% (EtOH), 4.29% (MeOH) and 3.31% (PETETHR) (Fig. 1). In the same way, MeOH gave a higher yield of extracts in camparison to the other two solvents which implies that MeOH was the best extraction proficiency while petroleum was the least proficient. Our findings are in agreement with previous study by Mahamadi et al. (2011)MAHAMADI C, TOGAREPI E AND DZOMbA P. 2011. Extraction of phenolic compounds from Temnocalyx obovatus. Afr J Biotechnol 10(54): 11245-11248., who reported that maximum extract yield from Temnocalyx obovatus was obtained with absolute methanol. Analysis of variance (ANOVA) also demonstrated that there was a significance variance between the yield extracts.

Fig. 1
- Yield of wood extractives from C. inophyllym extracted with different solvents (shake for 8 hour).

CHEMICAL COMPOSITIONS

A total of ten, seventeen and nine compounds comprising 99.46%, 99.99% and 99.28%, respec tively, of the total constituents of the wood extracts (Table I) were identified using different solvents of EtOH, MeOH and PETETHR.

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TABLE I Chemical constituents of ethanol, methanol and petroleum ether of C. inophyllum wood extracts.

The major compound in each of these wood extracts was isobornyl isobutanoate (43.27 - 46.60%) followed by indipone (15.16 - 39.32%) and carvacrol (2.30 - 29.91%) in EtOH, MeOH and PETETHR fractions, respectively. Other compounds that were significantly present were larixol (12.38%), rosifoliol (10.56%) and thujaplicinol (8.02%) in MeOH fractions. Quite a few of the compounds were only present in low concentrations (below 3%). It is also clear that monoterpenes (53.75-75.11%) were the main group of compounds in the C. inophyllum, except when extracted with MeOH (28.34%). Previous studies have shown that monoterpenes had significant insecticidal effects (Kordali et al. 2007KORDALI S, KESDEK M AND CAKIR A. 2007. Toxicity of monoterpenes against larvae and adults of Colorado potato beetle, Leptinotarsa decemlineata Say (Coleoptera: Chrysomelidae). Ind Crop Prod 26: 278-297., Abdelgaleil et al. 2009CHEN K, OHMURA W, DOI S AND AOYAMA M. 2004. Termite feeding deterrent from Japanese larch wood. Bioresour Technol 95(2): 129-134., Abdelgaleil 2010COELHO aam, pAULA je AND eSPINDOLA ls. 2006. insecticidal activity of cerrado plant extracts on Rhodnjus milesi Carcavallo, Rocha, Galvao and Juberg (Hemiptera: Reduviidae) under laboratory conditions. Neotrop Entomol 35: 133-138., Santos et al. 2011SANTOS SRL, MELO MA, CARDOSO AV, SANTOS RLC, SOUSA DP AND CAVACANTI SCH. 2011. Structure-activity relationships of larvicidal monoterpenes and derivatives against Aedes aegypti Linn. Chemosphere 84: 150-153., Zahran and Abdelgaleil 2011ZAHRAN HEDM AND ABDELGALEIL SAM. 2011. Insecticidal and developmental inhibitory properties of monoterpenes on Culex pipiens L. (Diptera: Culicidae). J Asia Pacific Entomol 14: 46-51., Xie et al. 2014XIE Y, WANG K, HUANG Q AND LEI C. 2014. Evaluation toxicity of monoterpenes to subterranean termite, Reticulitermes chinensis Snyder. Ind Crop Prod 53: 163-166.). Alkaloids were the second most important compound group in C. inophyllum (15.16-39.32%). Mao and Henderson (2007)MAO L AND HENDERSON G. 2007. Antifeedant activity and acute and residual toxicity of alkaloids from Sophora flavescens (leguminosae) against formosan subterranean termites (Isoptera: Rhinotermitidae). J Econ Entomol 100(3): 866-870. reported that alkaloids had a strong antifeedant effect against Formosan subterranean termite, Coptotermes formosanus Shiraki. Sesquiterpenes, diterpenes (except with PETETHR) and phenylpropanoids were also present in all fractions. Furthermore, an aromatic compound, abietadiene was only detected in the MeOH extract.

Out of twenty four different compounds identified in three solvents, indipone and carvacrol were the two compounds detected in each of solvents used. The toxicity of MeOH solvent extracts against C. curvignathus may be attributed to the presence of carvacrol (Seo et al. 2009SEO SM, KIM J, LEE SG, SHIN CH, SHIN SC AND PARK IK. 2009. Fumigant antitermitic activity of plant essential oils and components from ajowan (Trachyspermum ammi), allspice (Pimenta dioica), caraway (Carum carvi), dill (Anethum graveolens), geranium (Pelargonium graveolens), and Litsea (Litsea cubeba) oils against Japanese termite (Reticulitermes speratus Kolbe). J Agric Food Chem 57(15): 6596-6602.). Morales-Ramos et al. (2003)MORALES-RAMOS JA, ROJAS MG AND HENNON PE. 2003. Black-staining fungus effects on the natural resistance properties of Alaskan yellow cedar to the formosan subterranean termite (Isoptera: Rhinotermitidae). Environ Entomol 32(5): 1234-1241. reported that the absence of carvacrol is one of the factors that made the infected wood susceptible to Formosan subterranean termite attack while Ahn et al. (1998)AHN yj, LEE SB, LEE hs AND kIM gh. 1998. Insecticidal and acaricidal activity of carvacrol and β-Thujaplicine derived from Thujopsis dolabrata var. hondai sawdust. J Chem Ecol 24(1): 81-90. found that carvacrol had broad insecticidal and acaricidal activity against agricultural, stored-product, and medical arthropod pests including termite. Methyl p-tert butyphenyl acetate and hexadecanoic acid were detected in EtOH and MeOH fractions, only isobornyl isobutanoate in EtOH and PETETHR; and rosifoliol in MeOH and PETERHR, respectively. On the other hand, β- funebrene, coniferyl alcohol <E>, incensole acetate, tetradectene <1-> and isovelencenol <E> were detected only in EtOH fracion while abietadiene, agarospirol, hydroxyl citronellol, larixol, stilbene, occidenol, thujaplicinol and soprenyl cinnamate-(E)-methyl were only found in MeOH fraction. (+)-Citronellol has been reported as a mosquito repellent chemical (Taylor and Schreck 1985TAYLOR WG AND SCHRECK CE. 1985. Chiral-phase Capillary Gas Chromatography and mosquito repellent activity of some oxazolidine derivatives of (+) and (-) - Citronellol. J Pharm Sci 74 (5): 534-539.) and as being toxic against C. curvignathus (Roszaini et al. 2013ROSZAINI K, NOR AZAH MA, MAILINA J, ZAINI S AND MOHAMMAD FARIDZ Z. 2013. Toxicity and antitermite activity of the essential oils from Cinnamomum camphora, Cymbopogon nardus, Melaleuca cajuputi and Dipterocarpus sp. against Coptotermes curvignathus. Wood Sci Technol 47(6): 1273-1284.). According to Shibutani et al. (2004)SHIBUTANI S, SAMEJIMA M AND DOI S. 2004. Effects of stilbenes from bark of Picea glehnii (Sieb. et Zucc.) and their related compounds against feeding behaviour of Reticulitermes speratus (Kolbe). J Wood Sci (50): 439-444., stilbenes which are well known as biologically active compounds are very effective against Reticulitermes speratus (Kolbe) while methylated compounds increased termiticidal activity. Meanwhile, only five other compounds; presilphiperfolan-8-ol, hexenyl cinnamate <3Z, thymol, thujic acid and allo-hedycarvol were detected from PETETHR fraction. Thymol was reported give a good result of termite mortality (88.27%) when tested against harvest termites Anacanthotermes ochraceus (Moawad et al. 2012MOAWAD SS, AL-BARTY A AND AL-OTAIBI NJ. 2012. Behavioural response of Anacanthotermes ochraceus towards some baits and volatile oils. J Agr Sci Tech B 2: 1279-1286.). Pandey et al. (2012)PANDEY A, CHATTOPADHYAY P, BANERJEE S, PAKSHIRAJAN K AND SINGH L. 2012. Antitermitic activity of plant essential oils and their major constituents against termite Odontotermes assamensis Holmgren (Isoptera: Termitidae) of North East India. Int Biodeter Biodegr 75: 63-67. also found that thymol, eugenol and carvacrol exhibited 100% termite mortality of Odontotermes assamensis.

BIOASSAYS

Results of the antitermitic activity tests of C. inophyllum wood extracts were examined by termite mortality (Fig. 2) and percentage of wood consumption (Fig. 3). The results of analysis showed that the strong antitermitic activity of C. inophyllum was extracted using MeOH followed by EtOH and lastly PETETHR. MeOH are commonly used to get the higher yield of extracts (Ali et al. 2010ALI G, HAWA ZEJ AND ASMAH R. 2010. Effects of solvent type on phenolics and flavonoids content and antioxidant activities in two varieties of young ginger (Zingiber officinale Roscoe) extracts. J Med Plants Res 5(7): 1147-1154.) and this solvent is also a good solvent system for the extraction of polar and non polar compounds (Richard et al. 2012RICHARD WC, CATHERINE SR, MARK RS, DAVID CC AND MARK AS. 2012. Extraction of polar and nonpolar biomarkers from the martian soil using aqueous surfactant solutions. Planet Space Sci 67(1): 109-118.). The strong antitermitic activity by MeOH solvent is likely from the presence of hydroxy citronellol and stilbene (Taylor and Schreck 1985TAYLOR WG AND SCHRECK CE. 1985. Chiral-phase Capillary Gas Chromatography and mosquito repellent activity of some oxazolidine derivatives of (+) and (-) - Citronellol. J Pharm Sci 74 (5): 534-539., Shibutani et al. 2004SHIBUTANI S, SAMEJIMA M AND DOI S. 2004. Effects of stilbenes from bark of Picea glehnii (Sieb. et Zucc.) and their related compounds against feeding behaviour of Reticulitermes speratus (Kolbe). J Wood Sci (50): 439-444., Roszaini et al. 2013ROSZAINI K, NOR AZAH MA, MAILINA J, ZAINI S AND MOHAMMAD FARIDZ Z. 2013. Toxicity and antitermite activity of the essential oils from Cinnamomum camphora, Cymbopogon nardus, Melaleuca cajuputi and Dipterocarpus sp. against Coptotermes curvignathus. Wood Sci Technol 47(6): 1273-1284.) which can't be extracted by other solvents.

Fig. 2
- Effect of different level of concentration on termite mortality of C. curvignathus.

Fig. 3
- Wood consumption in bio-assay tests of C. inophyllum against subterranean termites.

By all assessment methods, extracted wood species were particularly susceptible to C. curvignathus (Fig. 3). Results show that MeOH solvents resulted in a higher (45.49%) impact on the durability of C. inophyllum followed by EtOH (21.96%). Only 6.64% of C. inophyllum durability affected by PETETHR. This means that, when a high extractive is removed, it will cause a lack of wood resistance against C. curvignathus and this is in line with the results obtained for wood extracts yield (Fig. 1). The result from this study is in accordance with the previous study by Taylor et al. (2006)TAYLOR AM, GARTNER BL AND MORRELL JJ. 2006. Effects of heartwood extractive fractions of Thuja plicata and Chamaecyparis nootkatensison wood degradation by termites or Fungi. J Wood Sci 52: 147-153.. The samples of C. nootkatensis extracted using MeOH solvent were significantly increased the susceptibility of this timber species against C. formosanus.

This shows that the extract yields and resulted of antitermitic activities of the wood species are strongly dependent on the nature of extracting solvent, due to the presence of different antitermitic compounds of varied chemical characteristics and polarities that may or may not be soluble in a particular solvent.

The two reported reasons why termites respond differently in wood in bioassay tests are the amount and type of extractives and the wood density. Generally, extractives have a bigger impact on durability than density (Sen-Sarma 1963). This is clearly shown in the data presented here (Table II and Fig. 3). Samples with less amount of extractive extracted, had higher termite resistance while sample with higher extractive content extracted showed poor performance. This result corroborated the results of earlier works by Hashimoto et al. (1997)hASHIMOTO k, oHTANI y AND sAMESHIMA k. 1997. termiticidal activity and its transverse distribution in camphor (Cinnamomum camphora) wood. Mokuzai Gakkaishi 43(7): 566-575.. They claims that lower extractive content has been correlated with reduced termite and fungal resistance. Significant variation in termite resistance properties of C. nootkatensis wood also were also observed by Grace and Yamamoto (1994) and they suggested that this was a function of heartwood extractive variability. However, samples extracted with PETETHR (of lower density and lower extractive content) showed poorer performance; much better performance was achieved with samples extracted with ethanol, with a little bit higher extractive content but had similar density. The effect of this wood density on the natural durability was still unclear.

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TABLE II Density of unextracted and extracted samples of C. inophyllum using different solvents.

CONCLUSIONS

In conclusion, analysis of chemical compounds and antitermitic activity of C. inoplyllum wood extracts showed differences depending on solvents and level of concentration used. The results show that methanol had the greatest extraction yields whereas petroleum ether had the least.

ACKNOWLEDGMENTS

This project was funded by FRIM Young Scientist grant. Authors would like to express their gratitude to the staff in Wood Entomology Laboratory and Herbal Product Development Laboratory, FRIM for their help in collecting termites and preparation of the wood extracts.

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» http://www.fau.edu/divdept/science/envsci/poison-pl.html
BARNES HM. 1992. Wood protecting chemicals from the 21st century. International Research Group on Wood Preservation. 24th Annual Conference Meeting at Orlando, Florida, USA. IRG/WP 93-30018, 29 p.
BURKHIL HM. 1994. The useful plants of west tropical Africa, 2nd ed., Vol. 2. Families E-I. XX Royal Botanic Gardens Kew, 522 p.
CHEN K, OHMURA W, DOI S AND AOYAMA M. 2004. Termite feeding deterrent from Japanese larch wood. Bioresour Technol 95(2): 129-134.
COELHO aam, pAULA je AND eSPINDOLA ls. 2006. insecticidal activity of cerrado plant extracts on Rhodnjus milesi Carcavallo, Rocha, Galvao and Juberg (Hemiptera: Reduviidae) under laboratory conditions. Neotrop Entomol 35: 133-138.
CRIBB AB AND CRIBB JW. 1981. Wild medicine in Australia. William Collins, Pty, Ltd, Sydney, 300 p.
DWECK AC AND MEADOWST T. 2002. Tamanu (Calophyllum inophyllum) - The African, Asian, Polynesian and Pacific Panacea. Int J Cosmetic Sci 24: 1-8.
ESCOUBAS P, LAJIDE L AND MITZUTANI J. 1995. Termite antifeedant activity in Afromomum melegueta. Phytochem 40: 1097-1099.
GANAPATY S, THOMAS PS, FOTSO S AND LAATSCH H. 2004. Antitermitic quinines from Diospyros sylvatica. Phytochem 65: 1265-1271.
GRACE JK AND YAMAMOTO RT. 1994. Natural resistance of Alaska-cedar, redwood and teak to Formosan subterranean termites. Forest Prod J 44(3): 41-45.
hASHIMOTO k, oHTANI y AND sAMESHIMA k. 1997. termiticidal activity and its transverse distribution in camphor (Cinnamomum camphora) wood. Mokuzai Gakkaishi 43(7): 566-575.
HATHURUSINGHA HMSD AND ASHWATH N. 2007. Beauty leaf (Calophyllum inophyllum L.) tree: A tree with great economic potential. In: Proceedings of 12th International Forestry and Environmet Symposium, Kalutara, Sri Lanka, 20 p.
JAHIRUL MI, BROWN JR, SENADERA W, ASHWATH N, LAING C, LESKI-TAyLOR J AND RASUL MG. 2012. Optimisation of bio-oil extraction process from Beauty Leaf (Calophyllum inophyllum) oil seed as a second generation biodiesel source. In: Proceedings of the 5th BSME International Conference on Thermal Engineering, Sadrul AKM (Ed), Bangladesh Society of Mechanical Engineers, Dhaka, Bangladesh.
KORDALI S, KESDEK M AND CAKIR A. 2007. Toxicity of monoterpenes against larvae and adults of Colorado potato beetle, Leptinotarsa decemlineata Say (Coleoptera: Chrysomelidae). Ind Crop Prod 26: 278-297.
LITTLE NS, SCHULTZ TP AND NICHOLAS DD. 2010. Termite-resistant heartwood. Effect of antioxidants on termite feeding deterrence and mortality. Holzforschung 64: 395-398.
MAHAMADI C, TOGAREPI E AND DZOMbA P. 2011. Extraction of phenolic compounds from Temnocalyx obovatus. Afr J Biotechnol 10(54): 11245-11248.
MAO L AND HENDERSON G. 2007. Antifeedant activity and acute and residual toxicity of alkaloids from Sophora flavescens (leguminosae) against formosan subterranean termites (Isoptera: Rhinotermitidae). J Econ Entomol 100(3): 866-870.
MISHA US, MURTHY PN, CHOUDHURY PK, PANIGRAHI G, MOHAPATRA S AND PRADHAN P. 2010. Antibacterial and analgesic effects of the stem barks of Calophyllum inophyllum. Int J Chem Technol Res 2(2): 973-979.
MOAWAD SS, AL-BARTY A AND AL-OTAIBI NJ. 2012. Behavioural response of Anacanthotermes ochraceus towards some baits and volatile oils. J Agr Sci Tech B 2: 1279-1286.
MORALES-RAMOS JA, ROJAS MG AND HENNON PE. 2003. Black-staining fungus effects on the natural resistance properties of Alaskan yellow cedar to the formosan subterranean termite (Isoptera: Rhinotermitidae). Environ Entomol 32(5): 1234-1241.
MORIMOTO M, FUKUMOTO H, HIRATANI M, CHAVASIRI W AND KOMAI K. 2006. Insect antifeedants, pterocarpol, in heartwood of Pterocarpus macrocarpus Kruz. Biosci Biotechn Biochem 70: 1864-1868.
MORISAWA J, KIM CS, KASHIWAGI T, TEBAYASHI SI AND HORIIKE M. 2002. repellents in the Japanese cedar Cryptomeria japonica against the Pill-bug, Armadillidium vulgare. Biosci Biotechn Biochem 66(11): 2424-2428.
NADKARNI KM AND NADKARNI AK. 1999. Indian material medica with ayurvedic, unani-tibbi, siddha, allophatic, homoopathic, naturopathic and home remedies, vol. 2, Popular Prakashan Private Ltd. Bombay, India.
NAKAYAMA FS, CHOW P, BAJWA DS, YOUNGQUIST JA, MUEHL JH AND KRYZIK AM. 2000. Preliminary investigation of the natural durability of Guayale (Parthenium argentatium) based wood products. The International Research Group on Wood Preservation. 31st Annual meeting Kona Hawaii USA, 14th - 19th May 2000.
OHMURA W, DOI S, AOYAMA M AND OHARA S. 2000. Antifeedant activity of flavonoids and related compounds against the subterranean termite Coptotermes formosanus. Holzforschung 53: 569-554.
ORDOñEZ AAL, GOMEZ JD, VATTUONE MA AND ISLA MI. 2006. Antioxidant activities of Sechlum edule (Jacq.) swart extracts. Food Chem 97: 452-458.
PANDEY A, CHATTOPADHYAY P, BANERJEE S, PAKSHIRAJAN K AND SINGH L. 2012. Antitermitic activity of plant essential oils and their major constituents against termite Odontotermes assamensis Holmgren (Isoptera: Termitidae) of North East India. Int Biodeter Biodegr 75: 63-67.
PATIL AD ET AL. 1993. The inophyllums, novel inhibitors of HIV-1 reverse transcriptase isolated from the Malaysian tree, Calophyllum inophyllum Linn. J Med Chem 36: 4131-4138.
PERALTA RCG, MENEZES EB, CARVALHO AD AND AGUIAR-MENEZES EL. 2004. Wood consumption rate of forest species by subterranean termites (Isoptera) under field conditions. Rev Arvore 28: 1-12.
RAGON kw, nICHOLAS dd AND sCHULTZ tp. 2008. termite effect of the non-biocidal antioxidant properties of the extractives (Isoptera: Rhinotermitidae). Sociobiol 52: 47-54.
RICHARD WC, CATHERINE SR, MARK RS, DAVID CC AND MARK AS. 2012. Extraction of polar and nonpolar biomarkers from the martian soil using aqueous surfactant solutions. Planet Space Sci 67(1): 109-118.
ROSZAINI K, RAFEADAH R AND MOHD DAHLAN J. 2009. Durability of Malaysian timbers against the Asian subterranean termite Coptotermes gestroi Wasmann. J Inst Wood Sci 19: 16-21.
ROSZAINI K, NOR AZAH MA, MAILINA J, ZAINI S AND MOHAMMAD FARIDZ Z. 2013. Toxicity and antitermite activity of the essential oils from Cinnamomum camphora, Cymbopogon nardus, Melaleuca cajuputi and Dipterocarpus sp. against Coptotermes curvignathus. Wood Sci Technol 47(6): 1273-1284.
SANTOS SRL, MELO MA, CARDOSO AV, SANTOS RLC, SOUSA DP AND CAVACANTI SCH. 2011. Structure-activity relationships of larvicidal monoterpenes and derivatives against Aedes aegypti Linn. Chemosphere 84: 150-153.
SCHEFFRAHN RH. 1991. Allelochemical resistance of wood to termites. Sociobiol 19: 257-282.
SEN-SARMA PK. 1963. Studies on the natural resistance of timbers to termites. Indian For Bull (Entomol) 20: 1-10.
SEO SM, KIM J, LEE SG, SHIN CH, SHIN SC AND PARK IK. 2009. Fumigant antitermitic activity of plant essential oils and components from ajowan (Trachyspermum ammi), allspice (Pimenta dioica), caraway (Carum carvi), dill (Anethum graveolens), geranium (Pelargonium graveolens), and Litsea (Litsea cubeba) oils against Japanese termite (Reticulitermes speratus Kolbe). J Agric Food Chem 57(15): 6596-6602.
SHARMA RN AND RAINA RM. 1998. Evaluating chemicals for eco-friendly pest management-I: Terpenoids and fatty acids for building termites. J Sci Ind Res 57: 306-309.
SHIBUTANI S, SAMEJIMA M AND DOI S. 2004. Effects of stilbenes from bark of Picea glehnii (Sieb. et Zucc.) and their related compounds against feeding behaviour of Reticulitermes speratus (Kolbe). J Wood Sci (50): 439-444.
SITI HUMEIRAH AG, NOR AZAH MA, MAILINA J, MUHAJIR H AND PUAD A. 2010. Chemical composition of three Xylopia leaf essential oils from Pasoh Forest Reserve, Negeri Sembilan, Malaysia. J Trop For Sci 22(1): 1-4.
TAYLOR AM, GARTNER BL AND MORRELL JJ. 2006. Effects of heartwood extractive fractions of Thuja plicata and Chamaecyparis nootkatensison wood degradation by termites or Fungi. J Wood Sci 52: 147-153.
TAYLOR WG AND SCHRECK CE. 1985. Chiral-phase Capillary Gas Chromatography and mosquito repellent activity of some oxazolidine derivatives of (+) and (-) - Citronellol. J Pharm Sci 74 (5): 534-539.
WATANABE Y, MIHARA R, MITSUNAGA T AND YOSHIMURA T. 2005. Termite repellent sesquiterpenoids from Callitris glaucophylla heartwood. J Wood Sci 51(5): 514-419.
XIE Y, WANG K, HUANG Q AND LEI C. 2014. Evaluation toxicity of monoterpenes to subterranean termite, Reticulitermes chinensis Snyder. Ind Crop Prod 53: 163-166.
ZAHRAN HEDM AND ABDELGALEIL SAM. 2011. Insecticidal and developmental inhibitory properties of monoterpenes on Culex pipiens L. (Diptera: Culicidae). J Asia Pacific Entomol 14: 46-51.

Publication Dates

Publication in this collection
Apr-Jun 2015

History

Received
13 Feb 2014
Accepted
12 Sept 2014

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ABDELGALEIL SAM. 2010. Molluscicidal and insecticidal potential of monoterpenes on the white garden snail, Theba pisana (Muller) and the cotton leafworm Spodoptera littoralis (Boisduval). Appl Entomol Zool 45: 425-433.

[2] ABDELGALEIL SAM, MOHAMED MIE, BADAWY MEI AND ELARAMI SAA. 2009. Fumigant and contact toxicities of monoterpenes to Sitophilus oryzae (L.) and Tribolium castaneum (Herbst) and their inhibitory effects on acetylcholinesterase activity. J Chem Ecol 35: 518-525.

[3] AHN yj, LEE SB, LEE hs AND kIM gh. 1998. Insecticidal and acaricidal activity of carvacrol and β-Thujaplicine derived from Thujopsis dolabrata var. hondai sawdust. J Chem Ecol 24(1): 81-90.

[4] ALI G, HAWA ZEJ AND ASMAH R. 2010. Effects of solvent type on phenolics and flavonoids content and antioxidant activities in two varieties of young ginger (Zingiber officinale Roscoe) extracts. J Med Plants Res 5(7): 1147-1154.

[5] ASTM - AMERICAN SOCIETy FOR TESTING AND MATERIALS. 1988. Standard test method of laboratory evaluation of wood and other cellulosic materials for resistance to termites (D3345-74). In: ASTM Annual Book of Standards Vol. 4.10 Wood West Conshohocken, PA, Vol. 4.10, p. 430-432.

[6] AUSTIN DF. 1998. Poisonous plants of southern Florida, 9 p. http://www.fau.edu/divdept/science/envsci/poison-pl.html.
» http://www.fau.edu/divdept/science/envsci/poison-pl.html

[7] BARNES HM. 1992. Wood protecting chemicals from the 21st century. International Research Group on Wood Preservation. 24th Annual Conference Meeting at Orlando, Florida, USA. IRG/WP 93-30018, 29 p.

[8] BURKHIL HM. 1994. The useful plants of west tropical Africa, 2nd ed., Vol. 2. Families E-I. XX Royal Botanic Gardens Kew, 522 p.

[9] CHEN K, OHMURA W, DOI S AND AOYAMA M. 2004. Termite feeding deterrent from Japanese larch wood. Bioresour Technol 95(2): 129-134.

[10] COELHO aam, pAULA je AND eSPINDOLA ls. 2006. insecticidal activity of cerrado plant extracts on Rhodnjus milesi Carcavallo, Rocha, Galvao and Juberg (Hemiptera: Reduviidae) under laboratory conditions. Neotrop Entomol 35: 133-138.

[11] CRIBB AB AND CRIBB JW. 1981. Wild medicine in Australia. William Collins, Pty, Ltd, Sydney, 300 p.

[12] DWECK AC AND MEADOWST T. 2002. Tamanu (Calophyllum inophyllum) - The African, Asian, Polynesian and Pacific Panacea. Int J Cosmetic Sci 24: 1-8.

[13] ESCOUBAS P, LAJIDE L AND MITZUTANI J. 1995. Termite antifeedant activity in Afromomum melegueta. Phytochem 40: 1097-1099.

[14] GANAPATY S, THOMAS PS, FOTSO S AND LAATSCH H. 2004. Antitermitic quinines from Diospyros sylvatica. Phytochem 65: 1265-1271.

[15] GRACE JK AND YAMAMOTO RT. 1994. Natural resistance of Alaska-cedar, redwood and teak to Formosan subterranean termites. Forest Prod J 44(3): 41-45.

[16] hASHIMOTO k, oHTANI y AND sAMESHIMA k. 1997. termiticidal activity and its transverse distribution in camphor (Cinnamomum camphora) wood. Mokuzai Gakkaishi 43(7): 566-575.

[17] HATHURUSINGHA HMSD AND ASHWATH N. 2007. Beauty leaf (Calophyllum inophyllum L.) tree: A tree with great economic potential. In: Proceedings of 12th International Forestry and Environmet Symposium, Kalutara, Sri Lanka, 20 p.

[18] JAHIRUL MI, BROWN JR, SENADERA W, ASHWATH N, LAING C, LESKI-TAyLOR J AND RASUL MG. 2012. Optimisation of bio-oil extraction process from Beauty Leaf (Calophyllum inophyllum) oil seed as a second generation biodiesel source. In: Proceedings of the 5th BSME International Conference on Thermal Engineering, Sadrul AKM (Ed), Bangladesh Society of Mechanical Engineers, Dhaka, Bangladesh.

[19] KORDALI S, KESDEK M AND CAKIR A. 2007. Toxicity of monoterpenes against larvae and adults of Colorado potato beetle, Leptinotarsa decemlineata Say (Coleoptera: Chrysomelidae). Ind Crop Prod 26: 278-297.

[20] LITTLE NS, SCHULTZ TP AND NICHOLAS DD. 2010. Termite-resistant heartwood. Effect of antioxidants on termite feeding deterrence and mortality. Holzforschung 64: 395-398.

[21] MAHAMADI C, TOGAREPI E AND DZOMbA P. 2011. Extraction of phenolic compounds from Temnocalyx obovatus. Afr J Biotechnol 10(54): 11245-11248.

[22] MAO L AND HENDERSON G. 2007. Antifeedant activity and acute and residual toxicity of alkaloids from Sophora flavescens (leguminosae) against formosan subterranean termites (Isoptera: Rhinotermitidae). J Econ Entomol 100(3): 866-870.

[23] MISHA US, MURTHY PN, CHOUDHURY PK, PANIGRAHI G, MOHAPATRA S AND PRADHAN P. 2010. Antibacterial and analgesic effects of the stem barks of Calophyllum inophyllum. Int J Chem Technol Res 2(2): 973-979.

[24] MOAWAD SS, AL-BARTY A AND AL-OTAIBI NJ. 2012. Behavioural response of Anacanthotermes ochraceus towards some baits and volatile oils. J Agr Sci Tech B 2: 1279-1286.

[25] MORALES-RAMOS JA, ROJAS MG AND HENNON PE. 2003. Black-staining fungus effects on the natural resistance properties of Alaskan yellow cedar to the formosan subterranean termite (Isoptera: Rhinotermitidae). Environ Entomol 32(5): 1234-1241.

[26] MORIMOTO M, FUKUMOTO H, HIRATANI M, CHAVASIRI W AND KOMAI K. 2006. Insect antifeedants, pterocarpol, in heartwood of Pterocarpus macrocarpus Kruz. Biosci Biotechn Biochem 70: 1864-1868.

[27] MORISAWA J, KIM CS, KASHIWAGI T, TEBAYASHI SI AND HORIIKE M. 2002. repellents in the Japanese cedar Cryptomeria japonica against the Pill-bug, Armadillidium vulgare. Biosci Biotechn Biochem 66(11): 2424-2428.

[28] NADKARNI KM AND NADKARNI AK. 1999. Indian material medica with ayurvedic, unani-tibbi, siddha, allophatic, homoopathic, naturopathic and home remedies, vol. 2, Popular Prakashan Private Ltd. Bombay, India.

[29] NAKAYAMA FS, CHOW P, BAJWA DS, YOUNGQUIST JA, MUEHL JH AND KRYZIK AM. 2000. Preliminary investigation of the natural durability of Guayale (Parthenium argentatium) based wood products. The International Research Group on Wood Preservation. 31st Annual meeting Kona Hawaii USA, 14th - 19th May 2000.

[30] OHMURA W, DOI S, AOYAMA M AND OHARA S. 2000. Antifeedant activity of flavonoids and related compounds against the subterranean termite Coptotermes formosanus. Holzforschung 53: 569-554.

[31] ORDOñEZ AAL, GOMEZ JD, VATTUONE MA AND ISLA MI. 2006. Antioxidant activities of Sechlum edule (Jacq.) swart extracts. Food Chem 97: 452-458.

[32] PANDEY A, CHATTOPADHYAY P, BANERJEE S, PAKSHIRAJAN K AND SINGH L. 2012. Antitermitic activity of plant essential oils and their major constituents against termite Odontotermes assamensis Holmgren (Isoptera: Termitidae) of North East India. Int Biodeter Biodegr 75: 63-67.

[33] PATIL AD ET AL. 1993. The inophyllums, novel inhibitors of HIV-1 reverse transcriptase isolated from the Malaysian tree, Calophyllum inophyllum Linn. J Med Chem 36: 4131-4138.

[34] PERALTA RCG, MENEZES EB, CARVALHO AD AND AGUIAR-MENEZES EL. 2004. Wood consumption rate of forest species by subterranean termites (Isoptera) under field conditions. Rev Arvore 28: 1-12.

[35] RAGON kw, nICHOLAS dd AND sCHULTZ tp. 2008. termite effect of the non-biocidal antioxidant properties of the extractives (Isoptera: Rhinotermitidae). Sociobiol 52: 47-54.

[36] RICHARD WC, CATHERINE SR, MARK RS, DAVID CC AND MARK AS. 2012. Extraction of polar and nonpolar biomarkers from the martian soil using aqueous surfactant solutions. Planet Space Sci 67(1): 109-118.

[37] ROSZAINI K, RAFEADAH R AND MOHD DAHLAN J. 2009. Durability of Malaysian timbers against the Asian subterranean termite Coptotermes gestroi Wasmann. J Inst Wood Sci 19: 16-21.

[38] ROSZAINI K, NOR AZAH MA, MAILINA J, ZAINI S AND MOHAMMAD FARIDZ Z. 2013. Toxicity and antitermite activity of the essential oils from Cinnamomum camphora, Cymbopogon nardus, Melaleuca cajuputi and Dipterocarpus sp. against Coptotermes curvignathus. Wood Sci Technol 47(6): 1273-1284.

[39] SANTOS SRL, MELO MA, CARDOSO AV, SANTOS RLC, SOUSA DP AND CAVACANTI SCH. 2011. Structure-activity relationships of larvicidal monoterpenes and derivatives against Aedes aegypti Linn. Chemosphere 84: 150-153.

[40] SCHEFFRAHN RH. 1991. Allelochemical resistance of wood to termites. Sociobiol 19: 257-282.

[41] SEN-SARMA PK. 1963. Studies on the natural resistance of timbers to termites. Indian For Bull (Entomol) 20: 1-10.

[42] SEO SM, KIM J, LEE SG, SHIN CH, SHIN SC AND PARK IK. 2009. Fumigant antitermitic activity of plant essential oils and components from ajowan (Trachyspermum ammi), allspice (Pimenta dioica), caraway (Carum carvi), dill (Anethum graveolens), geranium (Pelargonium graveolens), and Litsea (Litsea cubeba) oils against Japanese termite (Reticulitermes speratus Kolbe). J Agric Food Chem 57(15): 6596-6602.

[43] SHARMA RN AND RAINA RM. 1998. Evaluating chemicals for eco-friendly pest management-I: Terpenoids and fatty acids for building termites. J Sci Ind Res 57: 306-309.

[44] SHIBUTANI S, SAMEJIMA M AND DOI S. 2004. Effects of stilbenes from bark of Picea glehnii (Sieb. et Zucc.) and their related compounds against feeding behaviour of Reticulitermes speratus (Kolbe). J Wood Sci (50): 439-444.

[45] SITI HUMEIRAH AG, NOR AZAH MA, MAILINA J, MUHAJIR H AND PUAD A. 2010. Chemical composition of three Xylopia leaf essential oils from Pasoh Forest Reserve, Negeri Sembilan, Malaysia. J Trop For Sci 22(1): 1-4.

[46] TAYLOR AM, GARTNER BL AND MORRELL JJ. 2006. Effects of heartwood extractive fractions of Thuja plicata and Chamaecyparis nootkatensison wood degradation by termites or Fungi. J Wood Sci 52: 147-153.

[47] TAYLOR WG AND SCHRECK CE. 1985. Chiral-phase Capillary Gas Chromatography and mosquito repellent activity of some oxazolidine derivatives of (+) and (-) - Citronellol. J Pharm Sci 74 (5): 534-539.

[48] WATANABE Y, MIHARA R, MITSUNAGA T AND YOSHIMURA T. 2005. Termite repellent sesquiterpenoids from Callitris glaucophylla heartwood. J Wood Sci 51(5): 514-419.

[49] XIE Y, WANG K, HUANG Q AND LEI C. 2014. Evaluation toxicity of monoterpenes to subterranean termite, Reticulitermes chinensis Snyder. Ind Crop Prod 53: 163-166.

[50] ZAHRAN HEDM AND ABDELGALEIL SAM. 2011. Insecticidal and developmental inhibitory properties of monoterpenes on Culex pipiens L. (Diptera: Culicidae). J Asia Pacific Entomol 14: 46-51.

Compound	RI	RA
Compound	RI	EtOH	MeOH	PETETHR
Abietadiene	3	-	2.95	-
β- Funebrene	409	2.96	-	-
Coniferyl alcohol <E->	464	2.63	-	-
Agarospirol	544	-	1.15	-
Presilphiperfolan-8-ol	647	-	-	1.83
Incensole acetate	722	2.08	-	-
Hexenyl cinnamate <3Z	810	-	-	2.64
Hydroxy Citronellol	825	-	1.63	-
Indipone	839	15.16	38.46	39.32
Larixol	982	-	12.38	-
Tetradectene <1->	1215	0.55	-	-
Stilbene	1437	-	1.47	-
Isobornyl isobutanoate <5-oxy->	1447	43.27	-	46.60
Occidenol	1481	-	1.38	-
Thujaplicinol	1495	-	8.02	-
Carvacrol, methyl ether	1503	29.91	19.12	2.30
Thymol	1506	-	-	2.70
Rosifoliol	1595	-	10.56	0.27
Isoprenyl cinnamate-(E)-methyl	1671	-	1.25	-
Methyl p-tert butylphenyl acetate	1697	1.93	2.45	-
Hexadecanoic acid	1742	0.56	1.53	-
Thujic acid	1850	-	-	2.15
Allo-hedycaryol	1856	-	-	1.47
Isovalencenol<(E)-	2173	0.41	-	-
Identified compounds (%)	99.46	99.47	99.28
Group components
Monoterpenes		75.11	28.27	53.75
Sesquiterpenes		0.41	14.96	3.57
Diterpenes		2.08	15.33	-
Phenylpropanoids		3.52	2.45	2.64
Alkaloids		18.34	38.46	39.32

Solvent	Unextracted	Extracted
Ethanol	0.68 (0.03)^a	0.65 (0.03)^a
Methanol	0.69 (0.02)^a	0.66 (0.02)^a
Petroleum ether	0.66 (0.02)^a	0.65 (0.02)^b

Brasil