Study on Photosynthetic Characteristics of Calophyllum inophyllum Linn.

[Objective] The experiment aimed to research the photosynthetic characteristics of Calophyllum inophyllum Linn.and the relations between Calophyllum inophyllum Linn. and ecological factors.[Method] The portable photosynthesis system(Li-6400) was used to determine photosynthetic characteristics of 6-year-old Calophyllum inophyllum Linn.[Result] Both the leaf net photosynthetic rate change and diurnal variation of transpiration rate were single peak type.The relations among the leaf net photosynthetic rate of Calophyllum inophyllum Linn.and photosynthetically active radiation,CO2 concentration and other relevant ecological factors(including transpiration rate, stomatal conductance, difference of vapour pressure and leaf temperature) were two quadratic linear relations.[Conclusion] Calophyllum inophyllum Linn. preferred strong light irradiation and high temperature environment and the experiment has provided foundations for ecological and commercial cultivations.

Variations in bark thickness and sapwood density of Calophyllum inophyllum provenances in Australia and in Sri Lanka

Sapwood density and bark thickness of Calophyllum inophyllum L. （a multipurpose durable timber species） were studied in various locations in Northern Australia and in Sri Lanka. Measurements were taken non-destructively by using core sampling and bark gauge. From each provenance, 4–15 mature trees having girth at breast height over bark （GBHOB） at 100–150 cm were selected on the basis of the population size. Significant （p0.05） hemispheric and provenance variations in bark thickness were found. Variations in the bark thickness are influenced by environmental variables. Variations in sapwood density were less pronounced compared to that of bark thickness. Variations in sapwood density are likely to be governed by genotypic variations.

Calophyllum inophyllum: recalcitrant or intermediate seed?

We studied seed storage behaviour of a multipurpose tree Calophyllum inophyllum （Clusiaseae）. Seeds were collected at Roslyn bay （2307′60＂ S, 150°43′60＂ E） Central Queensland. Seed drying and desieeation tolerance tests were carried out according to International Seed Testing Association （ISTA） rules. We found C. inophyllum seeds to be recalcitrant and vulnerable to chilling injury, hence, unsuited for cold storage. C. inophyllum seeds maintained their viability for an appreciable period （〉 8 months） if stored in wanner environments.

Reproductive phenology of Calophyllum inophyllum in Yeppoon, Australia and Meegoda Western Province, Sri Lanka

Reproductive phenology of multiple use native plant Calo- phyllum inophyllum L. was studied in Yeppoon （23°7＇60＂ S, 150°43＇60＂ E）, northern Australia （southern hemisphere） and in Meegoda （6°18＇51＂N, 80°31＇3＂E）, Sri Lanka （northern hemisphere）. C. inophyllum trees in Yeppoon, Australia had relatively shorter flowering periods, shorter floral life spans, longer fruit life spans, smaller flowers and larger fi＇uits compared to those in Meegoda, Sri Lanka. Although the number of flower buds/ inflorescence was comparatively higher in Meegoda, C. inophyllum trees in both locations had similar mean number of mature fruits/cluster due to the higher floral abscission in C. inophyllum trees at Meegoda. Despite having a comparatively lower fruit yield （664 000 fruts·ha^-1·a^-1）, C. inophyllum trees in Yeppoon hdd lligher kernel weights （2988.0±853.2 kg·ha^-1·a^-1） and oil yields （1 33226±380.5 kg·ha^-1·a^-1） compared to those in Meegoda.

Identification of phytochemical compounds in Calophyllum inophyllum leaves

Objectives: To investigate the proximate composition, mineral content, and phytochemical compounds in Calophyllum inophyllum(C. inophyllum) leaves. Moreover,isolation and identification of pyrene were also performed.Methods: C. inophyllum leaves were extracted with methanol by percolation methods.The proximate composition of C. inophyllum leaves was analyzed by standard methods.Mineral contents in this plant were analyzed by using atomic absorption spectrophotometer. Phytochemical screening and analysis of this plant were performed by spectrophotometric method. Washing method with carbon disulfide was used for isolating dihydropyrene compound from C. inophyllum leaves extracts.Results: The result revealed that C. inophyllum leaves contained 11.24% moisture,4.75% ash, 6.43% crude protein, 23.96% crude fiber, 9.91% carbohydrate, and energy(79.17 kcal/100 g). The leaves also contained 0.007% iron, 1.240% calcium, 0.075%sodium, 0.195% magnesium, 0.100% ppm potassium, and 0.040% phosphorus. Moreover, 11.51% alkaloid, 2.48% triterpenoid, 2.37% flavonoid, 7.68% tannin, 2.16%saponin, 2.53% polyphenol, were identified in the methanolic crude extracts of C. inophyllum leaves. It was found that trans-2-[2-(trifluoromethyl)phenyl]-10 b,10 c-dimethyl-10 b,10 c-dihydropyrene was obtained at purity of 79.18%(22.17% yield)from C. inophyllum leaves.Conclusions: C. inophyllum leaves may be used as a good source of fiber. It was found that C. inophyllum leaves have the potential as herbal drugs due to their phytochemical content. The separation, isolation, and purification of bioactive compounds from this methanolic crude extract and their biological activity are under further investigation.

Upgrading the Quality of Solid Fuel Made from Nyamplung (Calophyllum inophyllum) Wastes Using Hydrothermal Carbonization Treatment

One of the major problems faced in managing biomass waste to higher quality products is choosing the right technology.Wastes are used as an alternative fuel,with increase in the calorific value.Hydrothermal carbonization(HTC)is a biomass conversion technology,used to obtain solid fuel.This study aims to utilize of Calophyllum inophyllum as an alternative solid fuel through HTC.The calorific value and proximate of the hydrochar will be determined and analyzed to find out its quality.The experiments were carried out at temperature variations of 160℃,190℃,and 220℃ and holding times of 30 and 60 minutes.The results show that an increase in temperature and holding time causes a decline in the moisture content 1.87%,volatile matter 54.03%,and ash content 12.35%,respectively,leading to elevations in the fixed carbon at 31.75%.In addition,the highest calorific value of 4149 Kcal/Kg was produced at a temperature of 220℃,within a holding time of 60 minutes.The results showed a significant increase in the quality of solid fuels between 3500–4611 Kcal/Kg in accordance with the American Standard Testing and Materials(ASTM).Therefore,this research leads to an important finding that Calophyllum inophyllum waste through the HTC process can be used as an alternative fuel to substitute lignite coal,which is environmentally friendly.

广西特色药材横经席鉴别方法的研究

目的:建立横经席专属性鉴别方法。方法:采用性状、显微及薄层色谱相结合的方法对横经席及其同属品种绣毛红厚壳、红厚壳进行对比研究,找到横经席的鉴别特征。结果:横经席性状鉴别特征为叶呈长圆状披针形,两面无毛;锈毛红厚壳叶呈矩圆形至椭圆形,两面主脉及小枝均密被锈红色柔毛;红厚壳叶呈宽椭圆形或倒卵状椭圆形,两面无毛。横经席粉末显微特征可观察到叶表皮细胞、纤维等,无非腺毛;锈毛红厚壳粉末可见较多非腺毛;红厚壳叶下表皮细胞垂周壁波浪状弯曲并呈连珠状增厚。薄层色谱鉴别结果显示,横经席比同属其他品种多1个特征斑点。结论:研究建立的横经席鉴别方法具有专属性,可区别横经席正品及其混伪品。

真菌诱导子对胡桐悬浮培养细胞产生红厚壳素的影响

目的 探讨真菌诱导子对胡桐悬浮培养细胞产生红厚壳素的影响。方法 通过对胡桐叶斑病病菌的分离培养 ,制成真菌诱导子补加到胡桐细胞悬浮培养基中 ,考察不同浓度、不同加入时间对胡桐细胞生物量及红厚壳素产量的影响。结果 S I菌株诱导胡桐CR2细胞合成红厚壳素的最佳浓度为 60mgGE·L- 1,诱导子在细胞生长静止期初期 (即培养d 18)加入对红厚壳素产量影响最大 ,可使产量提高 2 7% ,并促进了红厚壳素向胞外分泌。

红厚壳挥发油化学成分

The volatile oil of Calophyllum inophyllum Linn.in twigs was extracted with the steam distillation and analysed by GC-MS.Twenty-six compounds were characterized.The major constituents were identified as δ-amorphene(14.63%),β-caryophyllene(13.13%),γ-cadinene(10.22%),α-caryophyllene(8.87%),α-farnesene(7.80%),etc.

不同氮素水平对红厚壳幼苗生长及光合特性的影响

采用温室盆栽方法,设置0(对照)、50、100、150、200、300、400、600 mg.株-18个氮素处理,研究氮素供应对红厚壳幼苗生长及光合特性的影响。结果表明:随供氮量的增加,红厚壳幼苗高、地径、叶面积及整株生物量均呈现出先增加后降低的趋势,均在200 mg.株-1时达到峰值,分别为22.06 cm、0.65 cm、327.27 cm2和10.43 g.株-1,是对照的1.59、1.25、2.58、1.90倍;地下生物量N5显著高于N7、N8处理,但与其余处理无显著性差异,根冠比随供氮量的增加呈现单调递减趋势;红厚壳幼苗叶绿素a、b及总量随供氮量的增加而增加;红厚壳幼苗的净光合速率、气孔导度、胞间CO2浓度以及蒸腾速率随供氮量的增加呈现出先增加后减小的趋势,均在200 mg.株-1时达最大值,分别是7.29μmol.m-2.s-1、0.071 mol.m-2.s-1、220.22μmol.mol-1和1.34 mmol.m-2.s-1,分别是对照的2.26、1.92、1.37、1.79倍,不同氮素处理间红厚壳光合气体交换参数差异均显著。结果表明:施氮量200 mg.株-1左右为红厚壳幼苗温室栽培的最佳施肥量。

红厚壳光合特性及其与生态因子的关系

红厚壳(Calophyllum inophyllum Linn.)经济价值和生态效益十分巨大,为了研究其光合特性及其与生态因子的关系,为其生态栽培和商业栽培提供理论依据,对栽植6a的红厚壳利用便携式光合作用测定系统LI-6400测定其光合特性,试验包括以下在自然生长的条件下测定叶片光合、蒸腾作用的日变化规律;控制CO2浓度,测定叶片在不同光合有效辐射强度下光合作用的变化规律;控制光合有效辐射强度,测定叶片在不同CO2浓度下光合作用的变化规律。试验结果表明:(1)红厚壳叶片净光合速率与蒸腾速率日变化均为单峰型;(2)红厚壳叶片净光合速率与光合有效辐射、CO2浓度及其它相关生态因子(包括有蒸腾速率、气孔导度、水汽压差和叶温)均呈二次线性关系。红厚壳适于生长强光、高温的环境。

红厚壳的光合水分生理生态特性

研究了海南岛低山丘陵区红厚壳(Calophyllum inophyllum Linn.)在30℃温度条件下,不同光合有效辐射(PAR)强度及不同CO2摩尔分数(Ca)范围内叶片光合及水分生理生态参数的变化特征。结果表明:(1)400μmol/molCO2摩尔分数条件下,红厚壳叶片净光合速率(Pn)与PAR之间的回归方程:Pn=-1.3×10-6PAR2+4.89×10-3PAR-0.40902,相关系数(r)可达0.9214;光饱和点、补偿点及表观量子效率分别为1880.77μmol/(m2.s),85.59μmol/(m2.s),0.01644mol/mol;叶片蒸腾速率(Tr)与PAR间回归方程:Tr=-6.7098×10-8PAR2+2.8×10-4PAR+0.29612,相关系数r=0.8998;叶片水分利用率(WUE)与PAR间回归方程:WUE=-3×10-6PAR2+0.01093PAR-1.71097,二次回归关系较弱,相关系数为0.7601(n=39);(2)PAR为1000μmol.m-2.s-1PAR条件下,Pn与CO2之间回归方程Pn=-5.73×10-6Ca2+0.0161Ca-0.9765,相关系数r为0.9936,CO2饱和点、补偿点及羧化效率分别为1404.89μmol/mol,62.01μmol/mol,0.01598mol/mol;叶片蒸腾速率与Ca间回归方程:Tr=1.1804e-0.0009Ca,相关系数r为0.9803,水分利用率随CO2的增加呈直线上升,二者正相关明显WUE=2.33×10-2Ca-3.116,相关系数r为0.9821(n=36)。

不同缺素处理对红厚壳幼苗生长的影响

设置全素、缺氮、缺磷、缺钾、缺钙、缺镁和缺硫7种处理,采用温室水培方法进行红厚壳苗期缺素试验。结果表明:(1)各缺素处理均对幼苗产生影响,主要表现为植株矮小,叶片变黄,部分出现褐斑及坏死等现象,其中缺氮、缺钾和缺硫处理的症状最为明显。(2)与对照相比,各缺素处理的地径、叶面积、苗高以及生物量均显著降低,缺氮和缺硫处理幼苗的光合色素含量显著低于全素处理。(3)缺素处理导致叶片养分元素之间产生一定的协同和拮抗作用,各缺素处理中缺乏的元素是幼苗生长的第1限制因子,但第2限制因子存在差异。

壳聚糖涂膜对海红果贮藏效果的影响

以壳聚糖为成膜物质制得可食性涂膜保鲜剂,研究其不同浓度(1%、1.5%、2%)对海红果贮藏生理及效果的影响,结果表明:涂膜处理可以明显抑制果实的叶绿素分解、硬度下降、可溶性固形物含量下降、Vc含量下降和酸含量下降。其中以1.5%壳聚糖涂膜处理效果最佳。

红厚壳中黄酮类化学成分研究

目的：研究红厚壳茎叶的化学成分。方法：利用硅胶柱色谱，Sephadex LH-20柱色谱，PTLC等手段进行化合物的分离，运用^1H，^13C，2D-NMR，MS等波谱分析法确定结构。结果：分离并鉴定了9个黄酮类化合物，分别为：2-羟基咄酮（1），4-羟基咄酮（2），1，5-二羟基咄酮（3），1，7-二羟基咄酮（4），1，3，5．三羟基-2-甲氧基咄酮（5），6-deoxyjacareubin（6），穗花杉双黄酮（7），山柰酚-3-O-α—L-鼠李糖苷（8），槲皮苷（9）。结论：化合物8和9为首次从红厚壳属植物中得到，化合物1，2，4—6为首次从该植物中得到。

红厚壳在海南岛的分布及其生长习性

红厚壳在海南岛一直是适应性强、分布广泛的珍贵植物资源。调查结果表明,在经济建设、农业土地开发等压力下,海南岛的红厚壳植物资源正日趋减少,目前仅在琼山、文昌等地区还保留较丰富,南部地区已绝迹,西部地区也难以见到。

海南滨海木麻黄林下三种乡土树种的光合特性

主要研究了海南3种乡土树种肖槿Thespesia lampas、海棠果Calophyllum inophyllum、莲叶桐Hernandia sonora在海岸木麻黄林下生长的光合作用特征。定植植株的滨海沙土进行了添加木屑、蔗渣、及空白对照处理。用Li-6400便携式光合仪测定净光合速率(Pn)、气孔导度(Ccond)、胞间CO2浓度(Ci)和蒸腾速率(Tr)。结果表明:1)3种乡土树种一年中的Pn、Ccond、Tr日平均最大值均表现为肖槿>莲叶桐>海棠果。2)不同土壤处理下,肖槿、海棠果、莲叶桐Pn、Ccond、Ci、Tr日变化基本相似,只有添加蔗渣处理的肖槿、莲叶桐叶片在2009年11月Ccond、Tr明显大于对照处理,添加木屑处理的海棠果叶片在2009年8月Ccond、Tr明显大于对照处理;3)4个光合参数在一年的四次测定中,肖槿、莲叶桐的日变化曲线主要为单峰型,仅在2月份Pn、Ci日变化出现双峰;海棠果的日变化曲线也主要为单峰型,仅在5月份Pn、Tr日变化以及2月份Ci日变化出现双峰;且肖槿只有Ci在5月份达到一年中最大值,Pn、Ccond、Tr均在8月份达到一年中最大值;而海棠果和莲叶桐的Pn、Ccond、Ci、Tr均在5月份达到一年中最大值。4)这3种乡土树种均具有较好的光合能力和水分利用率,肖槿Pn在8月份达到一年中最大值7.68 mmol.m-2s-1,而海棠果和莲叶桐的Pn均在5月份达到一年中最大值,分别为3.82和4.13 mmol.m-2s-1;3种植物的水分利用率均在2月份达到一年中最大值,分别为9.96、12.43和19.56 mmol.mol-1。研究发现它们能在木麻黄林下的滨海沙地上良好地生长,可以作为与木麻黄林混交的树种。

海棠果油的提取及其理化性质和脂肪酸组成分析

采用浸提法对海南海棠果种仁油脂的提取工艺进行了研究,并分析了海棠果油的理化性质和脂肪酸组成。结果表明,提取海棠果油的适宜条件为:将海棠果种仁粉碎并干燥至水分含量在4.75%以下,以石油醚为提取溶剂,液料比为8,30℃提取12 h,重复提取2次,出油效率可达95.86%。所得海棠果油酸价为26.90 mgKOH/g,过氧化值为1.41 mmol/kg,碘值为55.54 gI2/100 g,皂化值为166.42。经过GC-MS分析,共检出了14种脂肪酸,占总脂肪酸质量的99.92%,其中油酸占42.05%,亚油酸占26.57%,棕榈酸占13.62%,硬脂酸占15.78%。

红厚壳中两个新呫酮类化合物的结构研究

呫酮类化合物存在于很多藤黄科植物中,并具有多样的生物活性.为了进一步发现其活性成分,本文对藤黄科植物红厚壳根的化学成分进行了研究,从中分离得到11个呫酮类化合物,其中两个为新化合物.经多种光谱方法确定了各化合物的结构,两个新化合物分别命名为红厚壳呫酮C(Calophyllumin C)(1)和红厚壳呫酮M(Caloxanthone M)(2).

红厚壳茎叶的化学成分

目的研究红厚壳(Calophyllum inophyllumL.)茎叶的化学成分。方法用硅胶、SephadexLH-20柱色谱等方法进行分离纯化,根据理化性质及光谱数据确定化合物的结构。结果分离得到10个化合物,分别鉴定为蒲公英甾醇(taraxasterol,1)、豆甾醇(stigmasterol,2)c、lovane-2β,9-αdi-ol(3)、12-methoxyinophyllum D(4)、calophyllic acid和isocalophyllic acid(5)i、nophyllum D(6)、calo-phyllolide(7)、莽草酸(shikimic acid,8)、没食子酸(gallic acid,9)、原儿茶酸(protocatechuic acid,10)。结论化合物1和3为首次从该属植物中分离得到,化合物8为首次从该植物中分离得到。