| 1 - 1 |
Untitled
Chang JS, Yang JW, Lee DJ, Hallenbeck PC |
| 2 - 8 |
Integrating an algal beta-carotene hydroxylase gene into a designed carotenoid-biosynthesis pathway increases carotenoid production in yeast
Chang JJ, Thia C, Lin HY, Liu HL, Ho FJ, Wu JT, Shih MC, Li WH, Huang CC |
| 9 - 17 |
Isolation and screening of heterocystous cyanobacterial strains for biodiesel production by evaluating the fuel properties from fatty acid methyl ester (FAME) profiles
Anahas AMP, Muralitharan G |
| 18 - 22 |
The selective breeding of the freshwater microalga Chlamydomonas reinhardtii for growth in salinity
Takouridis SJ, Tribe DE, Gras SL, Martin GJO |
| 23 - 32 |
Gene silencing in microalgae: Mechanisms and biological roles
Kim EJ, Ma XR, Cerutti H |
| 33 - 41 |
Using recombinant cyanobacterium (Synechococcus elongatus) with increased carbohydrate productivity as feedstock for bioethanol production via separate hydrolysis and fermentation process
Chow TJ, Su HY, Tsai TY, Chou HH, Lee TM, Chang JS |
| 42 - 46 |
Isolation and characterization of microalgae for biodiesel production from seawater
Zhao L, Qi Y, Chen GY |
| 47 - 52 |
Rapid method to screen and sort lipid accumulating microalgae
Cabanelas ITD, van der Zwart M, Kleinegris DMM, Barbosa MJ, Wijffels RH |
| 53 - 62 |
Screening and characterization of oleaginous Chlorella strains and exploration of photoautotrophic Chlorella protothecoides for oil production
Sun Z, Zhou ZG, Gerken H, Chen F, Liu J |
| 63 - 72 |
Recent nanoparticle engineering advances in microalgal cultivation and harvesting processes of biodiesel production: A review
Lee YC, Lee K, Oh YK |
| 73 - 81 |
Water use and its recycling in microalgae cultivation for biofuel application
Farooq W, Suh WI, Park MS, Yang JW |
| 82 - 89 |
Building a better Mousetrap I: Using Design of Experiments with unconfounded ions to discover superior media for growth and lipid production by Chlorella sp EN1234
Hallenbeck PC, Grogger M, Mraz M, Veverka D |
| 90 - 99 |
Building a better mousetrap II: Using Design of Experiments with unconfounded ions to compare the growth of different microalgae
Hallenbeck PC, Grogger M, Mraz M, Veverka D |
| 100 - 107 |
Effect of carbon sources on growth and lipid accumulation of newly isolated microalgae cultured under mixotrophic condition
Lin TS, Wu JY |
| 108 - 115 |
Comparison between solar utilization of a closed microalgae-based bio-loop and that of a stand-alone photovoltaic system
Jin Q, Chen L, Li AM, Liu FQ, Long C, Shan AD, Borthwick AGL |
| 116 - 122 |
Fed-batch cultivation of Desmodesmus sp in anaerobic digestion wastewater for improved nutrient removal and biodiesel production
Ji F, Zhou YG, Pang AP, Ning L, Rodgers K, Liu Y, Dong RJ |
| 123 - 130 |
Utilization of biodiesel-derived glycerol or xylose for increased growth and lipid production by indigenous microalgae
Leite GB, Paranjape K, Abdelaziz AEM, Hallenbeck PC |
| 131 - 138 |
Effects of nitrogen source availability and bioreactor operating strategies on lutein production with Scenedesmus obliquus FSP-3
Ho SH, Xie YP, Chan MC, Liu CC, Chen CY, Lee DJ, Huang CC, Chang JS |
| 139 - 147 |
Impact of carbon and nitrogen feeding strategy on high production of biomass and docosahexaenoic acid (DHA) by Schizochytrium sp LU310
Ling XP, Guo J, Liu XT, Zhang X, Wang N, Lu YH, Ng IS |
| 148 - 152 |
The synergistic effects for the co-cultivation of oleaginous yeast-Rhodotorula glutinis and microalgae-Scenedesmus obliquus on the biomass and total lipids accumulation
Yen HW, Chen PW, Chen LJ |
| 153 - 160 |
Nitrogen recycling from fuel-extracted algal biomass: Residuals as the sole nitrogen source for culturing Scenedesmus acutus
Gu HY, Nagle N, Pienkos PT, Posewitz MC |
| 161 - 168 |
The use of Design of Experiments and Response Surface Methodology to optimize biomass and lipid production by the oleaginous marine green alga, Nannochloropsis gaditana in response to light intensity, inoculum size and CO2
Hallenbeck PC, Grogger M, Mraz M, Veverka D |
| 169 - 178 |
Heterotrophic microalgae cultivation to synergize biodiesel production with waste remediation: Progress and perspectives
Mohan SV, Rohit MV, Chiranjeevi P, Chandra R, Navaneeth B |
| 179 - 189 |
Cultivation of microalgal Chlorella for biomass and lipid production using wastewater as nutrient resource
Chiu SY, Kao CY, Chen TY, Chang YB, Kuo CM, Lin CS |
| 190 - 201 |
Biosequestration of atmospheric CO2 and flue gas-containing CO2 by microalgae
Cheah WY, Show PL, Chang JS, Ling TC, Juan JC |
| 202 - 214 |
Wastewater treatment high rate algal ponds (WWT-HRAP) for low-cost biofuel production
Mehrabadi A, Craggs R, Farid MM |
| 215 - 221 |
Biodiesel production from Scenedesmus bijuga grown in anaerobically digested food wastewater effluent
Shin DY, Cho HU, Utomo JC, Choi YN, Xu X, Park JM |
| 222 - 229 |
Enhancing microalgal photosynthesis and productivity in wastewater treatment high rate algal ponds for biofuel production
Sutherland DL, Howard-Williams C, Turnbull MH, Broady PA, Craggs RJ |
| 230 - 235 |
Combining urban wastewater treatment with biohydrogen production - An integrated microalgae-based approach
Batista AP, Ambrosano L, Graca S, Sousa C, Marques PASS, Ribeiro B, Botrel EP, Neto PC, Gouveia L |
| 236 - 244 |
Algaculture integration in conventional wastewater treatment plants: Anaerobic digestion comparison of primary and secondary sludge with microalgae biomass
Mahdy A, Mendez L, Ballesteros M, Gonzalez-Fernandez C |
| 245 - 250 |
Effects of pH control and concentration on microbial oil production from Chlorella vulgaris cultivated in the effluent of a low-cost organic waste fermentation system producing volatile fatty acids
Cho HU, Kim YM, Choi YN, Xu X, Shin DY, Park JM |
| 251 - 257 |
Current progress and future prospect of microalgal biomass harvest using various flocculation technologies
Wan C, Alam MA, Zhao XQ, Zhang XY, Guo SL, Ho SH, Chang JS, Bai FW |
| 258 - 266 |
Microalgal drying and cell disruption - Recent advances
Show KY, Lee DJ, Tay JH, Lee TM, Chang JS |
| 267 - 275 |
Advances in direct transesterification of algal oils from wet biomass
Park JY, Park MS, Lee YC, Yang JW |
| 276 - 279 |
Ultrasonic cavitation for disruption of microalgae
Greenly JM, Tester JW |
| 280 - 285 |
Energy evaluation of algal cell disruption by high pressure homogenisation
Yap BHJ, Dumsday GJ, Scales PJ, Martin GJO |
| 286 - 290 |
Extraction of lipids from microalgae using CO2-expanded methanol and liquid CO2
Paudel A, Jessop MJ, Stubbins SH, Champagne P, Jessop PG |
| 291 - 296 |
Supercritical fluid extraction of valuable compounds from microalgal biomass
Yen HW, Yang SC, Chen CH, Jesisca, Chang JS |
| 297 - 304 |
Mild disintegration of the green microalgae Chlorella vulgaris using bead milling
Postma PR, Miron TL, Olivieri G, Barbosa MJ, Wijffels RH, Eppink MHM |
| 305 - 313 |
Cascade approach of red macroalgae Gracilaria gracilis sustainable valorization by extraction of phycobiliproteins and pyrolysis of residue
Francavilla M, Manara P, Kamaterou P, Monteleone M, Zabaniotou A |
| 314 - 327 |
Thermochemical conversion of microalgal biomass into biofuels: A review
Chen WH, Lin BJ, Huang MY, Chang JS |
| 328 - 335 |
Characterization of aqueous phase from the hydrothermal liquefaction of Chlorella pyrenoidosa
Gai C, Zhang YH, Chen WT, Zhou Y, Schideman L, Zhang P, Tommaso G, Kuo CT, Dong YP |
| 336 - 343 |
Hydrothermal liquefaction of harvested high-ash low-lipid algal biomass from Dianchi Lake: Effects of operational parameters and relations of products
Tian CY, Liu ZD, Zhang YH, Li BM, Cao W, Lu HF, Duan N, Zhang L, Zhang TT |
| 344 - 348 |
Characterization of activated carbon prepared from chlorella-based algal residue
Chang YM, Tsai WT, Li MH |
| 349 - 354 |
Catalytic hydropyrolysis of microalgae: Influence of operating variables on the formation and composition of bio-oil
Chang ZF, Duan PG, Xu YP |
| 355 - 362 |
Exploring the potential of using algae in cosmetics
Wang HMD, Chen CC, Huynh P, Chang JS |
| 363 - 372 |
Extremophilic micro-algae and their potential contribution in biotechnology
Varshney P, Mikulic P, Vonshak A, Beardall J, Wangikar PP |
| 373 - 378 |
Omega-3 fatty acid production from enzyme saccharified hemp hydrolysate using a novel marine thraustochytrid strain
Gupta A, Abraham RE, Barrow CJ, Puri M |
| 379 - 385 |
Biological butanol production from microalgae-based biodiesel residues by Clostridium acetobutylicum
Cheng HH, Whang LM, Chan KC, Chung MC, Wu SH, Liu CP, Tien SY, Chen SY, Chang JS, Lee WJ |
| 386 - 394 |
Immobilization of beta-glucosidase from Aspergillus niger on kappa-carrageenan hybrid matrix and its application on the production of reducing sugar from macroalgae cellulosic residue
Tan IS, Lee KT |
| 395 - 404 |
Defatted algal biomass as a non-conventional low-cost adsorbent: Surface characterization and methylene blue adsorption characteristics
Chandra TS, Mudliar SN, Vidyashankar S, Mukherji S, Sarada R, Krishnamurthi K, Chauhan VS |
| 405 - 414 |
From microalgae oil to produce novel structured triacylglycerols enriched with unsaturated fatty acids
Wang J, Wang XD, Zhao XY, Liu X, Dong T, Wu FA |
| 415 - 420 |
Optimization of renewable pinene production from the conversion of macroalgae Saccharina latissima
Scullin C, Stavila V, Skarstad A, Keasling JD, Simmons BA, Singh S |
| 421 - 428 |
Lutein production from biomass: Marigold flowers versus microalgae
Lin JH, Lee DJ, Chang JS |
| 429 - 435 |
Enzymatic exploration of catalase from a nanoparticle producing and biodecolorizing algae Shewanella xiamenensis BC01
Ng IS, Xu FX, Zhang X, Ye CM |
| 436 - 443 |
Hybrid life-cycle assessment of algal biofuel production
Malik A, Lenzen M, Ralph PJ, Tamburic B |
| 444 - 452 |
The potentials and challenges of algae based biofuels: A review of the techno-economic, life cycle, and resource assessment modeling
Quinn JC, Davis R |
