Materials and Methods
2.1. Macroalgal resource assessment and screening of potential feedstock for biofuel production
Macroalgal sampling has been done monthly during low tide period. Due to the immersion and emersion periods in rocky
shore, a 0.25 m2 random quadrats sampling was carried out. Algal biomass within the quadrat were
handpicked, species-wise sorted and washed in seawater to remove adhering epiphytes. Collected samples were
identified using standard identification keys [61,136] and standing biomass was determined,
which is expressed in g/m2. In areas, where seaweeds were not accessible, only qualitative data such as
the presence of seaweed species were recorded with location details using high spatial resolution virtual remote
sensing data (Google Earth).
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- Biochemical composition along Central West Coast of India
Species samples were washed thoroughly in seawater, followed by tap water to clean debris of extraneous material.
Cleaned seaweeds were sun dried in the shade for 2-3 days, followed by drying in the hot air oven, below
60oC till constant weight is attained. The dried material was pulverized and sieved to obtain a uniform
particle size. The powder was preserved in a zip lock pouches for subsequent analysis of total carbohydrate [137], cellulose [138], protein [139], and
lipid [140] contents. Carbon, hydrogen and nitrogen were estimated using CHN elemental
analyser. These samples were analyzed in triplicates and the mean values were considered for further calculations
and results are expressed in mean±SD.
2.3. Macroalgal pretreatment process
Sugar from macroalgae was extracted using boiling water, sonication, dilute acid and alkali pretreatment. Seaweed was
boiled in a 10 ml water for 30 min, sonication was carried out using an ultrasonic bath (frequency 35 kHz) for 30
min. Dilute acid pretreatment involved 0.7 N H2SO4 and alkali pretreatment was carried out
using 5N NaOH for 30 min. Neutralization was carried out for U.lactuca and E.intestinalis acid
hydrolysate using Na2CO3, NaOH, Activated charcoal and Ca(OH)2. The sugar removal
(%) by these agents was calculated as per equation (Eq.1).
% Sugar removal = ((A - B)/A ) * 100 Eq1
Where, A is the amount of reducing sugar (mg/g) before treatment, and B is the amount of reducing sugar (mg/g) after
treatment [141].
2.4. Enzyme hydrolysis
Enzyme was isolated from marine bacteria Vibrio parahaemolyticus [90] and hydrolysis
was carried out for direct biomass and acid pretreated biomass for U.lactuca and E.intestinalis to
demonstrate the effect of acid pretreatment in enzyme hydrolysis. Enzyme hydrolysis was carried out at 55
oC up to 48 h and reducing sugar was estimated every 6 h.
2.5. Bioethanol production from selected macroalgae
Dried biomass (5% w/v) was pretreated using dilute (0.7N) H2SO4 to release sugars and estimated
for reducing sugars by 3, 5 dinitrosalicylic acid method [142]. Acid hydrolysate neutralized
using Na2CO3. Released fermentable sugars were subjected to fermentation using cashew yeast
(CY) and toddy yeast (TY) at 30oC for 18 h in Separate hydrolysis and fermentation (SHF).
Saccharification and Fermentation (SSF) was carried out using 2% (w/v) pretreated biomass and 6% (v/v) enzyme and
yeast were added to the medium and fermented using CY and TY at 55oC for 18h. Co-fermentation of algal
hydrolysate was also carried out for SHF and SSF. Ethanol was estimated using GC-FID. Bioethanol production from all
the macroalgal biomass was estimated based on published literatures and the probable relationship of ethanol yield
and multivariate is determined through regression analyses.