Currently, microalgae-based biodies

Currently, microalgae-based biodiesel production has been the
focus of attention for the scientific community for an extended
period of time (Chisti, 2007; Mata et al., 2010).

However, the industrialization
production of single biodiesel production from microalgae
still faced with the commercial barrier of high cost (Logan and
Ronald, 2011). In fact, besides lipid, microalgae are sunlight-driven
cell factories that convert carbon dioxide to carbohydrate, which
could also be considered as source for bioethanol production
(Efremenko et al., 2012).

In addition, microalgae based bioethanol fermentation display greater sustainable and commercial advantages over lignocellulosic biomass. Microalgae based carbohydrates are mainly in the form of polysaccharide, starch and cellulose (with the absence of lignin and low hemicelluloses content), these carbohydrates are much easier to convert to fermented monosaccharides (Harun et al., 2010; Harun and Danquah, 2011; John
et al., 2011).

Therefore, making full use of lipid and carbohydrate in as feedstock for joint production of biodiesel and bioethanol creates a potential way to cut the high cost of single biofuel production from microalgae.

In order to realize biodiesel conversion and bioethanol fermentation,microalgae biomass needs to be processed in order to extract lipid and release sugar (Talukder et al., 2012).

Ultrasonication method and cycled freezing – thawing method have been widely used to break the cell wall of microalgae for lipid extraction (Huang et al., 2014; Silva et al., 2014).

However, large scale lipid
extraction using ultrasonication method or freezing-thawing
method is no doubt to be less efficient and time consuming.
Considering the lipid droplets are in thylakoid enveloped by cell
walls, a reasonable way may be the hydrolysis, resulting the fully
disruption of cell structure to release lipid oil and saccharification
simultaneously.