tina sui
(Tina Sui)
#1
It should be noted here that thePenicilliumsp. lipase referred to above, is a dif-
ferent lipase from the ‘triglyceride-specific’ lipase described above for 1,2-diglycer-
ide production. Several strains ofPenicilliumspp. are known to produce both types
of lipases, i.e., one selective for, and the other selective against triglyceride hydro-
lysis and synthesis (Gulomova et al., 1996).
By combining the selectivity of the biocatalyst with adjustment of the reaction
conditions, and especially the reaction temperature, much better monoglyceride
yields were obtained. Using the partial glyceride-specific lipase fromPenicillium
cyclopiumat 40 8 C, up to 90 % (w/w) degree of conversion towards monoglycerides
was achieved, even when using palmitic acid (Weiss, 1990). This result is quite
remarkable, considering the fact that both the fatty acid substrate and the monogly-
ceride product are essentially solid at reaction temperature. Under these conditions,
dissolution of the fatty acid becomes the rate-limiting step, and hence the process
takes 10–15 days to complete. However, crystallization of the monoglycerides is
promoted, resulting in very high yield of near-pure product. Clearly, the particle
size and initial mixing are very important in starting the reaction and obtaining a
high yield (Weiss, 1991). Patatin could presumably be used in a similar process.
The selectivity of theP. cyclopiumlipase for mono- or diglyceride formation
during directed esterification could be changed in a similar way as described earlier
for theP. camembertiilipase. Increasing the water content in the glycerol from 5 %
(w/w) up to 20 % (w/w), the product composition changed from monoglycerides to
near-pure diglycerides (Weiss, 1990).
Temperature control, as applied above, also appeared crucial during the directed
glycerolysis of triglycerides. Using the nonspecific lipases fromPseudomonas fluor-
escenssp. orChromobacterium viscosum(Rosu et al., 1999; McNeill and Berger,
1993; McNeill et al., 1991), high-yield monoglyceride synthesis was obtained, sim-
ply by controlling the reaction temperature below a certain upper limit – referred to
as the ‘critical temperature’ (McNeill et al., 1991). It was shown that this ‘critical
temperature’ was dependent on the saturation level and the type of triglyceride sub-
strate involved. Monoglyceride yields between 70 % (w/w) and 90 % (w/w) were
reported, predominantly consisting of the 1-isomer (Bornscheuer et al., 1994;
Rosu et al., 1997).
As discussed earlier, recovery of the lipase during directed glycerolysis is rather
difficult. Applying solvent-based systems, this problem can easily be solved using
other means of directing synthesis towards monoglyceride production. In these cases
the reaction mixture is circulated over an enzyme reactor and a separator vessel,
removing the monoglycerides from the product mixture by selective adsorption
(Padt et al., 1990), crystallization (Berger and Schneider, 1993) or extraction (Ste-
venson et al., 1992). As the removal system is monoglyceride selective a conven-
tional non-selective lipase can be applied.
18 1 The Exploitation of Lipase Selectivities for the Production of Acylglycerols
