Jac. Flipsen et al., MECHANISM OF REMOVAL OF IMMOBILIZED TRIACYLGLYCEROL BY LIPOLYTIC ENZYMES IN A SEQUENTIAL LAUNDRY WASH PROCESS, Enzyme and microbial technology, 23(3-4), 1998, pp. 274-280
Although the contribution of lipolytic enzymes to fatty soil removal a
fter repeated laundry wash cycles has been established the benefit of
lipolytic enzymes in detergent products after a single wash is margina
l. In order to improve fatty soil removal with the help of lipolytic e
nzymes during the main wash cycle, a two-step sequential wash system h
as been set up. Triglyceride oil, immobilized on a testcloth, is hydro
lyzed by the lipolytic enzyme during the first incubation. In a subseq
uent incubation, a detergent product was added to remove the fatty soi
l. In this sequential wash system, the commercially available Lipolase
(TM) did nor attribute to enhanced soil removal as water insoluble cal
cium soaps were formed. The use of a calcium-independent lipolytic enz
yme, cutinase, resulted in a significant increased soil removal. Durin
g the first incubation at pH 9, the soil was hydrolyzed for 65% within
30 min but only 20% of the products was removed. An increase in the p
H to pH > 10.5 was sufficient to remove the majority of the hydrolysis
products to the water phase. No detergent product needed to be added
It is concluded that the enzyme benefit in the sequential wash system
could be attributed to the partitioning of hydrolysis products over th
e water and oil phase. It is shown that the benefit of cutinase in a n
onsequential wash mainly could be attributed to its calcium independen
cy and the solubilization of hydrolysis products. (C) 1998 Elsevier Sc
ience Inc.