Results and DiscussionSago starch o

Results and Discussion
Sago starch obtained from all studied sources had similar characteristics, i.e. white
fine powder, particles with an oval shape (Figure 1) and an average size of 25.09 to 30.14
microns, and angle of repose was in the range of 37.93 to 40.12. It could be seen that the
shape of the sago starch was related to flowability. The pH values of all samples were
observed to be in the range of 6.97 to 7.09, implying it to be safe for skin application. The
scores of most specific properties, i.e. covering power, adhesiveness, absorbency, bloom and
spreading power, according to TIS 443-2525 were in fair levels while the scores of slip
property fluctuated between fair to good levels. No skin irritation was found. Therefore, it is
possible to use sago starch in cosmetic formulations by mixing with other cosmetic
acceptable ingredients (Boonmee et al. 2009a; Boonmee et al. 2009b; Boonmee et al. 2010).
Figure 1. Images of sago starch under light microscope with magnification of x40. From
right to left: 8B, 8M, 8T, 15B, 15M, and 15T, respectively.
Particles of sago starch could be seen in the prepared perfumed and cool body
powders while commercial products showed flake particles of talcum (Figure 2). The
obtained body powders had better flowability than pure sago starch due to the flow property
of talcum in the formulations. The pH values of the prepared products were 7.43 to 7.69, pH
increase might be caused by added ingredients. However, the product pH values were still
safe for the skin. The scores of all specific properties, i.e. slip, covering power, adhesiveness,
absorbency, bloom and spreading power, according to TIS 443-2525 were in good levels
which were better than sago starch. No skin irritation was found in the perfumed and cool
body powders containing sago starch. The good levels of users’ satisfaction were obtained
from questionnaires of both products. Thus, it is possible to use the perfumed and cool body
powders form the investigated formulations as merchandises (Boonme et al. 2009a; Boonme
et al. 2009b).
Figure 2. Images of body powders under light microscope with magnification of x40. From
right to left: prepared perfumed powders, commercial perfumed powders, prepared cool
powders, and commercial cool powders, respectively.
The major ingredients in mosquito repellant powders were 60% w/w sago starch and
15% w/w cajuput oil. It was found that the formulation with added talcum and magnesium
carbonate had more fine-looking appearance than that with added talcum only due to oil
absorption ability of magnesium carbonate. All prepared mosquito repellant powders
exhibited no mosquito repellant effectivity since the cajuput oil used could not perform
mosquito repellant effectivity. The soil minerals in the environment of growing area of
cajuput trees in this study may have caused the inability to make cajuput leaves synthesize
mosquito repellant chemicals such as monoterpenoids (e.g., -pinene, limonene, terpinolene,
citronellol, citronellal, camphor and thymol) and sesquiterpenes (e.g., -caryophyllene).
However, the powder formulation with aesthetic appearance after volatile oil incorporation
from this study can be adapted for mixing with other mosquito repellant volatile oils such as
citronella oil in further studies (Boonme et al. 2012).