4. DiscussionTo our knowledge, this

4. Discussion
To our knowledge, this is the first work performedevaluating diet utilization in abalone postlarvae usingmore than one or two response variables, such as growth biochemical composition. Here a multidisciplinaryapproach was utilized to evaluate growth, survival, feed, digestibility, energy budget, feed impact on
tissue fatty acids and digestive enzyme activities. The
data presented here demonstrates that a single diatom
(NAV) or a combination of all three diets (MIX) resulted
in the highest growth and survival. This last is opposite to
that reported by Gordon et al. (2006) where a mixture of
microalgae resulted in better growth than single strains.
Moreover Gordon et al. (2004) concluded that larvae
settlement was not related to the biochemical composition
of microalgae. These contradictory results could be
due to differences in microalgae strains. Growth rates
obtained in the present study are similar to those reported
in earlier studies for other abalone postlarvae, ranging
from 21.7 to 60.6 μm day− 1 (Takami et al., 1997;
Kawamura et al., 1998a) even for the same specie
(Uriarte et al., 2006) with a quite good survival for MIX
and NAV treatments (over 83%). The factors associated
to the higher growth and survival in the present work are
related to several factors, like chemical composition, in
particular ash and lipid content of the diatoms. NIT and
AMP treatments resulted in a lower postlarvae growth
and survival. These diets contained high ash and in the
case of AMP a low lipid level. Moreover, high values of
apparent digestibility were associated with the NAV diet,
which contained the lowest content in ash and the highest
lipid content, whereas NIT resulted in the highest ash
content with the lowest digestibility.
The feed ingestion reported here resulted in extremely
low values and much lower to those reported earlier
for juvenile abalone (Gómez-Montes et al., 2003;
Montaño-Vargas et al., 2005) being not enough to support
the reported growth. It appears that the methodology
utilized was not adequate for our purposes and
significantly underestimated feed intake. The method
used here requires the measurement of cleared patches
by the abalone using fixed images from a video recorder
(photographs) taken at different times and extrapolating
to the complete plate (5 cm of diameter). Even if several
areas are taken per plate, it seems that 5 postlarvae per
plate are not enough to accurately represent what is
occurring in the whole plate. Thus, it is recommended
for future measurements, the registration from each
single postlarvae following their feeding path along time
in order to quantify the area clear by one postlarvae
through time, from several postlarvae in each experimental
unit per triplicate. This should give more accurate
estimates of feed intake per organism while
feeding. Additionally, our FCE values were exceptionally
high and unrealistic, resulting from our feed intake
underestimation.
Since an accurate estimate of feed intake was lacking
in the present work, to build the energy budget it was
decided to back calculate feed intake based on the
minimum feed intake required to obtain the observed
growth. In order to do this, digestibility values of each
diet were combined with the caloric estimates of growth
and respiration, assuming no other energy loss. In this
way it was possible to estimate a caloric intake equivalent
to 25 to 35 cal day− 1 g abalone− 1 to sustain the best
growth (NAVand MIX, respectively). In an earlier study
with juveniles of the same species an estimated caloric
intake of 60 cal day− 1 g abalone− 1 was obtained
utilizing more accurate feed intake values (Gómez-
Montes et al., 2003). Nonetheless, in the latter study a
certain amount of energy could not be explained (ranging
from 7 to 28% of the total caloric intake). Additionally,
the lower values obtained in the presented study (25 to
35 cal day− 1 g abalone− 1) could be partially explained
by the fact that here it was not considered energy lost due