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energies
Article
Brosimum Alicastrum as a Novel Starch Source for
Bioethanol Production
Edgar Olguin-Maciel 1, Alfonso Larqué-Saavedra 2, Daisy Pérez-Brito 3, Luis F. Barahona-Pérez 1,
Liliana Alzate-Gaviria 1, Tanit Toledano-Thompson 1, Patricia E. Lappe-Oliveras 4,
Emy G. Huchin-Poot 1and Raúl Tapia-Tussell 1,*
1Unidad de Energía Renovable, Centro de Investigación Científica de Yucatán AC,
Carretera Sierra Papacal-ChuburnáPuerto, Km 5, Sierra Papacal, Mérida 97302, Yucatán, Mexico;
edgar.olguin@cicy.mx (E.O.-M); barahona@cicy.mx (L.F.B.-P); lag@cic.mx (L.A.-G); tanit@cicy.mx (T.T.-T);
eghp.09@gmail.com (E.G.H.-P)
2Unidad de Recursos Naturales, Centro de Investigación Científica de Yucatán AC,
Calle 43 No. 130 x 32 y 34 Col. Chuburnáde Hidalgo, Mérida 97205, Yucatán, Mexico; larque@cicy.mx
3Laboratorio GeMBio, Centro de Investigación Científica de Yucatán AC,
Calle No. 130 43 x 32 y 34 Col. Chuburnáde Hidalgo, Mérida 97205, Yucatán, Mexico; daisypb@cicy.mx
4Laboratorio de Micología, Instituto de Biología, Universidad Nacional Autónoma de México,
Ciudad de México 04510, Mexico; lappe@ib.unam.mx
*Correspondence: rtapia@cicy.mx; Tel.: +52-999-942-8330
Received: 4 September 2017; Accepted: 6 October 2017; Published: 12 October 2017
Abstract:
Ramon (Brosimum alicastrum) is a forest tree native to the Mesoamerican region and the
Caribbean. The flour obtained from Ramon seeds is 75% carbohydrate, of which 63% is starch,
indicating its potential as a novel raw material for bioethanol production. The objective of this study
was to produce ethanol from Ramon flour using a 90
◦
C thermic treatment for 30 min and a native
yeast strain (Candida tropicalis) for the fermentation process. In addition, the structure of the flour
and the effects of pretreatment were observed via scanning electron microscopy. The native yeast
strain was superior to the commercial strain, fermenting 98.8% of the reducing sugar (RS) at 48 h
and generating 31% more ethanol than commercial yeast. One ton of flour yielded 213 L of ethanol.
These results suggest that Ramon flour is an excellent candidate for ethanol production. This is the
first report on bioethanol production using the starch from Ramon seed flour and a native yeast
strain isolated from this feedstock. This alternative material for bioethanol production minimizes the
competition between food and energy production, a priority for Mexico that has led to significant
changes in public policies to enhance the development of renewable energies.
Keywords: bioethanol production; starch; Brosimum alicastrum;Candida tropicalis
1. Introduction
The continued depletion of fossil fuels and the need to reduce greenhouse gas emissions to
mitigate global warming have generated an increasing worldwide interest in alternative energy
sources [
1
,
2
]. For this reason, the biofuel market has shown exponential growth in global production
in the past decade [
3
]. Among biofuels, bioethanol is the most frequently used, with a 2016 worldwide
production of 26,584 million gallons [
4
]. USA and Brazil are the major producers, generating 87% of
global bioethanol [3].
To avoid conflicts arising from designating land for food or energy production, the search and
characterization of inedible energy crops with a low requirement of agricultural management is
important [
5
]. The availability of local raw materials is also an important issue that must be addressed
when assessing feedstock viability [
6
]. In this regard, one alternative starch source is the Ramon tree
Energies 2017,10, 1574; doi:10.3390/en10101574 www.mdpi.com/journal/energies
Energies 2017,10, 1574 2 of 10
seed (Brosimum alicastrum Sw.) This tree is native to the Mesoamerican region and the Caribbean,
inhabiting warm, semi-warm, tropical, and mild climates—from 10 to 1600 m above sea level—and
growing in the wild in association with a variety of vegetation [7].
The north of the Yucatán peninsula consists mainly of semi-arid lands with poor soil quality that
does not support cultivation. B. alicastrum is one of the few forest species that actually thrive in this
area, with a seed production of 95.5 kg per tree per year, representing an annual seed productivity of
28.6 tons in a commercial plantation of 300 trees per hectare or 19.1 tons with 200 trees per hectare [
7
].
The flour obtained from Ramon seeds is 75% carbohydrate, of which, 63% is starch, indicating its
potential as a raw material for the bioethanol production, given that, nowadays, this seed is rarely
used for human consumption among the population of the Yucatan Peninsula [8].
Since this source of starch has not been studied previously for bioethanol production, it is
important to isolate native strains from the biomass that naturally ferment the tree fruits, allowing better
adaptation to the fermentation process, thus reducing time and production costs of second-generation
ethanol, and increasing yield [
9
,
10
]. In a previous study about Ramon’s mycobiota, different species of
native yeasts were isolated and characterized; the species Candida tropicalis was able to produce ethanol
from starch [
11
]. Therefore, this Candida species strain could be a good candidate for the fermentation
of Ramon’s must in the place of commercial strains as Saccharomyces cerevisiae.
The aim of this work was to use this novel source of starch and test a native yeast strain in
combination with a thermic pretreatment for bioethanol production.
2. Materials and Methods
2.1. Raw Material
B. alicastrum seeds were collected from different locations in the State of Yucatan, Mexico.
Each seed coat was removed manually. Then, the seeds were dried in a convection oven (Binder, Fed
model 115
®
, Tuttlingen, Germany) at 70
◦
C for 72 h, after which they were stored in a desiccator until
milling. The flour was obtained according to methodology described by Perez-Pacheco [
8
]. The starch
content was determined as per the method described previously by Holm [
12
] and protein content
was determined in accordance with Association of Analytical Chemists (AOAC) methods for proteins
(920.87) [13].
2.2. Scanning Electron Microscopy (SEM)
To study the microscopic structure of the flour and the effect of pretreatment, a scanning electron
microscope (SEM, model JSM-6360LV, JEOL, Tokyo, Japan) was used. Flour samples were mounted
on a metallic stub using double-sided adhesive tape coated with a 15 nm gold layer and observed at
20 kV.
2.3. Analytical Methods
Reducing sugar (RS) concentrations were determined in the hydrolysates and during fermentation
by the 3,5-dinitrosalicylic acid method [
14
]. The sample absorbance was measured at 550 nm.
For ethanol quantification, 25 mL of fermented sample was diluted with 25 mL of distilled water
and distilled at 100
◦
C until 25 mL of distillate was recovered. Gas chromatograph (GC) analysis
was carried out in a PerkinElmer Clarus 500 gas chromatograph (PerkinElmer, Waltham, MA, USA)
equipped with a Flame Ionization Detector. An EC-WAX capillary column (30 m
×
0.32 mm ID
(Internal diameter)
×
0.25
µ
m film thickness, Alltech) was used. The carrier gas was N
2
at 7 psi and
80 mL min−1
. Temperature conditions were 50
◦
C for 1 min, a 35
◦
C min
−1
ramp to 70
◦
C for 10 min.,
and a 35
◦
C min
−1
ramp to 100
◦
C for 7 min. Injector temperature was 150
◦
C and the FID detector
temperature was 200
◦
C. The sample injection volume was 1
µ
L. The external standard technique was
used for quantification of ethanol. The results were considered statistically significant if p< 0.05 using
Energies 2017,10, 1574 3 of 10
Tukey’s test. All of the statistical analyses were performed using SPSS 16
®
(SPSS Inc., IBM, Armonk,
NY, USA). All experiments were conducted in triplicate.
2.4. Enzymatic Hydrolysis
A suspension of Ramon flour (100 mL, 20% w/v) in sodium phosphate buffer (0.1 M) was prepared
and heated to 90
±
2
◦
C for 30 min in a water bath recirculator (Polyscience
®
, model 9505, Niles, IL,
USA) with constant agitation at 20 rpm. The samples were cooled to room temperature and used
straightaway in a liquefaction process.
2.4.1. Liquefaction
The pH of the flour suspension was adjusted to 6 with an alkaline solution of KOH (1 N). Then,
60 ppm of Ca
2+
was added in the form of calcium chloride in addition to 0.075 U of
α
-amylase enzyme
(a-7595 Sigma-Aldrich
®
, St Luis, MO, USA) per gram of starch present in the flour in accordance with
Barquera [15]. The mixture was homogenized, placed in the water bath recirculator and incubated at
85 ±2◦C for 1 h with constant agitation at 25 rpm.
2.4.2. Saccharification
The suspension obtained from the liquefaction was adjusted to pH 4.5 with Hydrochloric acid
(HCl) (1N). Then, 0.36 U amyloglucosidase enzyme (A-7095, Sigma-Aldrich
®
) was added per gram
of starch present in the flour and incubated at 60
±
2
◦
C for 24 h with constant orbital agitation
at 100 rpm on a MAXQ
™
4000 Benchtop Orbital Shaker (Thermo Scientific, Norcross, GA, USA).
After saccharification, samples were taken to measure the reducing sugar levels [15].
2.5. Yeast Strains
Candida tropicalis (PL1) was isolated from the pericarp of the B. alicastrum fruit. It was characterized
by phenotypic and molecular tests [
14
]. Commercial Saccharomyces cerevisiae was obtained from Safmex
S.A. de C.V. (Toluca, México). Both yeasts were maintained in tubes with YPD (yeast extract; peptone
and dextrose) medium containing yeast extract (5 g
·
L
−1
) peptone (10 g
·
L
−1
) and dextrose (20 g
·
L
−1
).
The inoculum of both strains was prepared in YPD supplemented with ammonium sulfate (1.5 g
·
L
−1
)
as a nitrogen source and incubated with orbital agitation at 30
±
2
◦
C for 6 h. In all cases, the inoculum
used had a concentration of 3 ×107cell mL−1.
2.6. Fermentation Conditions
Fermentation was performed in cotton stoppered 150 mL-Erlenmeyer flasks, under limited
anaerobic conditions, with 40 mL of hydrolyzed flour, and 10 mL of water at an initial concentration
of 77.18 g
·
L
−1
of RS. The pH was adjusted to 4.5, and 1.2 mL ammonium sulfate (1 N) was added.
Two mL (4% v/v) of inoculum were added to each sample and incubated at 35
±
3
◦
C for 48 h in
a drying chamber (Binder, Fed model 115
®
, Tuttlingen, Germany) without agitation. The fermentation
product was centrifuged at 4000 rpm for 20 min, and the supernatant was collected for distillation,
25 mL of fermented sample was diluted with 25 mL of distilled water, and distilled at 100
◦
C, until
25 mL of distillate was recovered. All of the tests were repeated three times.
3. Results and Discussion
Flour obtained from Ramon seeds exhibited a particle size between 0.425 and 0.600 mm in
diameter and 12% in moisture. This flour contains a high proportion of starch (61%) and 12.24%
total protein. The starch content is similar to the main sources of starch used for biofuels, including
cereals (60–80% starch), legumes (25–50% starch), tubers and roots (60–90% starch), and green and
immature fruits (as much as 70% starch) [
16
,
17
]. The main crops used are sorghum, wheat, cassava,
potatoes, and sweet potatoes [
16
,
18
,
19
], in addition to maize, which is the most widely-used starch
Energies 2017,10, 1574 4 of 10
crop for bioethanol production and has a starch content ranging from 60 to 85% depending on the
variety [20–22].
Scanning electron microscopy images showed a large amount of starch granules embedded
in a protein matrix (Figure 1a), which might act as a barrier during the amylolysis of starch
granules
[23,24]
. Martin and Lopez [
25
] suggest that these granules provide resistance to enzymatic
activity, as they are tightly packed by intra- and intermolecular hydrogen bonds in a polycrystalline
state, making them resistant to enzymatic treatments. Figure 1a shows different (spherical, elliptic,
and truncated) starch granule shapes, which agree with those reported for starch granules from
different sources such as potato, cassava, and chestnut [
26
,
27
]. In Figure 1b, the spherical shape of
a starch granule with dimensions of 15
×
15
µ
m is depicted, which agrees with the shape reported
by Pérez-Pacheco et al. [
8
], the first to study Ramon flour starch. They observed that Ramon starch
granules have an oval to spherical shape with diameters ranging from 6 to 15 µm.
Energies 2017, 10, 1574 4 of 9
are tightly packed by intra- and intermolecular hydrogen bonds in a polycrystalline state, making
them resistant to enzymatic treatments. Figure 1a shows different (spherical, elliptic, and truncated)
starch granule shapes, which agree with those reported for starch granules from different sources
such as potato, cassava, and chestnut [26,27]. In Figure 1b, the spherical shape of a starch granule
with dimensions of 15 × 15 μm is depicted, which agrees with the shape reported by Pérez-Pacheco
et al. [8], the first to study Ramon flour starch. They observed that Ramon starch granules have an
oval to spherical shape with diameters ranging from 6 to 15 μm.
Figure 1. Scanning electron microscopy (SEM) of B. alicastrum flour: (a) starch granules embedded in
a flour protein matrix; and (b) the size and shape of starch granules.
3.1. Enzymatic Hydrolysis
The effects of heating the flour suspension are shown in Figure 2b, in which a modification of the
protein matrix enhanced starch granule release compared to that in the untreated flour (Figure 2a), in
which granules were trapped and clustered in the protein matrix. The majority of released granules
maintained their structure, even though we used higher temperatures than those used by Chen et al. [28],
who reported that hydrothermal treatment at 62 °C induces changes to the physicochemical properties of
corn starch without destroying granule structure. The observed physicochemical changes involved the
release of dextrins and glucose molecules in small amounts into the solution [29], which coincides with
the present study, in which the RS value increased from 1.4 g∙L
−1
to 5.9 g∙L
−1
after the Ramon flour
suspension was heated.
Figure 2. Scanning electron microscopy (SEM) of B. alicastrum flour: (a) without pretreatment; and (b)
after thermic pretreatment 90 °C for 30 min.
Figure 2b shows that complete gelatinization was not obtained. This can be attributed to this
flour being not only starch, but a mixture that includes other components, such as proteins, which
Figure 1.
Scanning electron microscopy (SEM) of B. alicastrum flour: (
a
) starch granules embedded in
a flour protein matrix; and (b) the size and shape of starch granules.
3.1. Enzymatic Hydrolysis
The effects of heating the flour suspension are shown in Figure 2b, in which a modification
of the protein matrix enhanced starch granule release compared to that in the untreated flour
(Figure 2a), in which granules were trapped and clustered in the protein matrix. The majority of
released granules maintained their structure, even though we used higher temperatures than those
used by Chen et al. [
28
], who reported that hydrothermal treatment at 62
◦
C induces changes to
the physicochemical properties of corn starch without destroying granule structure. The observed
physicochemical changes involved the release of dextrins and glucose molecules in small amounts
into the solution [
29
], which coincides with the present study, in which the RS value increased from
1.4 g·L−1to 5.9 g·L−1after the Ramon flour suspension was heated.
Figure 2b shows that complete gelatinization was not obtained. This can be attributed to this flour
being not only starch, but a mixture that includes other components, such as proteins, which could
interfere negatively in the process of gelatinization. Furthermore, it might indicate that the temperature
of Ramon starch gelatinization is higher than 80
◦
C, the temperature at which the majority of starches
gelatinize [
30
]. This agrees with Perez Pacheco et al. [
8
], who found that the gelatinization point
for starch granules extracted from Ramon flour is 83.05
◦
C. Heat treatment followed by hydrolysis
increased the RS value by 33% compared with that in untreated flour (Figure 3).
Energies 2017,10, 1574 5 of 10
Energies 2017, 10, 1574 4 of 9
are tightly packed by intra- and intermolecular hydrogen bonds in a polycrystalline state, making
them resistant to enzymatic treatments. Figure 1a shows different (spherical, elliptic, and truncated)
starch granule shapes, which agree with those reported for starch granules from different sources
such as potato, cassava, and chestnut [26,27]. In Figure 1b, the spherical shape of a starch granule
with dimensions of 15 × 15 μm is depicted, which agrees with the shape reported by Pérez-Pacheco
et al. [8], the first to study Ramon flour starch. They observed that Ramon starch granules have an
oval to spherical shape with diameters ranging from 6 to 15 μm.
Figure 1. Scanning electron microscopy (SEM) of B. alicastrum flour: (a) starch granules embedded in
a flour protein matrix; and (b) the size and shape of starch granules.
3.1. Enzymatic Hydrolysis
The effects of heating the flour suspension are shown in Figure 2b, in which a modification of the
protein matrix enhanced starch granule release compared to that in the untreated flour (Figure 2a), in
which granules were trapped and clustered in the protein matrix. The majority of released granules
maintained their structure, even though we used higher temperatures than those used by Chen et al. [28],
who reported that hydrothermal treatment at 62 °C induces changes to the physicochemical properties of
corn starch without destroying granule structure. The observed physicochemical changes involved the
release of dextrins and glucose molecules in small amounts into the solution [29], which coincides with
the present study, in which the RS value increased from 1.4 g∙L
−1
to 5.9 g∙L
−1
after the Ramon flour
suspension was heated.
Figure 2. Scanning electron microscopy (SEM) of B. alicastrum flour: (a) without pretreatment; and (b)
after thermic pretreatment 90 °C for 30 min.
Figure 2b shows that complete gelatinization was not obtained. This can be attributed to this
flour being not only starch, but a mixture that includes other components, such as proteins, which
Figure 2.
Scanning electron microscopy (SEM) of B. alicastrum flour: (
a
) without pretreatment;
and (b) after thermic pretreatment 90 ◦C for 30 min.
Energies 2017, 10, 1574 5 of 9
could interfere negatively in the process of gelatinization. Furthermore, it might indicate that the
temperature of Ramon starch gelatinization is higher than 80 °C, the temperature at which the
majority of starches gelatinize [30]. This agrees with Perez Pacheco et al. [8], who found that the
gelatinization point for starch granules extracted from Ramon flour is 83.05 °C. Heat treatment
followed by hydrolysis increased the RS value by 33% compared with that in untreated flour (Figure 3).
Figure 3. Production dynamics of reducing sugars in the Ramon flour enzymatic hydrolysis. Open
symbols thermic pretreatment 90 °C for 30 min. and solid symbols without pretreatment. The results
are represented as the mean ± standard deviation of three parallel measurements (n = 3).
RS concentrations obtained at the two steps (liquefaction and saccharificaction) of the enzymatic
hydrolysis were higher in the thermal pretreatment (36.5 and 96.2 g∙L−1, respectively). These values
are similar to those obtained by Baks et al. [31], who reported a range of 15–30 g∙L−1 after liquefaction
and 40–98 g∙L−1 after saccharification. These results showed that a combination of thermal
pretreatment (90 °C for 30 min) with the enzyme concentrations used in this study providing
adequate RS concentrations for the fermentation process.
Heating exposes more starch granules to the action of the enzymes, as described by Dhital et al. [24],
Martín and López [25], and Pepe et al. [32], who suggest that heating the starch in an aqueous
suspension increases susceptibility to enzymatic hydrolysis. When the starch suspension is heated,
water first enters the amorphous regions, specifically in the hilum, which expands and transmits a
disruptive force to the crystalline regions. These changes are accompanied by the swelling of granules
which, under agitated conditions, increase viscosity, leading to eventual collapse and the formation
of a paste. When this occurs, α-amylase molecules progressively digest starch granules as they
gelatinize [33]. In contrast, in unmodified starches, enzymatic activity is decreased by several factors,
including the amylose–amylopectin ratio and interaction with protein components and lipids.
Among others, Wang et al. [34] established that unmodified starch is slowly digested by enzymes
due to the high molecular order of the intact granules; processes such as cooking disrupt the ordered
structure, resulting in increased susceptibility to enzymatic digestion.
3.2. Fermentation
After the production of hydrolysates from pretreated flour, the maximum RS level obtained had
a concentration of 77.18 g∙L−1. It was fermented using two strains of yeast: an industrial strain of S.
cerevisiae (Safoeno®) and a strain of C. tropicalis (PL1) isolated from Ramon seeds. Both strains
generated different fermentation profiles (Figure 4).
Figure 3.
Production dynamics of reducing sugars in the Ramon flour enzymatic hydrolysis.
Open symbols thermic pretreatment 90
◦
C for 30 min. and solid symbols without pretreatment.
The results are represented as the mean ±standard deviation of three parallel measurements (n= 3).
RS concentrations obtained at the two steps (liquefaction and saccharificaction) of the enzymatic
hydrolysis were higher in the thermal pretreatment (36.5 and 96.2 g
·
L
−1
, respectively). These values are
similar to those obtained by Baks et al. [
31
], who reported a range of 15–30 g
·
L
−1
after liquefaction and
40–98 g
·
L
−1
after saccharification. These results showed that a combination of thermal pretreatment
(90
◦
C for 30 min) with the enzyme concentrations used in this study providing adequate RS
concentrations for the fermentation process.
Heating exposes more starch granules to the action of the enzymes, as described by
Dhital et al. [
24
], Martín and López [
25
], and Pepe et al. [
32
], who suggest that heating the starch in
an aqueous suspension increases susceptibility to enzymatic hydrolysis. When the starch suspension
is heated, water first enters the amorphous regions, specifically in the hilum, which expands and
transmits a disruptive force to the crystalline regions. These changes are accompanied by the swelling
of granules which, under agitated conditions, increase viscosity, leading to eventual collapse and the
formation of a paste. When this occurs,
α
-amylase molecules progressively digest starch granules as
they gelatinize [
33
]. In contrast, in unmodified starches, enzymatic activity is decreased by several
Energies 2017,10, 1574 6 of 10
factors, including the amylose–amylopectin ratio and interaction with protein components and lipids.
Among others, Wang et al. [
34
] established that unmodified starch is slowly digested by enzymes
due to the high molecular order of the intact granules; processes such as cooking disrupt the ordered
structure, resulting in increased susceptibility to enzymatic digestion.
3.2. Fermentation
After the production of hydrolysates from pretreated flour, the maximum RS level obtained had
a concentration of 77.18 g
·
L
−1
. It was fermented using two strains of yeast: an industrial strain of
S. cerevisiae (Safoeno
®
) and a strain of C. tropicalis (PL1) isolated from Ramon seeds. Both strains
generated different fermentation profiles (Figure 4).
Energies 2017, 10, 1574 6 of 9
Figure 4. Fermentation profile of flour from B. alicastrum using two yeast strains: Solid symbols (S.
cerevisiae, Safoeno
®
) and open symbols (C. tropicalis, PL1). (a) Represents the consumption of reducing
sugars and (b) shows ethanol production. The results are represented as the mean ± standard
deviation of three parallel measurements (n = 3).
The Safoeno
®
strain began rapidly consuming RS, fermenting 80.4% of the total initial sugars in
the first 24 h (Figure 4a). After 36 h, the fermentation process was stopped, because the yeast did not
continue fermenting, leaving a residual 5% of RS. For the PL1 strain, the first 12 h of fermentation
was slower, and at 24 h, only 60% of the RS had been consumed. However, this strain fermented
98.8% of RS after 48 h. Figure 4b shows the marked difference between the ethanol production
profiles of both strains. In the first 12 h, the S. cerevisiae was more efficient than C. tropicalis, whereas
between 24 and 48 h the native strain (C. tropicalis) produced more ethanol (37.76 g∙L
−1
) than the
commercial strain (30.9 g∙L
−1
). This is associated with the ability of C. tropicalis to produce ethanol
from starch through the production of glucoamylase [35,36], which allows dextrin degradation
during the hydrolysis process, leading to a more efficient fermentation. GC analysis showed one
dominant analyte peak, which was identified as ethanol (Figure 5) based on the results obtained using
standard solutions.
Figure 5. GC chromatogram of the B. alicastrum distillation product fermented with two yeast strains:
(a) Internal standard; (b) S. cerevisiae (Safoeno
®
); and (c) C. tropicalis (PL1).
As shown in Figure 5b, the commercial S. cerevisiae (Safoeno
®
) strain produced less ethanol than
the native yeast strain isolated from B. alicastrum PL1 (Figure 5c). Currently, there is a tendency to
use strains isolated from spontaneous fermentations, because it is assumed that they will be better
adapted to the system. The calculation of ethanol production for both strains is shown in Figure 6.
Strain PL1 (Candida tropicalis) exhibited a 31% increase in ethanol production with respect to strain
Safoeno
®
(S. cerevisiae) with values of 213 and 147 mL∙kg
−1
flour, respectively.
Figure 4.
Fermentation profile of flour from B. alicastrum using two yeast strains: Solid symbols
(S. cerevisiae, Safoeno
®
) and open symbols (C. tropicalis, PL1). (
a
) Represents the consumption of
reducing sugars and (
b
) shows ethanol production. The results are represented as the mean
±
standard
deviation of three parallel measurements (n= 3).
The Safoeno
®
strain began rapidly consuming RS, fermenting 80.4% of the total initial sugars
in the first 24 h (Figure 4a). After 36 h, the fermentation process was stopped, because the yeast did
not continue fermenting, leaving a residual 5% of RS. For the PL1 strain, the first 12 h of fermentation
was slower, and at 24 h, only 60% of the RS had been consumed. However, this strain fermented
98.8% of RS after 48 h. Figure 4b shows the marked difference between the ethanol production
profiles of both strains. In the first 12 h, the S. cerevisiae was more efficient than C. tropicalis, whereas
between 24 and 48 h
the native strain (C. tropicalis) produced more ethanol (37.76 g
·
L
−1
) than the
commercial strain (
30.9 g·L−1
). This is associated with the ability of C. tropicalis to produce ethanol from
starch through the production of glucoamylase [
35
,
36
], which allows dextrin degradation during the
hydrolysis process, leading to a more efficient fermentation. GC analysis showed one dominant analyte
peak, which was identified as ethanol (Figure 5) based on the results obtained using standard solutions.
As shown in Figure 5b, the commercial S. cerevisiae (Safoeno
®
) strain produced less ethanol than
the native yeast strain isolated from B. alicastrum PL1 (Figure 5c). Currently, there is a tendency to
use strains isolated from spontaneous fermentations, because it is assumed that they will be better
adapted to the system. The calculation of ethanol production for both strains is shown in Figure 6.
Strain PL1 (Candida tropicalis) exhibited a 31% increase in ethanol production with respect to strain
Safoeno®(S. cerevisiae) with values of 213 and 147 mL·kg−1flour, respectively.
Energies 2017,10, 1574 7 of 10
Energies 2017, 10, 1574 6 of 9
Figure 4. Fermentation profile of flour from B. alicastrum using two yeast strains: Solid symbols (S.
cerevisiae, Safoeno
®
) and open symbols (C. tropicalis, PL1). (a) Represents the consumption of reducing
sugars and (b) shows ethanol production. The results are represented as the mean ± standard
deviation of three parallel measurements (n = 3).
The Safoeno
®
strain began rapidly consuming RS, fermenting 80.4% of the total initial sugars in
the first 24 h (Figure 4a). After 36 h, the fermentation process was stopped, because the yeast did not
continue fermenting, leaving a residual 5% of RS. For the PL1 strain, the first 12 h of fermentation
was slower, and at 24 h, only 60% of the RS had been consumed. However, this strain fermented
98.8% of RS after 48 h. Figure 4b shows the marked difference between the ethanol production
profiles of both strains. In the first 12 h, the S. cerevisiae was more efficient than C. tropicalis, whereas
between 24 and 48 h the native strain (C. tropicalis) produced more ethanol (37.76 g∙L
−1
) than the
commercial strain (30.9 g∙L
−1
). This is associated with the ability of C. tropicalis to produce ethanol
from starch through the production of glucoamylase [35,36], which allows dextrin degradation
during the hydrolysis process, leading to a more efficient fermentation. GC analysis showed one
dominant analyte peak, which was identified as ethanol (Figure 5) based on the results obtained using
standard solutions.
Figure 5. GC chromatogram of the B. alicastrum distillation product fermented with two yeast strains:
(a) Internal standard; (b) S. cerevisiae (Safoeno
®
); and (c) C. tropicalis (PL1).
As shown in Figure 5b, the commercial S. cerevisiae (Safoeno
®
) strain produced less ethanol than
the native yeast strain isolated from B. alicastrum PL1 (Figure 5c). Currently, there is a tendency to
use strains isolated from spontaneous fermentations, because it is assumed that they will be better
adapted to the system. The calculation of ethanol production for both strains is shown in Figure 6.
Strain PL1 (Candida tropicalis) exhibited a 31% increase in ethanol production with respect to strain
Safoeno
®
(S. cerevisiae) with values of 213 and 147 mL∙kg
−1
flour, respectively.
Figure 5.
GC chromatogram of the B. alicastrum distillation product fermented with two yeast strains:
(a) Internal standard; (b)S. cerevisiae (Safoeno®); and (c)C. tropicalis (PL1).
Energies 2017, 10, 1574 7 of 9
Figure 6. Comparison of ethanol yields obtained after fermentation of B. alicastrum flour with two
yeast strains. The results are represented as the mean ± standard deviation of three parallel
measurements (n = 3). Different letters represent significant differences at p < 0.05.
With the yield obtained in this work, it is possible to produce 213 L of ethanol per ton of flour.
Taking into account that B. alicastrum produces 95.5 kg of seed per tree per year [7], in a commercial
plantation of 300 trees per ha, 11.5 tons of flour could be produced. This would represent the
production of 2500 L of ethanol per ha per year, which is 50% of the maximum theoretical yield of
this raw material, making it attractive as an alternative source for bioethanol production.
When comparing these yields with those obtained from maize (417 L∙ton
−1
, 3336 L ethanol per
ha [37]), which is the main source of ethanol production from starch, we see that the yield from
Ramon is 25% lower than that from corn. However, one of the main advantages of Ramon starch is
that, unlike corn, it does not compete with the basic diet of the Mexican population. Moreover, as
Ramon is a perennial species, it contributes to carbon capture and helps to reduce the negative effects
of climate change. Neither does this tree require agricultural inputs for its establishment nor
management, which dampens biofuel production costs. In addition, as a dense, slow-growing timber
tree, it is likely to be used in carbon dioxide capture programs (or bonds) by producers. This study
demonstrates the potential of Ramon tree seeds for use in the sustainable production of bioethanol,
which is a priority for Mexico, which has led to significant changes in public policies to enhance the
development of renewable energies.
4. Conclusions
Ramon flour contains a high concentration of starch that can be converted into fermentable
sugars. Ramon seeds are rarely used for human consumption, and their use as animal feed is
negligible. The strain PL1 (C. tropicalis) isolated from Ramon fruits was superior to the Safoeno
®
strain, fermenting 98.8% of RS after 48 h and yielding 31% more ethanol than commercial yeast. We
calculated 213 L of ethanol per ton of flour, suggesting that Ramon flour is an excellent candidate for
ethanol production when used in combination with a thermic treatment (90 °C for 30 min) and a
native yeast strain. This is the first report of bioethanol production from Ramon starch using native
yeast strains isolated from this feedstock.
Acknowledgments: This work was financially supported by the Consejo Nacional de Ciencia y Tecnología
(CONACYT) of Mexico.
Author Contributions: All the authors contributed to this work. Raul Tapia-Tussell, Alfonso Larque-Saavedra,
and Daisy Perez-Brito conceived, designed, and wrote the paper; Edgar Olguin-Maciel, Emy G. Huchin-Poot,
Figure 6.
Comparison of ethanol yields obtained after fermentation of B. alicastrum flour with two yeast
strains. The results are represented as the mean
±
standard deviation of three parallel measurements
(n= 3). Different letters represent significant differences at p< 0.05.
With the yield obtained in this work, it is possible to produce 213 L of ethanol per ton of flour.
Taking into account that B. alicastrum produces 95.5 kg of seed per tree per year [
7
], in a commercial
plantation of 300 trees per ha, 11.5 tons of flour could be produced. This would represent the production
of 2500 L of ethanol per ha per year, which is 50% of the maximum theoretical yield of this raw material,
making it attractive as an alternative source for bioethanol production.
When comparing these yields with those obtained from maize (417 L
·
ton
−1
, 3336 L ethanol per
ha [
37
]), which is the main source of ethanol production from starch, we see that the yield from Ramon
is 25% lower than that from corn. However, one of the main advantages of Ramon starch is that,
unlike corn, it does not compete with the basic diet of the Mexican population. Moreover, as Ramon is
a perennial species, it contributes to carbon capture and helps to reduce the negative effects of climate
change. Neither does this tree require agricultural inputs for its establishment nor management, which
dampens biofuel production costs. In addition, as a dense, slow-growing timber tree, it is likely to
be used in carbon dioxide capture programs (or bonds) by producers. This study demonstrates the
potential of Ramon tree seeds for use in the sustainable production of bioethanol, which is a priority
Energies 2017,10, 1574 8 of 10
for Mexico, which has led to significant changes in public policies to enhance the development of
renewable energies.
4. Conclusions
Ramon flour contains a high concentration of starch that can be converted into fermentable sugars.
Ramon seeds are rarely used for human consumption, and their use as animal feed is negligible.
The strain PL1 (C. tropicalis) isolated from Ramon fruits was superior to the Safoeno
®
strain, fermenting
98.8% of RS after 48 h and yielding 31% more ethanol than commercial yeast. We calculated 213 L of
ethanol per ton of flour, suggesting that Ramon flour is an excellent candidate for ethanol production
when used in combination with a thermic treatment (90
◦
C for 30 min) and a native yeast strain. This is
the first report of bioethanol production from Ramon starch using native yeast strains isolated from
this feedstock.
Acknowledgments:
This work was financially supported by the Consejo Nacional de Ciencia y Tecnología
(CONACYT) of Mexico.
Author Contributions:
All the authors contributed to this work. Raul Tapia-Tussell, Alfonso Larque-Saavedra,
and Daisy Perez-Brito conceived, designed, and wrote the paper; Edgar Olguin-Maciel, Emy G. Huchin-Poot,
and Tanit Toledano-Thompson performed the experiments and analyzed the data; and Luis F. Barahona-Perez,
Liliana Alzate-Gaviria, and Patricia Lappe Oliveras participated in the data analysis and writing of the paper.
Conflicts of Interest: The authors declare no conflict of interest.
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