Composition analysis of the PHL
Pre-hydrolysis is the primary technology used for kraft-based dissolving pulp production. During the pre-hydrolysis stage, most hemicellulose and portion of lignin can be removed,which are depended upon both treatments conditions for different woody feedstocks [19, 25]. In consideration of these variables, it is necessary to obtain a detailed chemical composition of the mixed hardwood PHL used in this work. The chemical compositions of PHL are shown in Table 1. It can be seen that xylose (86.3 g/L) and xylooligosaccharide (32.3 g/L) are the major sugars in this PHL. In addition, a certain amount of glucose (7.5 g/L), arabinose (6.1 g/L) and sugar-derived byproducts (0.9 g/L of furfural and 0.4 g/L of HMF) were quantified. The high concentration of xylooligosaccharides in PHL confirms that this stream can be further transformed into xylose-rich solution by hydrolyzing xylooligosaccharides into xylose. The sugar contents in this PHL were significantly higher than those in the PHL (40-60 g/L) used in the work of Shi et al., (2012) [3]. This difference occurred because the used mixed hardwood PHL was obtained after steam concentration. In addition, it is important to note that a high concentration (42.1 g/L) of soluble lignin also existed in the PHL.
Table 1 Composition analysis of PHL, A-PHL, and P-A-PHL (g/L)
|
PHL a
|
A-PHL b
|
P-A-PHL c
|
Xylose
|
86.3±0.3
|
101.1±1.1
|
97.1±0.9
|
Glucose
|
7.5±1.2
|
8.8±0.3
|
8.4±0.1
|
Arabinose
|
6.1±0.2
|
4.5±0.2
|
4.3±0.5
|
HMF
|
0.4±0.2
|
1.9±0.1
|
0.04±0.01
|
Furfural
|
0.9±0.4
|
7.8±1.2
|
0.6±0.1
|
Xylooligosaccharide
|
32.3±2.1
|
/
|
/
|
Glucooligosaccharides
|
3.3±1.1
|
/
|
/
|
Soluble lignin
|
42.1±0.5
|
42.9±0.6
|
2.1±0.3
|
a: pre-hydrolysis liquor
b: PHL after acid-hydrolysis
c: A-PHL after purification by PS-DVB resin
Two-dimensional heteronuclear single-quantum coherence (2D-HSQC) NMR, an advanced technology that has been used to characterize samples with carbohydrate and lignin mixtures [31] or lignin-carbohydrate complexes [32], was carried out to understand the structural information of the chemical components in the PHL. The obtained spectra are shown in Fig. 1(a). Peaks in the 2D-HSQC spectra are assigned according to recent works [33,34].
The signals for internal xylan units (X) were clear and obvious in the spectra. Specifically, the C2/H2, C3/H3, C4/H4, and C5/H5 positions showed correlation signals at 72.3/3.03, 73.9/3.22, 75.3/3.48, and 62.9/3.15, 3.85 ppm, respectively. In addition, xylan with reducing-end units (XR) was also identified from the C2/H2 and C4/H4 correlation signals at 74.4/2.89 and 75.3/3.48 ppm, respectively. The presence of XR indicates that the soluble xylan (xylo-oligosaccharide) in the PHL possesses a relatively low degree of polymerization, which makes it a promising resource for xylose production [31].
In addition, the spectra of PHL showed common lignin substructures of β-O-4 (A), β−β (B), and β-5 (C), which can be identified by their Ca-Ha signals at 71.8/4.86, 84.9/4.69, and 86.8/5.49 ppm, respectively. Correlation signals for syringyl units (S) and guaiacyl units (G) were also noted from their C2-H2 and C2,6-H2,6 positions at 111.0/7.01 and 104.1/6.74 ppm, respectively. Hence, it can verify the lignin fraction was present in the PHL, which is in accordance with the results of the composition analysis.
Acid hydrolysis of the PHL
In previous work, it was reported that even though PS-DVB resin shows a low affinity for carbohydrates, some of high molecular weight carbohydrate linked to lignin can still be adsorbed by the resin [27, 29-30]. To reduce the loss of sugars in PHL and maximize the quantity of available fermentation substrate, the oligosaccharides in PHL were hydrolyzed into monosaccharides. Acid hydrolysis was carried out with sulfuric acid under different reaction conditions (acid concentration, time, and temperature) to obtain a recipe for maximizing xylooligosaccharide conversion into xylose.
The increase in xylose concentration in the PHL under different acid concentrations (1-5%) at 100 °C for 60 min is shown in Fig. 2a. First, increasing xylose concentrations were found with increasing acid catalyst concentrations. For example, the concentration of xylose in PHL increased from 86.1 g/mL to 95.4 g/L when the acid concentration was increased from 1% to 4%. However, a maximum was noted, as the xylose concentration decreased to 88.9 g/L when the acid concentration was further increased to 5%. This can be explained by the mechanism that xylose is easily dehydrated into furfural at higher acid concentration. As observed by Yang et al., (2012) [35], increasing the acid catalyst (formic acid) concentration from 5-10 g/L could effectively dehydrate xylose into furfural, with the yield rising from 15.8 % to 74%, indicating that xylose can be degraded with increasing acid concentration. Depending on the maximum xylose concentration in A-PHL, it can be speculated that 4% sulfuric acid was the optimum condition to produce the xylose from PHL.
According to the aforementioned results, the effects of different reaction temperature (90-130 oC) with 4% acid and 60 min of acid hydrolysis on increases in xylose concentration in PHL were investigated and are shown in Fig. 2b. The maximum concentration of xylose in A-PHL was 95.4 g/L at 100 oC. Increasing the reaction temperature from 100 oC to 130 oC significantly reduced the xylose concentrations from 95.4 g/L to 75.1 g/L. This result occurred because increasing the reaction temperature further accelerated the dehydration of xylose into furfural given the high acid dosage applied in this series of experiments [35]. Chen et al., (2018) [31] also found that the xylose in PHL could be further degraded under reaction temperatures from 120 oC to 135 oC with 4% aqueous sulfuric acid for 30 min. Based on the maximum xylose concentration in A-PHL, it can be speculated that acid hydrolysis with a 4% acid concentration at 100 oC was the optimum condition to produce the xylose from PHL.
The effect of the reaction time (20-100 min) of acid hydrolysis with 4% acid at 100 oC on xylose concentration in PHL is illustrated in Fig. 2c. It can be observed that the xylose concentration in the A-PHL increased first and then decreased with increasing reaction time from 20 min to 100 min. The optimal reaction temperature was 80 min, and a maximum xylose concentration of 101.1 g/L was obtained. Therefore, the highest xylose concentration in A-PHL (with a 17% increase relative to that of the original PHL) was obtained by acid hydrolysis at 100 oC for 80 min with 4% sulfuric acid dosage. These conditions approach to those of the work of Chen et al., (2018) [31], who found that an optimal xylose yield (30.10 g/L) from poplar PHL was obtained at 120 °C for 0.5 h with 4% aqueous sulfuric acid.
Although a higher xylose concentration can be obtained in PHL by applying acid hydrolysis, this method has also been shown to unavoidable lead to the dehydration of sugars (xylose and glucose) into fermentation inhibitors (furfural and HMF). As seen in Table 1, the PHL subjected to acid treatment under (A-PHL) the aforementioned optimal condition contained a higher xylose concentration than the original PHL. However, the concentration of furfural and HMF were 7.8 g/L and 1.9 g/L, respectively. These quantities are significantly higher than those in PHL (0.9 g/L and 0.4 g/L). In the reported work of Bellido et al (2011) [36], it was found that the pentose-fermenting yeast P. stipitis had poor tolerance towards furfural and HMF, with cell growth almost completely inhibited when the fermentation media contained at least 2 g/L furfural. In addition, various phenolic compounds formed from the degradation of lignin can inhibit the efficiency of ethanol fermentation. Zhou et al., (2017) [37] found a significant inhibitory effect of furfural occurred using a G. oxydans fermentation system with prehydrolyzate containing 6.5 g/L furfural, revealing the toxicity of furfural for XA production from G. oxydans. In addition, the concentration of water soluble lignin (44.9 g/L) was slightly increased in A-PHL relative to that in PHL. As pointed out by Wang and Chen (2011) [38], the high concentration (>2 g/L ) of lignin fractions in the sugar solutions can also cause an inhibitory effect on fermentation. Thus, removing the fermentation inhibitors in A-PHL not only provides a favorable environment for pentose-fermenting yeast but also removes a critical hurdle towards the fermentation of xylose to XA by G. oxydans.
Purification of PHL by PS-DVB resin
Lignin and sugar-derived byproducts in PHL are difficult to separate from sugars due to their similar molecular weights and water solubilities [27]. In this work, we used a lignin-selective adsorptive resin to separate the lignin and sugar byproducts (furfural and HMF) from A-PHL while retaining most of the sugars in the A-PHL. A diagram of the process used is shown in Fig. 3. The lignin and sugar byproducts in A-PHL can be adsorbed in the resin, while the purified sugar solution proceeds to the next unit operation. Ethanol can be used to regenerate the resin by desorbing the adsorbates and can also be recycled to prepare lignin-based materials. Importantly, the regenerated resin can be reused in another purification process to adsorb the lignin and sugar byproducts in A-PHL. Hence, the present concept for the purification of A-PHL by PS-DVB resin is inherently environmentally friendly and sustainable.
First, the most important parameter for resin separation technology, the feed flow rate, was optimized at 0.5-4 mL/min for the column (40×2 cm) with a solution loading of 500 mL for adsorption. As shown in Table S1, the resin’s ability to remove fermentation inhibitors (soluble lignin, furfural and HMF) was similar with an increase in flow rate from 0.5 mL/min to 2 mL/min. However, increasing the flow rate from 2 mL/min to 4 mL/min resulted in a decreased removal efficiency for fermentation inhibitors, even though there was no obvious decrease in sugars in the treated A-PHL. This result can be attributed to the fact that the higher flow rate might cause the solution (A-PHL) to pass through with a shorter retention time in the resin column, resulting in insufficient time for the PS-DVB resin to adsorb the fermentation inhibitors. This phenomenon is in agreement with the work of Lin et al. (2017) [39], who found that a higher resin feed flow rate could result in a higher Reynolds number and prolong the mass transfer zone, leading to a shorter breakthrough time and then decreasing the diffusion coefficient of the resin for the adsorption of substances in aqueous solution. Based on the best fermentation inhibitor removal performance of PS-DVB with the highest retention of xylose for subsequent fermentation, a feed flow rate of 2 mL/min was chosen as the optimal condition for the use of the resin.
As shown in Table 1, the concentration of soluble lignin, HMF, and furfural in PS-DVB treated A-PHL (P-A-PHL) were 1.1 g/L, 0.04 g/L, and 0.61 g/L, respectively. Each of these quantified values is significantly lower than that in the original A-PHL solution (46.9 g/L, 1.9 g/L, and 7.8 g/L, respectively). These results indicate that not only can 97% of the lignin be removed, but also 92-97% of sugars byproducts can be separated from the xylose solution. In addition, a high r proportion (96%) of xylose was retained in P-A-PHL. These results indicate that this process can simultaneously separate and recover lignin and sugars in PHL with recovery > 90%, which is more effective than the reported technologies of acidification, nanofiltration or microfiltration, applying cationic polymers (e.g., p-DADMAC), activated carbon, or lime mud [1,19,25]. Overall, the low concentration of fermentation inhibitors in P-A-PHL suggests that the fermentability of A-PHL should be sufficient for producing ethanol and XA, which will be verified in the subsequent work.
To further understand the structural changes of the carbohydrates and lignin in A-PHL after being treated by PS-DVB resin, 2D-HSQC spectra of A-PHL and P-A-PHL were obtained and are shown in Fig. 1b and Fig. 1c, respectively. A-PHL showed the similar cross-signals for various substructures of lignin and carbohydrate in the 2D-HSQC spectra compared to those in the original PHL spectra (Fig. 1a). However, the signal intensities of β-O-4 substructures in the A-PHL spectra were significantly lower than those in the PHL spectra. This difference might be due to the cleavage of ether bond under the acidic hydrothermal conditions of acid hydrolysis [40]. For the 2D-HSQC spectra of P-A-PHL, the signals observed for carbohydrates remained in similar positions compared to those noted in the A-PHL spectra (Fig. 1c). Importantly, the correlations of lignin substructures and units were absent in the P-A-PHL spectra. This result again indicates the successful removal of lignin from A-PHL, which is attributed to the adsorption ability of PS-DVB resin.
Fermentation of A-PHL and P-A-PHL by Pichia stipites (P. stipitis) to produce ethanol
To understand the improvement in the fermentability of A-PHL after being treated by PS-DVB resin, both A-PHL and P-A-PHL (containing the same xylose concentration of 30 g/L and 50 g/L) were used as the fermentation stocks to produce ethanol by Pichia stipites (P. stipitis) yeast. The concentration of xylose was selected based on the general tolerance ability of P. stipitis for xylose. The fermentation inhibitor concentrations in prepared A-PHL and P-A-PHL containing different xylose concentrations are listed in Table 2. The xylose consumption and ethanol production of A-PHL and P-A-PHL are shown in Fig. 4a and Fig. 4b, respectively. The ethanol yields, which are defined as the percentage of the total amount of ethanol that could be produced from consumed xylose, are shown in Fig. 4c.
Table 2 Composition analysis of prepared A-PHL and P-A-PHL containing different xylose concentrations (g/L) for ethanol and xylosic acid fermentation
|
A-PHL a
|
P-A-PHL a
|
Xylose
|
30.1±0.1
|
40.2±0.3
|
50.3±0.1
|
90.5±0.2
|
150.6±1.1
|
30.3±0.3
|
40.6±0.1
|
50.3±0.9
|
90.9±0.3
|
150±0.1
|
HMF
|
0.6±0.5
|
0.8±0.4
|
0.8±0.1
|
1.8±0.4
|
2.8±0.3
|
0±0.0
|
0±0.0
|
0±0.0
|
0.1±0.0
|
0.1±0.0
|
Furfural
|
2.4±0.2
|
3.2±0.3
|
3.9±0.7
|
6.7±1.2
|
10.8±0.9
|
0.2±0.5
|
0.3±0.1
|
0.3±1.1
|
0.6±0.4
|
1.2±1.3
|
Soluble lignin
|
15.4±1.3
|
20.1±0.9
|
23.5±0.8
|
41.3±0.7
|
59.9±1.2
|
0.8±1.1
|
0.9±0.5
|
1.0±0.2
|
2.3±0.4
|
3.0±1.4
|
a: prepared from corresponding solutions by dilution or concentration
The results in Fig. 4a revealed that A-PHL has low ethanol fermentation productivity with P. stipitis. Specifically, xylose in A-PHL was slowly consumed during the fermentation process. After 36 h of fermentation , 20.2 g/L and 41.6 g/L of xylose remained in A-PHL with initial xylose concentrations of 30 g/L and 50 g/L, indicated that only 32.6% and 16.8% of xylose in A-PHL were consumed, respectively. The ethanol yield (Fig. 4c) obtained from A-PHL containing 50 g/L xylose was only 12.0%, which was lower than that of A-PHL containing 30 g/L xylose (23.5%). The low fermentability of A-PHL for producing the ethanol by P. stipitis was therefore due to its high concentration of inhibitors [41, 42]. A total of 0.57 g/L HMF and 2.36 g/L furfural were present in A-PHL containing 30 g/L xylose and 0.82 g/L HMF and 3.93 g/L furfural were present in A-PHL containing 50 g/L xylose. As pointed out by Díaz et al. (2009) [41], an inhibitory effect on ethanol fermentation by P. stipitis can be observed with furfural concentrations of 1-2 g/L, and almost no sugars can be consumed when there is greater than 4 g/L furfural in the fermentation media.
From Fig. 4b, it can be seen that PS-DVB resin treatment remarkably improved the fermentability of A-PHL for ethanol production. 80% and 47% of the xylose in P-A-PHL containing 30 g/L xylose and 50 g/L xylose was consumed after 36 h of fermentation, resulting in ethanol yields of 61.8% and 45.9%, respectively. Compared to the results for untreated A-PHL containing 30 g/L and 50 g/L xylose, the ethanol yield was improved by 162% and 282%, respectively. The improved fermentability of P-A-PHL therefore must be due to the removal of fermentation inhibitors (HMF, furfural, and soluble lignin). As shown in Table 3, the concentrations of HMF, furfural, and soluble lignin in P-A-PHL containing 30 g/L and 50 g/L xylose were 0 g/L, 0.21-0.30 g/L, and 0.75-1.01 g/L, respectively, which were significantly lower than those in untreated A-PHL. In view of the other technologies that have been used to improve the fermentability of sugar solutions with inhibitors, Lai et al., (2016) [42] reported that the ethanol production could be increased by 45.5% and 42.8% for the prehydrolyzate treated with cetyltrimethylammonium- and benzyltrimethylammonium-modified bentonites, respectively. Zhu et al., (2011) [43] reported that a trialkylamine extraction technology could be used remove 45.7% HMF and 100% furfural from prehydrolyzate, which could improve its fermentability by P. stipitis by a degree of 89.6%. Based on the aforementioned results, it can be concluded that PS-DVB resin treatment is a valid detoxification method to improve A-PHL fermentability for ethanol production.
According to the results in Fig. 4 c, the fermentability of A-PHL and P-A-PHL containing 50 g/L xylose was weaker than that of A-PHL and P-A-PHL containing 30 g/L xylose. Two reasons can explain this phenomenon. First, the concentrations of furfural and soluble lignin in A-PHL containing 50 g/L xylose were 3.9 g/L and 0.3 g/L, and those in P-A-PHL containing 50 g/L xylose were 23.5 g/L and 1.0 g/L, respectively; these values were higher than those in A-PHL and P-A-PHL containing 30 g/L xylose. The higher concentrations of these fermentation inhibitors may show greater inhibition of the bioconversion ability of P. stipitis to produce ethanol [37]. Second, A-PHL and P-A-PHL containing a higher xylose concentration (50 g/L) may inhibit the bioconversion ability of P. stipitis. As pointed out by Agbogbo and Coward-Kelly (2008) [44], ethanol productivity can be inhibited when the initial xylose concentration is 50 g/L, which is called sugar inhibition.
Fermentation of A-PHL and P-A-PHL for producing XA by Gluconobacter oxydans (G. oxydans)
The fermentability of A-PHL treated by PS-DVB resin with different xylose concentrations (40, 90, and 150 g/L) to produce XA by Gluconobacter oxydans (G. oxydans) were investigated . As shown in Fig.5a, the xylose in A-PHL containing 40 g/L xylose could be completely consumed within 48 h, resulting in an XA production of 44.4 g/L and a corresponding yield of 96.6% (Fig.5c). When increasing the A-PHL xylose concentration to 90 g/L, even a better XA production of 58.8 g/L could be achieved at 48 h. However, only 49.7% of the xylose was consumed by G. oxydans to produce XA, with a yield of 60.6%. When further increasing the A-PHL xylose concentration to 150 g/L, only 12.1% of the xylose could be consumed to produce XA, with a yield of 12.1% (4.7 g/L) at 48 h. From these results, it can be seen that the bioconversion of xylose in A-PHL was strongly inhibited by increases in the concentration of xylose from 40-150 g/L, which can be attributed to the corresponding increased concentration of furfural in A-PHL. As can be seen in Table 2, A-PHL containing 40 g/L and 90 g/L xylose contained 3.2 g/L and 6.7 g/L furfural, which were the values within the tolerance of G. oxydans to produce XA. However, there was 10.8 g/L of furfural in A-PHL containing 150 g/L xylose, which is beyond the tolerance threshold for bioconversion. As pointed out by Zhou et al., (2018) [37], the bioconversion ability of G. oxydans can be reduced by 60% when the furfural concentration in fermentation media is increased from ~10 to 15 g/L.
Since high concentration of furfural causes severe inhibition of the bioconversion ability of G. oxydans [45], we also use the PS-DVB resin to treat A-PHL to produce XA by G. oxydans. As seen in Fig.5b, predictably enhanced XA productivity with 71.6% and 26.1% yields was achieved with P-A-PHL containing 90 g/L and 150 g/L xylose, corresponding to improvements of 18% and 828% compared to the yields of A-PHL containing 90 g/L and 150 g/L xylose, respectively. The tremendous improvement obtained with A-PHL was due to its low concentration of furfural, which was achieved by PS-DVB treatment. According to the research of Chai et al.(2013) [46], the inhibition by furfural towards whole-cell catalysis of G. oxydans can be avoided by implementation by furfural removal. Our observations support this previous finding. Overall, it can be concluded that PS-DVB resin treatment is also a potential detoxification method for A-PHL to improve its fermentability for XA production, especially when using PHL with high concentrations of xylose and fermentation inhibitors.
Prospect of the protocol for industry application
In the kraft-based dissolving pulp industry, prehydrolysis is a crucial stage that can result in dissolving the majority of the hemicelluloses and part of the lignin in PHL. Currently, PHL is mostly concentrated with the black liquid from the cooking process and burned in the recovery boiler [4,7]. Hence, using the generated PHL to produce biobased chemicals means that the cost for the feedstock is almost zero. It is estimated that the global production of dissolving pulp was 5.6 million tons in 2013 and 7.5 million tons in 2015; these quantities can produce 50-80 million tons PHL (nonconcentrated) [47, 48]. The large amount of PHL produced will provide adequate feedstock for the industrial-scale production of ethanol and XA by the current protocol. Acid hydrolysis is a mature and commercial technology for the production of platform chemicals, such as furfural and HMF [49]. In this work, this technology has also been proposed to enrich the xylose amount in PHL to prepare a fermentation substrate. Acid hydrolysis was carried out and optimized at a 4% sulfuric acid dosage at 100 °C for 80 min. These low conditions for preparing the fermentation feedstock indicate that this treatment may result in less reactor corrosion and lower costs for investment, operation, and management [50]. After treatment with PS-DVB, the bioconversion efficiency reached 61.8% for ethanol production from feedstock containing 30 g/L xylose and 96.6% for XA production from feedstock containing 40 g/L xylose. Regarding the final products ethanol and XA, both are important industrial products that can be applied in different areas [11, 13, 14]. Importantly, the used resin can be reused by regenerating it with ethanol, which can be obtained from self-production in the current protocol. Regarding reuse, it can be seen that (Table S2) after different 5 cycle times, the resin could still remove HFM, furfural and soluble lignin, with reuse efficiencies of 97.9-99.3%, 91.5-90.2%, and 94.2-95.1%, respectively. In addition, the recovery yield of xylose was still over 94% after 5 cycles. The good reuse efficiency of regenerated resin indicated that it has a long lifetime and satisfactory regeneration ability for processing, suggesting potential applications in industry. The adsorbed substances (HFM, furfural and soluble lignin) in the resin can be recovered after being desorbed by ethanol. Due to differences in molecular weight and boiling point, the HFM, furfural and soluble lignin in desorbed ethanol can be further separated by distillation, membrane separation, or other combined technologies. All of these products are important platform chemicals that can be further used to synthesize resins, plastics, and other value-added products [10, 51].
Hence, the potential value-added products produced from A-PHL in the current protocol, such as ethanol, XA, HFM, furfural and lignin, can ideally provide additional revenue streams for dissolving pulp production mills, enhancing their competitiveness [51]. The technology discussed in this work represents a good starting point for future industrial exploitation of PHL due to the low cost of the feedstock, mature technologies, high bioconversion efficiency, satisfactory regeneration of resin, and multiple value-added products. Further research should be carried out to assess industrial applications of this protocol, such as case studies of specific PHLs from different mills, detailed process design, and economic analysis considering costs and revenues.