Employing newly developed plastic bubble wrap technique for biofuel production from diatoms cultivated in discarded plastic waste
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Science of the Total Environment 823 (2022) 153667 Contents lists available at ScienceDirect Science of the Total Environment journal homepage: www.elsevier.com/locate/scitotenv Employing newly developed plastic bubble wrap technique for biofuel production from diatoms cultivated in discarded plastic waste ⁎ ⁎ Mohd Jahir Khan a, Richard Gordon b,c, Sunita Varjani d, , Vandana Vinayak a, a Diatom Nano Engineering and Metabolism Laboratory (DNM), School of Applied Sciences, Dr. Harisingh Gour Central University, Sagar, Madhya Pradesh 470003, India Gulf Specimen Marine Laboratory & Aquarium, 222 Clark Drive Panacea, FL 32346, USA C.S. Mott Center for Human Growth & Development, Department of Obstetrics & Gynecology, Wayne State University, 275 E. Hancock, Detroit, MI 48201, USA d Gujarat Pollution Control Board, Gandhinagar, Gujarat 382010, India b c H I G H L I G H T S G R A P H I C A L A B S T R A C T • Bubble farming© using different plastic bubble wraps® were used to harvest diatoms. • No post nutrient uptake and water loss for 40 days to culture diatoms was noted. • Diatom cell density was maximum in low density polyethylene (LDPE) bubble wrap. • Maximum Diafuel™ (37%) and lipid (35 μgmL−1) on 40th day in LDPE bubble wrap was recorded. A R T I C L E I N F O Article history: Received 5 January 2022 Received in revised form 28 January 2022 Accepted 31 January 2022 Available online 05 February 2022 Editor: Damià Barceló Keywords: Biofuel Bubble farming© Diatom Lipid Photobioreactor Plastic air wrap A B S T R A C T Algal culturing in photobioreactors for biofuel and other value-added products is a challenge globally specifically due to expensive closed or open photobioreactors associated with the high cost, problems of water loss and contamination. Among the wide varieties of microalgae, diatoms have come out as potential source for crude oil in the form of Diafuel™ (biofuel from diatoms). However, culturing diatoms at large scale hypothesized as diatom solar panels for biofuel production is still facing a need for facile and economical production of value-added products. The aim of this work was to culture diatom (microalgae) in a closed system by sealing the reactor rim tightly with very cheap priced and used plastic bubble wrap material which is generally discarded in a lodging and transportation of goods. To optimize it, different plastic wraps discarded from a plastic industry were tested first for their permeability to gases and impermeability to water loss. It was found that among different varieties of plastic bubble wraps, low density polyethylene (LDPE) bubble wrap material which was used to seal glass containers as photobioreactors allowed harvest of maximum Diafuel™ (37%), lipid (35 μgmL−1), highest cell count (1152 × 102 cells mL−1), maximum CO2 absorbance (0.084) with almost no water loss and nutrient uptake for 40 days of experiments. This was due to its permeability to gases and impermeability to water. To check usability of such LDPE bubble wrap on other microalgae it was therefore tested on the red-green microalgae Haematococcus pluvialis, which showed scope to be scaled up for astaxanthin production using discarded bubble wrap packing material. This study thus would open up a new way for decreasing plastic disposal and with reuse for sustainable development and application of diatom in biofuel production which could find applications in environmental and industrial sectors. ⁎ Corresponding authors. E-mail addresses: drsvs18@gmail.com (S. Varjani), kapilvinayak@gmail.com (V. Vinayak). http://dx.doi.org/10.1016/j.scitotenv.2022.153667 0048-9697/© 2022 Elsevier B.V. All rights reserved. M.J. Khan et al. Science of the Total Environment 823 (2022) 153667 1. Introduction environmental pollution (Varjani et al., 2021). This is essentially not only good for the cultivation of diatoms but every microalga of potential industrial value cultivated at mass scale for e.g., Haematococcus pluvialis, which is rich in astaxanthin, a high value product of high demand in the international market. The high cost is probably due to the fact that exorbitant cost of harvesting/extracting increases the cost of value-added products like astaxanthin. High cost further is due to the thick cell wall of many such microalgae which needs pretreatment before extracting value added products from them (Ahirwar et al., 2021a; Zheng et al., 2022). In the present study three different qualities of diverse bubble wraps with different densities of polyethylene were collected and tested for their CO2 and water permeability. Plastic bubble wraps with the most desirable permeability to gases and impermeability to water were selected and diatoms were cultivated in conical flasks simulated as photobioreactors (PBR). The rims of the conical flasks were sealed with such plastic bubble wrap using a visible colored and robust microalga like H. pluvialis. With the increase in industrialization and consumer goods, plastic had been an immense part of industrial and commercial sector (Rajmohan et al., 2019; Gaur et al., 2022; Varjani et al., 2021). Plastic has somehow entered into every nook and corner of our daily lifestyle (Rajmohan et al., 2020). Disposing the plastic has been a major cause of environmental pollution leading to its indirect effect on our ecological niche (Khan et al., 2020; Varjani et al., 2020; Varjani and Upasani, 2021; Tran et al., 2022). In this manuscript we have considered the reuse of air bubble wraps for algal culturing not only preventing its dumping into our environment but economically lowering their culturing cost. For a long time, large scale algae culture has taken place in closed photobioreactors (Bani et al., 2021), open raceway ponds (Mohan et al., 2021), horizontal plates (Cuaresma et al., 2011), tubular equipment (Bani et al., 2021), “Christmas trees” (Legrand et al., 2021), foil, porous substrate bioreactors (Carbone et al., 2020) and bubble column photobioreactors (PBR) (Bose et al., 2021). The exorbitant cost of biofuel from algae like diatoms (about $3.36/l) (Vinayak et al., 2018) make these methods unsuccessful at a commercial scale, since the market cost is higher (Gordon et al., 2019a; Jayakumar et al., 2021; Richardson et al., 2012; Singh et al., 2016). This essentially has attracted researchers to look for alternative sources for crude oil (Ho et al., 2014; Leite et al., 2013). It is projected that by 2030 the global energy demand will increase 57% (Kowthaman et al., 2022). To meet this demand for energy, diatoms are good choice as an alternative energy source as they alone contribute 30% of total crude oil besides synthesizing value added products like fucoxanthin, fatty acids like eicosanoic acid, and docosapentaenoic acid (Mourya et al., 2021). These fatty acids vary from C14:0 to C22:6, and are used extensively in food, personal and health care markets (Paliwal et al., 2017; Seth et al., 2021). Fucoxanthin is one of the most common high value metabolites from diatoms; it along with chlorophyll-a/c, proteins and other metabolites has therapeutic properties viz; anticancer, antioxidant, antiangiogenic, antidiabetic etc. (Seth et al., 2021; Leong et al., 2022). Like other microalgae, diatom culture in photobioreactors is not easy nor economic since harvesting of high yield biomass and high value added products kills the cells (Vinayak et al., 2015). This is mainly due to thick silica wall of diatoms which makes harvesting/extraction tedious and exorbitant. Also, making such photobioreactors requires continuous media supplements to maintain the nutrients and water loss. Furthermore, diatoms cultured in open systems have high chances of contamination with spores, bacteria, fungi and other microalgae (Xiang et al., 2017). To conquer these stumbling blocks the possibility of using plastic wraps used in packaging goods in the form of Bubble Farming© (Gordon et al., 2019a) stemmed out of earlier research on diatom solar panels for biofuel production to harvest biofuel than to extract (Gautam et al., 2016; Ghobara et al., 2019; Gupta et al., 2018; Kumar et al., 2016; Kumar et al., 2018; Vinayak et al., 2014; Mishra et al., 2020). Using bubble wrap in microalgae culture is advantageous compared to conventional farming as bubble farming photobioreactors besides recycling the plastic bubble wrap waste maintains a closed system enabling air exchange with minimum chances of contamination. Hence, bubble farming photobioreactors are economical and prevent water loss and constant feeding of the nutrient media (Gordon et al., 2019b). Furthermore, bubble farming lowers the cost of culture and additionally, if microalgae of interest like diatoms or any other microalgae are cultured in wastewaters they not only remediate wastewater pollutants, but it becomes environment friendly and cheap way for mass cultivation of microalgae (Khan et al., 2021d, Khan et al., 2021d). To achieve this, researchers have been continuously doing effort to design different techniques like microbial fuel cell, high rate algal ponds, pyrolysis, etc. using diatoms and other microalgae to harvest value-added metabolites from them (Mishra et al., 2019; Khan et al., 2021b; Khan et al., 2021c; Khan et al., 2021e; Lee et al., 2020; Shah et al., 2021; Vinayak et al., 2021b; Vyas et al., 2022). Plastic bubble wrap, on the other hand, used in culturing of microalga, can be obtained from goods transport or the plastic industry. Hence it is economical as well as reduces 2. Materials and methods 2.1. Experimental In the first step, pond water from local pond in Canada (50.8012° N, 98.9776° W) was filled in wide-mouth glass jars and its mouth was sealed with AIRplus® air pillow bubble wrap material (Storopack Industry, Canada; www.storopack.com) using elastic bands. The temperature of water in the jars was checked to be at 5 °C in the pond. Jars were set below a west windowsill under a McKenzie Hydrofarm Inc. 24 W Agrobrite Highoutput 553 cm fluorescent light bulb, on a 12 h on/off cycle starting 6 am (November/December 2020). Ambient temperature of the room was ~21 °C with a relative humidity of ~43%. 2.2. Testing different plastic bubble wraps for CO2 permeability and physical parameters To evaluate CO2 permeability, three different types of plastic bubble wraps viz low density polyethylene (LDPE) (Barentsen and Heikens, 1973), high density polyethylene (HDPE) (Khonakdar et al., 2003) and normal polyethylene (NP) (Ingraham et al., 1947) were used. These plastic bubble wraps having size 20 cm × 20 cm, thickness 20 μm, collected from disposed plastic packaging material from packaged goods were collected and were used to seal the rim of test tubes in which CO2 permeability was checked. About 1 mL of calcium hydroxide solution (30 mM) was added in each culture in test tubes containing about 100 mL of distilled MilliQ water (Holm and Brien, 1971). Nylon based bubble wrap was avoided, as these bubble wraps are impervious to atmospheric gases (Levy, 1998). Each of the above sets was also observed for its quantity of water retention, UV–Vis absorbance, humidity, pH, conductivity and Total Dissolved Solids (TDS) after every 5th day for a period of 20 days at an ambient temperature of 22–25 °C. 2.3. Testing diatom growth in most permeable plastic bubble wrap in a glass flask photobioreactor As hypothesized, microalgae would grow in plastic Bubble Farming© technique without requirement of any additional nutrient feeding (Gordon et al., 2019a). In this hypothesis we first examined different plastic bubble wraps showing adequate exchange of gases, especially CO2 and O2. Thereafter, diatoms added in the flask simulated PBR sealed with the plastic bubble wraps and were tested for which was most efficient with regard to permeability to gases and water retention. All experiments had been planned to be conducted in triplicates with the flasks kept stationary. The mouth of each conical flask (250 mL) was sealed with different polyethylene bubble wraps using elastic rubber bands, acting as laboratory PBR. These flasks/PBR were inoculated with a fixed inoculum of the diatom Nitzschia palea (4.79 × 104 cells mL−1 added to 100 mL of modified f/2 medium) (Vinayak et al., 2021a). A fixed number of cells was added into 2 M.J. Khan et al. Science of the Total Environment 823 (2022) 153667 et al., 2021b). The type of bubble wrap which would be most efficient regarding its permeability and water retention properties would be selected to grow these green-red microalgae. The selected plastic bubble wrap of size 6″ × 6″ with each bubble having diameter of 0.25″ was chosen. Each plastic bubble wrap was filled with microalgae via U-100 injection and sealed thereafter with clear cuticle hardener (Bwambok et al., 2014). The maximum amount of H. pluvialis culture was injected per bubble was 160 μL, having about 20 cells/μL. The cell density was analyzed via histograms of images against a white background. Each image was split into red green and blue (RGB) (Vrablik et al., 2018) individually using Image J software since direct counting would lead to loss and leakage of culture (Ferreira and Rasband, 2021). This would be thereafter studied for a period of 21 days. 100 mL of modified f/2 medium in the test samples (flasks simulated photobioreactor which were sealed with different plastic bubble wrap material viz NP, LDPE and HDPE) and control (one which was open acted as an open algal photobioreactor). The diatom cells in these flasks were sealed with different plastic bubble wraps and were grown at 22 °C temperature in standard light/dark duration of 8 h/16 h (Vinayak et al., 2014). 2.4. Trans-esterification of lipid into fatty acid methyl ester Lipid was harvested from the control and three different test samples (5 mL) in triplicates and transesterified as per the Bligh and Dyer method (Bligh and Dyer, 1959). Both the test and control samples were centrifuged and pellets were dried. The biomass was weighed and mixed in chloroform: methanol: water in a 1:2:0.9 ratio, vortexed and sonicated for 5 min. This was followed by the addition of chloroform and deionized water to make a total ratio of chloroform: methanol: water as 2:2:1.8. After that 1 mL of 0.5% NaCl solution was added and the samples were mixed vigorously, centrifuged at 5000 g for 10 min and then kept at room temperature for 1 h to separate organic and aqueous layers. The organic layer was transferred carefully into a fresh tube. Solvent was removed from the extract using a speed-vacuum system and the fatty acid obtained was weighed at a precision of 0.0001 g. 3. Results and discussion Herein the use of disposed or discarded plastic bubble wrap has shown significant results. It was seen that the glass jars having pond water algae with open rim which served as control and test jar rim sealed with AIRplus® pillow plastics served as test showed some consequential analysis of algal growth and no water loss. On day 1, volume of pond water in both the glass jars was same. It was observed that even up to 50th day, the microalgae remained green in both closed and as well as open glass jar. However, it was seen that there was no water loss in the jar sealed with plastic bubble wrap while about 50% water loss was seen in an open jar (Fig. S1). On the offset, there was full water retention in the sealed jar, with almost equal algal growth in both control and test samples analyzed via histograms of RGB images studied using Image J software which showed no change in the peak's positions (Fig. S1). This demonstratedd that the sealing of glass jar rim with plastic bubble wrap didn't starve the algae for exchange of gases (CO2 and O2) which is required for photosynthesis and respiration and simultaneously maintained the water level in growth media. This is significant since water loss and contamination are the major drawbacks of microalgae cultivation in open raceways (Branyikova and Lucakova, 2021; de Carvalho Silvello et al., 2021). Furthermore, bubble wraps can be used in making cost effective photobioreactor for algal farming and obtained value added products from these microalgae could be commercialized. Plastic bubble wrap which is generally used to pack the goods is thrown away once the goods items are unpacked, projected at US10.7 billion in 2023 (https://www. statista.com/statistics/1013196/global-market-value-of-bubble-wrap/, covering over 2 million hectares, per Gordon et al., 2019b). These disposed bubbles wraps from lodging goods or from plastic industry caused environmental pollution. These bubble wraps can be thus utilized for economical algal farming. Therefore, sealing of an open raceway by large sheets of bubble wrap plastic or customizing its production in large size bubble wrap for mass scale diatom cultivation could probably avoid most these stumbling blocks. The quest was thus to quantitatively check the CO2, O2 availability and water retention of different bubble wrap plastic materials viz NP, LDPE, HDPE and compare them with the control. This was done by recording physical parameters such as humidity, pH, conductivity and TDS. It was found that the pH in all the test samples sealed with NP, LDPE, HDPE bubble wraps was alkaline (pH 12) on 20th day. The pH change in control and test samples is associated with growth of microalgae as well exchange of gases through the different bubble wraps (Siddiki et al., 2022). The pH of control was recorded slightly lower than test samples (pH 11.3 ± 0.25) on the 20th day (Fig 1A). However, there were only minor changes in the conductivity and TDS value in all bubble wrapped test samples. Conductivity of the control sample on the other hand decreased from 5.64 ± 0.02 μS on day 1 to 2.42 ± 0.32 μS on 20th day, whereas conductivity of test samples increased from ~5.64 ± 0.10 μS on the 1st day to 5.74 ± 0.25 μS for NP, 6.95 ± 0.24 μS for LDPE and 7.23 ± 0.27 μS for HDPE on 20th day (Fig 1B). These results were in concordance with the previous reported data (Grishagin, 2015; Mostafa et al., 2012). Control samples without any bubble wrap showed maximum TDS value (3.88 ppt) on 1st day and decreased (1.61 ppt) thereafter till 20th day (Fig 1C). This was possibly 2.5. Lipid estimation by sulpho-phospho vanillin (SPV) method The amount of lipid in diatom samples was estimated from the FAME by the colorimetric sulfo-phospho-vanillin (SPV) method (Khan et al., 2019). Linseed oil (Supelco, PA, USA; 1000 mg) was used as a standard. In each sample, 100 μL of concentrated sulfuric acid was added and incubated at 90 °C for 10 min followed by cooling at 4 °C for 5 min. After cooling, 2.4 mL of phosphovanillin (PV) reagent was added (prepared by addition of 120 mg vanillin (Sigma-Aldrich, USA) into 100 mL of hot 85% phosphoric acid). The mixture was then kept for 30 min at room temperature so as to develop pink color. The absorbance was thereafter recorded at 530 nm using a UV–Vis spectrophotometer (LabIndia, UV-3000). The amounts of oil in diatom samples were determined with the help of a standard plot prepared using different concentrations of linseed oil. At the start, the neutral lipids in live diatoms were stained using Nile red stain and imaged via confocal microscopy to confirm their presence. 2.6. Estimation of chlorophyll content Microalgal culture having diatoms (5 mL) were taken on 1st, 10th, 20th, 30th and 40th day and the absorbances were recorded at 680 nm using a UV–Vis spectrophotometer (Lab India UV-3000, India) (Khan et al., 2020). This analyzes the physiological state as well as growth of diatom cells. The amount of chlorophyll in control and experimental samples were determined using the UV–Vis spectrophotometer for different time intervals as per Eq. (1) (Angioni et al., 2018): ð20:2 A645 Þ þ ð8:02 A663 Þ Chlorophyll μg mL−1 ¼ 2 (1) Control and test diatom culture (5 mL) of 1st, 10th, 20th, 30th and 40th day were taken and centrifuged at 3000 ×g for 10 min. Supernatant was discarded and 2 mL absolute ethanol was added in the pellet and vortexed followed by boiling in a water bath for 5 min. Cell debris was removed by centrifugation and the absorbance of clear ethanol layer having pigments was recorded at 645 nm and 663 nm using the UV–vis spectrophotometer (Angioni et al., 2018). 2.7. Employing bubble wrap as plastic waste for growing H. pluvialis In order to test if bubble wrap could actually be used for in-vitro culturing of microalgae, rapidly growing microalgae H. pluvialis (a green-red microalgae) in its red encyst stage was taken for cross checking (Ahirwar 3 M.J. Khan et al. Science of the Total Environment 823 (2022) 153667 Fig. 1. CO2 absorption and desorption in different experimental conditions at temperature 25 ± 0.237 °C for 20 days. because of high availability of CO2 and other gases due to no hindrance and mingling of CO2 gases. This was a unlike behavior seen in NP, LDPE and HDPE test samples where water was turbid on last 20th day as there were gradual increase in TDS due to less permeability of gases (Fig 1C). However, TDS was near 0.07 ± 0.04 ppt on 1st day for NP, LDPE and HDPE whereas on 20th day it increased and reached near ~2.5 ± 0.25 ppt in NP and LDPE while it was least for HDPE bubble wrap as it was 2.12 ± 0.24 ppt on the 20th day. The changes in conductivity and TDS with the carbon dioxide absorption and desorption were concordant in pattern as explained by Al-Hindi and Azizi in a bubble column reactor tank (Al-Hindi and Azizi, 2020). However, there were minor changes in pH which is concordant with the earlier reported studies in which pH changed with CO2 absorption (Al-Hindi and Azizi, 2020). Increase in CO2 absorption results in rise in salinities with the effect of different water types studied for CO2 absorption and desorption studies in bubble column reactors (Al-Hindi and Azizi, 2020) (Navaza et al., 2009). Lastly, relative humidity of the culture room where the experiment was conducted was stable for all days reaching between 15 and 17% which is a significant factor for the maintaining concentration of gases present in the atmosphere throughout the experiment. The UV–Vis spectroscopic observations of control and test for CO2 absorption and desorption showed that the control changed its turbidity after addition of calcium hydroxide solution into it. Figure 2 illustrates that on 5th day, control showed maximum absorbance of 1.77 Au at 208 nm whereas NP, LDPE, and HDPE showed maximum absorbance's of 1.75 Au, 1.73 Au and 1.72 Au at 212 Au, respectively. As the time of exposure increased, absorbance of CO2 increased from 10th to 20th day. The highest absorbance (1.91) was reported in control sample on 20th day whereas there were significant changes in the absorbance in NP, LDPE and HDPE observed as 1.72 Au, 1.68 Au and 1.67 Au, respectively. The high absorbance in control was due to the fact that maximum CO2 was absorbed thus forming CaCO3 precipitate (Gettens et al., 1974). This is clearly elaborated in Fig. 2D due to maximum area under curve occupied by control compared to test samples. It was further seen that the increase in CO2 absorption results not only decrease in TDS but also decrease in absorption coefficient as is seen from the UV–Vis spectral studies for control sample which is concordant with earlier reported studies (Al-Hindi and Azizi, 2020). Even though LDPE bubble wrap test samples showed comparatively better absorption of CO2, all the bubble wraps test samples were further tested for growth of diatoms, water loss, chlorophyll content, cell density, lipids and biofuel from diatoms. It was further seen that cell growth in the LDPE test sample was linearly proportional to the CO2 gases absorbed in LDPE samples as seen in Fig. 2. Henceforth, fixed number of diatom cells contained in 250 mL conical flasks acting as PBR was sealed with NP, LDPE and HDPE bubble wraps along with control in triplicates. These experimental sets were run for 40 days and showed varied diatom cell counts as shown in Fig 3A. It was observed that the control showed a fall in diatom growth on the 40th day (197 × 102 cells mL−1). On the 40th day, the growth of diatoms was lower than on the 30th day in the case of NP (429 × 102 cells mL−1) and HDPE (856 × 102 cells mL−1) bubble wrap. However, only LDPE showed a stable quasi-exponential behavior in growth of diatom cells (1152 × 102 cells mL−1) until 30th to 40th day as compared to NP and HDPE. The growth condition was further verified by recording the absorbance at 680 nm using UV–Vis spectrophotometer (Fig 3B). On 10th day, LDPE sample displayed a higher absorbance (0.4) with cell count of 499 × 102 cells mL−1 as compared to other bubble wrap because of active photosynthesis. Active photosynthesis in LDPE bubble wrap is associated with efficient absorption of CO2 gases exchanged via its permeable plastic membrane. However, at 40th day, lowest absorbance (0.052 Au) was found in the NP samples with minimum cell count of 429 × 102 cells mL−1. Similarly, cell count was low in HDPE (0.018 Au) with 856 × 102 cells mL−1on 40th day as seen in Fig 3B. On the other hand, LDPE on the 40th day displayed maximum absorbance (0.084 Au) with highest cell count of about 1152 × 102 cells mL−1. The results were in concordance with the theory that cell growth is directly proportional to the absorbance of light getting absorbed due to scattered particles in the cuvette (Ritchie and Sma-Air, 2020). 4 M.J. Khan et al. Science of the Total Environment 823 (2022) 153667 Fig. 2. Absorbance of water mixed with calcium hydroxide in test tubes marked as Control, NP, LDPE and HDPE bubble wrap/s on 5th; 10th; 15th and 20th day of exposure to atmospheric CO2. Furthermore, it was found that the amount of lipid on 10th day was 26.17 μgmL−1, 22.40 μgmL−1, 25.09 μgmL−1 and 25.97 μgmL−1 for control, NP, LDPE and HDPE, respectively (Fig 4A). Lipid content further increased substantially in LDPE 31.21 μgmL −1 on 20th day, 33.88 μgmL−1 on 30th day and 34.89 μgmL−1 on 40th day. The control sample showed decrease in lipid content about 2.33 μgmL−1 on 40th day which is possibly due to decrease in cell count and contaminations in open culture flask. The fall in lipid was also observed in NP (10.24 μgmL −1 ) and HDPE (15.83 μgmL −1 ) on 40th day. However, lipid yield continued to rise in LDPE. Comparing these results, it was analyzed that even though on 10th day LDPE showed lowest lipid content (22.40 μgmL−1), it increased gradually which was well in accordance with cell growth analyzed spectrophotometrically and via and cell count. This was probably due to scarcity in CO2 and decline in photosynthesis during initial days after inoculation. Hence, CO2 plays an important role in photosynthesis to make carbohydrates required for its fixation by ribulose-1,5-bisphosphate carboxylase/oxygenase (RUBISCO) enzyme in C4 pathway photosystem (Pandey et al., 2021; Riebesell, 2000). Its deficiency may ultimately result in failure to synthesize carbohydrates required for further energy generating pathways. Furthermore, when these lipids were transesterified they showed the formation of Diafuel™ (biofuel from diatoms) i.e. fatty acid methyl esters (FAME) (Fig 4B). However, maximum Diafuel™ percentage was 37.27% per dry weight (DW) for the LDPE sample, less in HDPE about 28.1% per DW and minimum for NP 2.35% per DW and least in control sample (1.6%) per DW on 40th day. Diatoms were further stained with Nile red dye for the detection of neutral lipids on day 1 and 40th day in LDPE. Neutral lipid in diatom samples was visualized by confocal microscopy (Fig 4). The optical images clearly showed that lipid in diatoms increased on 30th day in LDPE It was seen that the chlorophyll concentration on the 10th day was highest for control (0.835 μg mL −1 ) as compared to NP (0.456 μg mL−1), LDPE (0.752 μg mL−1) and HDPE (0.555 μg mL−1) test samples inoculated with fixed number of diatom cells (Fig. 3C). The chlorophyll concentration of the control increased until the20th day and decreased thereafter. However, on 20th day, chlorophyll concentration of control decreased to 0.735 μg mL−1. Decrease in chlorophyll concentration in the control sample after 20th day is because of water loss and microbial contaminations concordant with open raceway culturing results (Borowitzka and Moheimani, 2013; Shekh et al., 2021). On the offset, the chlorophyll concentration in LDPE and HDPE on 40th day reached to 3.34 μg mL−1 and 2.5 μg mL−1, respectively. The amount of chlorophyll is also directly proportional to cell growth and the results obtained were in accordance with the cell count in each set (Lim et al., 2021). This was also in concordance with earlier research demonstrating a direct correlation between the chlorophyll content and cell count (Groß et al., 2021; Myers and Kratz, 1955). The chlorophyll content constitutes the major carotenoids which are a group of high value metabolites being synthesized in a diatoms (Seth et al., 2021). The water content was measured for each sample on 1st, 10th, 20th, 30th and 40th day and it was found that there was no remarkable water loss in bubble wraps closed test samples except control which displayed significant water loss (~37%) (Fig. 3D) and microalgal contamination as evident from the microscopy. This is the reason closed system PBRs are superior to open raceway ponds but due to their high operational cost they have limited use (Gordon et al., 2019a); therefore, a variety of techniques have been inspired for their economical harvesting (Khan et al., 2021c; Vinayak et al., 2021b) while simultaneously cleaning the environmental plastic pollution (Dang et al., 2022; Khan et al., 2020). 5 M.J. Khan et al. Science of the Total Environment 823 (2022) 153667 Fig. 3. Diatom samples in different bubble wrap plastics sets at different time periods showing their A: Cell count mL−1; B: Absorbance of diatom cells at 680 nm, C: Extracted Chlorophyll content and D: Water retention. sealed flask PBRs without requiring any extra post-inoculation nutrient feed. Nile red staining has been used in analyzing neutral lipids in diatoms and is one of the most reliable method for in situ testing for amount of neutral lipids in cells (Jayakumar et al., 2021; Wu et al., 2014). The confocal microscopy of the amount of neutral lipids stained in diatoms on day 1 and 40th day as seen in Fig 4C and D clearly showed increase in amount of neutral lipids in diatoms cultured in LDPE flask PBR in accordance with earlier published results with neutral red dye (Khan et al., 2021a). It indicates that LDPE is most efficient plastic bubble wrap material to seal PBR while simultaneously maintaining a closed microcosm, thus avoiding contamination and water loss. Its scale up in bubble farming would definitely bring down the cost of harvesting value added products, which is probably due to the high capital cost and investment in running the PBR whether it's closed or open type. Table 1 shows a comparison of closed, open and LDPE bubble farming PBR for various parameters which are involved while cultivating different types of algae. Not limiting to our study on diatoms it was necessary to check this novel practice on in situ bubble wrap as such, henceforth an already optimized LDPE bubble wrap material measuring 6″ × 6″ with each bubble having diameter of 0.25″ was chosen for inoculation of a visibly distinguishable red-green microalgae, H. pluvialis for 21 days inoculated during its condition of stress from the mother liquor. H. pluvialis is rich in astaxanthin which gives it its red color and is highly distinguishable in bubble wrap (Ahirwar et al., 2021b). However, using plastic bubble wrap having a bubble diameter of 0.25″ made cell counting cumbersome due to frequent puncturing of the bubble wrap. Hence, cell density was measured by histogram of each photographed image spilt into red, green and blue and processed via Image J software (Grishagin, 2015). Fig 5 shows the blue channel of the image shifted from in its mean value of 143 ± 7.77 at day 1 towards 155 ± 11.17 at 21st day. This method gave concordant analysis as given for yeast biomass concentration where cell counting was not possible (Acevedo et al., 2009). This gives a scope for light weighted economical algal foods and cultivations in space missions too (Vinayak, 2022). However, this was just a small-scale check and the same could be done using bigger air pillows of LDPE plastic wrap material wherein the main aim was to keep the system closed, have enough permeability for CO2 and other gases while simultaneously preventing water loss, avoiding contamination and frequent inputs of nutrient media. This gives us reason to start a pilot scale project with Air pillow mass cultivation of any microalgae of interest and analyzing all the desired parameters for industrial scale economic start up. 4. Conclusions The results demonstrated that the desirable gaseous exchange takes place through discarded low density polyethylene (LDPE) plastic bubble wrap to support diatom growth without loss of water and any extra nutrient uptake. The LDPE had highest diatom cell count on 40th day (1152 × 102 cells mL−1). The chlorophyll content was maximum for LDPE compared to that in the control; NP and HDPE. NP and HDPE also exhibited no significant water loss. The lipid and Diafuel™ had the highest values in LDPE at the 40th day, 34.89 μg mL −1 , and 37.27% per 1152 × 102 cells mL −1 , respectively whereas a fall in lipid content in the control and rest of the test samples was noted. This not only demonstrates a facile way of making a diatom solar panel for Diafuel™ production but also an economical way to bridge the gap between the cost of operating expensive photobioreactors which in turn increase the cost of high value metabolites obtained from them. On the offset, algal Bubble Farming© would be envisaged on fields under natural, uncontrolled weather conditions by utilizing discarded plastic bubble wraps from plastic industry or lodging goods and materials. The weight of the water might protect the bubble wrap 6 M.J. Khan et al. Science of the Total Environment 823 (2022) 153667 Fig. 4. Diatoms cultured in different bubble wrap plastics at different time periods producing A: Lipids; B: Diafuel™ percentage and confocal microscopy of Nile red stained diatoms in LDPE bubble wrap showing lipid accumulation at C: day 1 and D: 40th day. Declaration of competing interest from wind, and their shape may clean their top surface during rain. Field test are in order. This research work serves an economical method for harvesting algae by recycling plastic waste for their biomass and value-added products. Supplementary data to this article can be found online at https://doi. org/10.1016/j.scitotenv.2022.153667. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. Acknowledgments CRediT authorship contribution statement VV is thankful to DST-Nanomission (Govt. of India) project number (SR/NM/NT-1090/2014(G) and PPMB 7133 CEFIPRA Indo French project for financial support. MJK thanks DST-Nanomission for Postdoc Fellowship. Authors are also thankful to DST-Nanomission Lab Assistant, Deepesh Sinha and SIC, Dr. Harisingh Gour Central University, Sagar, India for providing necessary research facilities. MJK: Literature review, Writing - original draft, Data curation; RG: Conceptualization, Design of experiment; SV: Writing - original draft, Review & editing Resources; VV: Conceptualization, Supervision; Writing - original draft, Review & editing, Funding acquisition. Table 1 Parameters and their role in different photobioreactors vs bubble farming. S. no. Parameter Closed system photobioreactors Open system photobioreactors Bubble farming (LDPE) (this study) 1 2 3 4 5 6 7 8 9 10 11 12 Capital cost Rate of Contaminations Gases exchange rate Scale up to higher reactors Land area required Feeding Algae type Operation and handling Water loss due to evaporation Cultivation period Productivities Power/energy to run the reactor High Low Fair/high Easy Small Required regularly Any Excellent Low/prevented Long High Required Low High Poor Possible Large Required regularly Limited Excellent High short Low Not required Zero Zero Fair/high Easy Small Not required regularly Any Excellent Zero Long High Not required 7 M.J. Khan et al. Science of the Total Environment 823 (2022) 153667 Fig. 5. Histogram segregation of red, green, blue (R, G, B) images of Haematococcus pluvialis inoculated in LDPE bubble plastic wrap of size 6″ × 6″ into A1 (R), A2 (G), A3 (B) on day 1 and B1 (R), B2 (G) and B3 (B) on 21st day by ImageJ software. 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