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    BioCrystals Journal
    Home»Latest Post»pure partially depolymerized
    Latest Post

    pure partially depolymerized

    Sherif S. Z. HindiBy Sherif S. Z. Hindi13 October 2025Updated:13 October 2025No Comments4 Views
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    Microcrystalline cellulose: Its processing and pharmaceutical specifications

    Sherif S. Z. Hindi 1,*; Abdulmohsin R. Al-Shareef 2

    1 Department of Agriculture, Faculty of Environmental Sciences, King Abdullaziz University (KAU), P.O. Box 80208, Jeddah 21589.; 2 Deanship of Scientific Research, KAU, Jeddah, 21551, Saudi Arabia

     

     

    Abstract: Microcrystalline cellulose (MCC) is pure partially depolymerized cellulose synthesized from α-cellulose precursor. The MCC can be synthesized by different processes such as reactive extrusion, enzyme mediated, steam explosion and acid hydrolysis. The later process can be done using mineral acids such as H2SO4, HCl and HBr as well as ionic liquids. The role of these reagents is to destroy the amorphous regions remaining the crystalline domains. The degree of polymerization is typically less than 400. The MCC particles with size lower than 5µm must not be more than 10%. The MCC is a valuable additive in pharmaceutical, food, cosmetic and other industries. Different properties of MCC are measured to qualify its suitability to such utilization, namely particle size, density, compressibility index, angle of repose, powder porosity, hydration swelling capacity, moisture sorption capacity, moisture content, crystallinity index, crystallite size and mechanical properties such as hardness and tensile strength. Thermogravimetric analysis (TGA) and differential thermal analysis (DTA) or differential scanning calorimetry (DSC) are also important to predict the thermal behavior of the MCC upon heat stresses.

    Keywords: Microcrystalline cellulose (MCC); XRD, FTIR; XRD;TGA; DTA; MSDS.

    * Corresponding Author: shindi@kau.edu.sa

    Introduction

    Raw Precursor

    MCC can be obtained commercially from wood (El-Sakhawy and Hassan, 2007) as well as non-woody lignocellulosic materials such as cotton linters (Chauhan et al., 2009),

     

    cotton stalks (El-Sakhawy and Hassan, 2007), cotton rags (Chauhan et al., 2009), soyabean husk (Uesu et al., 2000), corn cob (Suvachittanont and Ratanapan, 2013), water hyacinth (Gaonkar and Kulkarni, 1987), coconut shells (Gaonkar and Kulkarni, 1989), rice husk (Ilindra and Dhake, 2008; El-Sakhawy and Hassan, 2007), sugar cane bagasse (Paralikar and Bhatawdekar, 1988; Padmadisastra and Gonda, 1989; Shah et al., 1993; Tang et al., 1996; El-Sakhawy and Hassan, 2007; Ilindra and Dhake, 2008), jute (Abdullah, 1991), ramie (Kuga and Brown, 1987), fibers and straw of flax (Bochek et al., 2003), wheat straw (Monschein et al., 2013), sorghum stalks (Ohwoavworhua and Adelakun, 2010), sisal fibers (Bhimte and Tayade, 2007) and coconut shells (Gaonkar and Kulkarni, 1989).

    Industrial Applications

    The MCC is a valuable additive in pharmaceutical as a binder for tablets by direct compression and in vitamin supplements, in food as an anticaking, thickener, texturizer, emulsifier and bulking agent as well as a fat substitute and in cosmetic as a filler (Chauhan et al., 2009, Ohwoavworhua and Adelakun, 2010). It is one of the most important tableting excipients due to its superior dry binding properties producing high quality of tablets by direct compression (Thoorens et al., 2014). It is also used in plaque assays for counting viruses, as an alternative to carboxymethyl cellulose (Matrosovich et al., 2006). Another applications of the MCC such as paints, paper and nonwoven textiles, oils field services, medicine and composites because of its properties such as high strength, flexibility and aspect ratio (Tubark et al., 1983; Herrick et al., 1983)

    Synthesis

    The MCC can be synthesized by different processes such as reactive extrusion process, enzyme mediated process (Monschein et al., 2013), the steam explosion process and acid hydrolysis process (El-Sakhawy and Hassan, 2007; Chauhan et al., 2009). The acid hydrolysis process (Table 1) is preferred due to its shorter reaction duration comparing to the other processes. Furthermore, it can be applied by a continuous process

     

    rather than a batch-type process and it consumes limited quantity of acid and produces fine particles of the MCC (Chauhan et al., 2009).

    The synthesis procedure of the MCC reported by (Ohwoavworhua et al., 2004) and applied with slight modification by Ohwoavworhua et al., 2010 can be concluded as follow: A 50 g quantity of the α-cellulose was hydrolyzed with 0.8 l of 2.5 N hydrochloric acid at a boiling temperature of 105° for 15 min. The fraction passing through 710 µm sieve was obtained and stored at room temperature in a desiccator.

    Table 1. Hydrolysis reagents (acid type and concentration), liquor to cellulose ratio (L/C)

    , hydrolysis conditions (HC) and yield of microcrystalline cellulose (MCC-Y)

     

     

    Reference

    Acid L/C

    Vol./wt

    HC  

    MCC-Y

    %

     

    Type

     

    Conc.

     

    Temperature, ⁰C

     

    Duration, minute

    Bhimte and Tayade, 2007 HCl 2N 10:1 105 15 n.f1.
     

    El-Sakhawy and Hassan, 2007

     

    HCl

     

    2N

     

    10:1

     

    45

     

    15

     

    n.f.

    Chauhan et al., 2009 HCl 2.5N 20:1 85 90 80
     

    Ohwoavworhua and Adelakun, 2010

     

    HCl

     

    2.5N

     

    62.5:1

     

    105

     

    15

     

    19

     

    Suvachittanont and Ratanapan, 2013

     

    HCl

     

    2N

    10:1

    20:1

    n.f.           45-60  

    n.f.

    1Not defined

    Characterization

    There are many different techniques are available to characterize the MCC such as infrared spectroscopy (FTIR), X-ray diffraction (XRD), thermogravimetric analysis (TGA), differential thermal analysis (DTA), differential scanning calorimetry (DSC), nuclear magnetic resonance (NMR), atomic force spectroscopy (AFM), scanning electron microscopy (SEM), transmission electron microscopy (TEM), hi-resolution transmission electron microscopy (Hi-TEM).

     

    Physicochemical properties of MCC

    The organoleptic characteristic, identification tests, solubility and presence of organic impurities such as starch, dextrin and water-soluble substances can be done according to credit procedures such as the British Pharmacopoeia (BP) specifications (Ejikeme, 2008). The pH determination of the supernant obtained by shaking 2 g of the MCC powder with 100 ml of deionized water for 5 minutes (Ohwoavworhua et al., 2004). Total ash content in the MCC can be determined by weighing the residue remained after combustion at 550° until all the carbon is eliminated (Ohwoavworhua et al., 2004).

    Different properties of MCC synthesized from many cellulosic precursors were evaluated by several investigators. The MCC of sugar cane and Avicel powders were evaluated for particle size analysis (Ansel et al., 2005) , density and compressibility index (Ohwoavworhua et al., 2004 and 2005 and Bhimte and Tayade, 2007) , angle of repose (Train, 1958) , powder porosity (Ohwoavworhua et al., 2004) , hydration ( (Kornblum and Stoopak, 1973) and swelling capacity (Ohwoavworhua et al., 2004), moisture sorption capacity and moisture content (Ohwoavworhua et al., 2005) .

    For particle size analysis, it can be determined using a sieve shaker, containing standard sieves arranged in a descending order according to their opening size. About 20 grams of the MCC powder is placed on the top sieve and shaking for 5 min. The weight of MCC retained on each sieve is determined. The average diameter can be calculated as reported by Ansel et al. (2005) using the following equation: Average diameter of the MCC particles = [∑ (% retained)×(mean aperture)]/100. The real density (Dr) of cellulose powders can be determined by the xylene displacement method (Ohwoavworhua et al., 2005) and computed according to the following Equation: Dr = [w/{(a+w)-b}×SG], where w represents weight of powder, SG represents specific gravity of xylene, a represents sum weights of bottle and solvent and b represents the sum weights of bottle, solvent and the MCC powder (Ohwoavworhua and Adelakun, 2010).

     

    For the moisture content (MC) determination, about 2 g of the MCC sample was weighed

    • and oven-dried at 105-C for 8 hours, and then weighed again (B). The MC was calculated using the following formula: [(A-B)/A]×100 (Annonymous, 2006). Spectroscopic Studies

    The optical microscope (10X, 40X or 100 X magnifications) can be used for speculating advancing hydrolysis as well as preliminary assessment of the MCC particles. Scanning electron microscopy (SEM) and/or transmission electron microscopy (TEM) study (Table 2) is widely used to character the MCC particles. The samples are placed on the double side carbon tape on Al-stub and dried in air. Before examination, all samples are sputtered with a 15 nm thick gold layer (JEOL JFC- 1600 Auto Fine Coater) in a vacuum chamber. For the SEM imaging, it can be done by Field Emmision SEM device such as JEOL, JSM-7600F (Bhimte and Tayade, 2007), while TEM imaging can

    be applied by such TEM-1011 JEOL, Japan.

    For X-ray differaction (XRD), the wide angle X-ray diffraction spectra of the MCC can be recorded on a proper X-ray differactometer such as a XRD 7000 Shimadzu diffractometer (Japan). The system has a rotating anode generator with a copper target and wide angle powder goniometer. The generator must be operated at 30 KV and 30 mA. All the experiments should be performed in the reflection mode at a scan speed of 4° /min in steps of 0.05°. All samples are scanned in 2θ range varying from 4° to 30°.

    The crystallinity index of the fiber is determined by using the following equation: Ic=[(I002-Iam)/( I002)]x100 (Bhimte and Tayade, 2007), where I002 represents the intensity of crystalline peak arising from and alpha-cellulose while Iam is the crystallographic plane arising from remained amorphous cellulose plus amorphous impurities (lignin and pectin.

    The crystal and molecular structure together with the hydrogen-bonding system in cellulose Iβ can be determined using synchrotron and neutron diffraction data recorded from oriented fibrous samples prepared by aligning cellulose microcrystals (Nishiyama et al., 2002).

     

    Thermal Analyses

    There are different types of the thermal analyses of the MCC (Table 2), namely thermogravimetric analysis (TGA) which measures weight changes, differential thermal analysis (DTA) that measures exothermic and endothermic reactions, differential scanning calorimetry (DSC) which measures the heat required to raiuse the sample temperature. In addition, thermal conductivity (TC) is frequently used to measure ability to transmit heat across the MCC sample. Furthermore, thermo-mechanical analysis (TMA) is useful to measure dimensional changes due to altering temperature. For the composites reinforced by the MCC, dynamic mechanical thermal analysis (DMTA) is used to investigate viscoelastic properties of polymers. The thermal behavior of the MCC can be predicted by TGA, DTA or DSC using a Seiko &star 6300 analyzer. Heating scans from 30 up to 550

    °C at 20 °C/min in nitrogen atmosphere are performed for each sample (Fortunati et al., 2013)

    Table 2. Parameters and techniques used to characterize microcrystalline cellulose (MCC), namely crystallinity index (CI) and crystallite size (CS) determined by X-ray differaction (XRD), Fourier transform infrared (FTIR) spectrometry, thermogravimetric analysis (TGA), differential thermal analysis (DTA), differential scanning calorimetry (DSC), scanning electron microscopy (SEM), transmission electron microscopy (TEM), viscosity measurement (VM), particle size and particle size distribution (PZ&PZD), true density (TD), tensile strength (TS), hardness (H), wet granulation (WG), hydration capacity (HC), swelling capacity (SC), moisture sorption capacity (MSC) and compressibility (Co).

     

    Reference No.

    XRD FTIR TGA DTG DTA DSC SEM TEM VM PZ&PZD TD TS H WG HC SC MSC Co
    CI CS
    4                                      
    9                                      
    27                                      
    6                                      
    22                                      
    26                                      

     

     

    The material safety data sheet (MSDS) of the MCC is presented in appendices 1-7.

     

    Conclusions

    • The Microcrystalline cellulose is a valuable additive in pharmaceutical, food, composites and cosmetic industries.
    • The Microcrystalline cellulose can be synthesized by reactive extrusion, enzyme mediated, the steam explosion and acid hydrolysis.
    • The acid hydrolysis process is preferred due to its shorter reaction duration, can be applied by a continuous process rather than a batch-type, it consumes limited quantity of acid and produces fine particles.
    • Different techniques are used to characterize the microcrystalline cellulose such as infrared spectroscopy, X-ray diffraction, thermogravimetric analysis, differential thermal analysis, differential scanning calorimetry, nuclear magnetic resonance, atomic force spectroscopy, scanning electron microscopy, transmission electron microscopy, hi-resolution transmission electron microscopy.
    • The organoleptic characteristic, identification tests, solubility and presence of organic impurities such as starch, dextrin and water-soluble substances are important to characterize the microcrystalline cellulose.

     

     

    • The pH, moisture content, total ash content, particle size analysis, true density, compressibility index, angle of repose, porosity, hydration, swelling capacity, moisture sorption capacity and moisture content.

    Appendices

    Appendix 1. Product and commercial identification of the microcrystalline cellulose

     

    Product name Avicel® PH Microcrystalline Cellulose
    Chemical family Carbohydrate
    Synonyms Microcrystalline cellulose (INCI name): MCC, cellulose gel

     

     

    Alternate names Avicel PH 101, 102, 103, 105, 112, 200, 113, 301, 302, 200LM

    Appendix 2. Physical and chemical properties

     

    Property Value
    Appearance White, free-flowing powder
    Moisture content (%) Typically 1 – 5 % water, by weight
    pH (In solution) 5.0 – 7.0 (11% solids dispersion)
    Solubility in water (% by weight) Insoluble
    Specific gravity 0.2 – 0.5 g/cc
    Explosive properties St-1
    Minimum ignition temperature 420°C
    Stability and reactivity Stable

    Appendix 3. Hazards and toxicological information of microcrystalline cellulose

     

    Emergency overview White free-flowing, odorless powder.
     Powder becomes slippery when wet.                                                                                   

    Accumulation of overhead settled dust may form fire problems.

    Potential health effects No significant health hazard expected
    Eye Non-irritating (rabbit)
    Skin Non-irritating (PII = 0/8) (rabbit); Non-sensitizing (guinea pig).
    Dermal LD50 > 2,000 mg/kg (rabbit)
    Oral LD50 > 5,000 mg/kg (rat)
    Inhalation LC50 (rat > 5.05 mg/l Maximum attainable concentration-zero mortality
    Acute effects from overexposure It has low oral, dermal and inhalation toxicity as well as non- irritating and non-sensitizing to the skin.
    Chronic effects from overexposure It is an inert dust and nontoxic to the lung. A 90-day animal study showed no adverse effects when administered in the diet. It is negative in the Ames mutagenicity assay and caused no

    chromosome damage.

    Carcinogenicity Not listed

     

    Appendix 4. First aid treatments to confront any health hazards due to the microcrystalline cellulose (MCC)

    Eye Flush with plenty of water. Get medical attention if irritation occurs and persists.
    Skin Wash with plenty of soap and water
    Ingestion Drink plenty of water. Never give anything by mouth to an unconscious person. If any discomfort persists, obtain medical attention.
    Inhalation Remove to fresh air. If breathing difficulty or discomfort occurs and persists, obtain medical attention.
     

    General notes

    This product has low oral, dermal and inhalation toxicity. It is non- irritating to the eyes and skin, and non-sensitizing to the skin. Treatment is symptomatic and supportive.

     

    Appendix 5. Ecological and eco-toxicological information

     

    Ecological results Microcrystalline cellulose is inherently biodegradable in soil. It biodegrades in soil at a rate comparable to corn starch.
     

    Eco-toxicological results

    48-hour LC50 > 100%, saturated solution, NOEC = 100% (daphnia).
    96-hour LC50 > 100%, saturated solution, NOEC =100%

     (rainbow trout).                                                                                          96-hour EC50 > 100%, saturated solution, NOEC = 12.5% (algae).

    Appendix 6. Permissible exposure limits (PEL) of dust in some countries:

     

    Country PEL (mg/m³) Notes
    Australia (TWA)1 10 –
    Belgium (TWA)1 10 Inhalable dust.
    China (STEL)2 25 –
    China (TWA)1 10 –
    Hong Kong (TWA)1 10 –
    Ireland (TWA)1 10 Inhalable dust.
    Korea (TWA)1 10 –
    New Zealand (TWA)1 10 Respirable dust with no asbestos and less than 1% free silica.
    Singapore (PEL)3 10 –
    Switzerland (TWA)1 3 Respirable dust.
    United Kingdom (STEL)2 10 Total inhalable dust.
    United Kingdom (TWA)1 10 Total inhalable dust.
    4 Respirable dust.

     

    1 TWA: Time-weighted average, 2 STEL: Short-term exposure limits and 3 PEL: Permissible exposure limit.

    Appendix 7. Considerations on fighting fires occurred due to microcrystalline cellulose

     

    Extinguishing media Water.
     

    Fire/explosion hazards

    The accumulation of excessive dust on overhead structures may produce explosive concentrations when disturbed and dispersed. According to NFPA 68, (Explosion Venting Guide),

    the Hazard Class of Dust Deflagrations for microcrystalline cellulose is St-1, the lowest hazard class.

     

    Fire fighting procedure

    For fires involving this material, do not enter any enclosed or confined fire space without wearing full protective clothing and self-contained breathing. Do not breathe smoke, gases or

    vapors generated.

    Release notes Since the MCC powder becomes slippery when wet, good housekeeping maintenance practices must be considered.

     

    References

    1. Abdullah, A. M. 1991. Production of jute microcrystalline cellulose. Journal of Bangladesh Academy of Science, 15 (2): 85–87.
    2. Annonymous, United States Pharmacopeia and Formulary (USP 29 – NF 24): Microcrystalline Cellulose. Rockville, MD: United States Pharmacopeia Convention; 2006:3306Y3307
    3. Ansel, C. H., Popovich, G. N. and Allen, V. L. 2005. Ansel’s Pharmaceutical Dosage Forms and Drug Delivery Systems. New York: Lippincott Williams and Wilkins, p.189.
    4. Bhimte, NA. and Tayade, P. T. Evaluation of microcrystalline cellulose prepared from sisal fibers as a tablet excipient: A technical note. Association of Pharmaceutical Scientists (AAPS), Pharmaceutical Science and Technology 2007;8(1):E56-E62. doi:10.1208/pt0801008.
    5. Bochek, A. M., Shevchuk, I. L., and Lavrentev, V. N. 2003. Fabrication of microcrystalline and powdered cellulose from shortflax fiber and flax straw. Russian Journal of Applied Chemistry, 76 (10), 1679–1682.

     

    1. Chauhan, Y. P., Sapkal, R. S., Sapkal, V. S. and Zamre, G. S. 2009. Microcrystalline cellulose from cotton rags (waste from garment and hosiery industries. International Journal of Chemical Sciences, 7 (2): 681-688.
    2. DFE-pharma: http://www.dfepharma.com/en/excipients/mcc/pharmacel-101.aspx.
    3. Ejikeme, P. M. 2008. Investigation of the physicochemical properties of microcrystalline cellulose from agriculture Wastes I: Orange Cellulose, 15: 141-147.
    4. El-Sakhawy, M. and Hassan, M. L. 2007. Physical and mechanical properties of microcrystalline cellulose prepared from agricultural residues. Carbohydrate Polymers, 67: 1–10. DOI:10.1016/j.carbpol.2006.04.009.
    5. Fortunati, E., Puglia, D., Monti, M., Peponi, L., Santulli, C., Kenny, J. M. and Torre, 2013. Extraction of Cellulose Nanocrystals from Phormium tenax Fibres. Journal of Polymers and the Environment. 21(2): 319-328.
    6. Gaonkar, S. M. and Kulkarni, P. R. 1987. Improved method for the preparation of microcrystalline cellulose from water hyacinth. Textile Dyer Printer, 20 (26): 19-
    7. Gaonkar, M. and Kulkarni, P. R. 1989. Microcrystalline cellulose from coconut shells. Acta Polymer, 40: 292–293. doi: 10.1002/actp.1989.010400419.
    8. Herrick, F.W.C., R. L.; Hamilton, J. K.; Sandberg, K. R., 1983. Microfibrillated cellulose: morphology and accessibility. Journal of Applied Polymer Science: Applied Polymer Symposium, 37: 797-813.
    9. Ilindra, and Dhake, J. D. 2008. Microcrystalline cellulose from bagasse and rice straw. Indian Journal of Chemical Technology, 15 (5): 497-499.
    10. Kornblum, S. and Stoopak, S. B. 1973. A new tablet disintegrant agent: crosslinked polyvinylpyrollidone. J Pharm Sci , 62: 43-51.
    11. Kuga, and Brown, R. M. 1987. Lattice imaging of ramie cellulose. Polymer Communications Guildford, 28 (11): 311-314.

     

    1. Matrosovich, M., Matrosovich, T., Garten, W. and Klenk, H.-D. 2006. New low- viscosity overlay medium for viral plaque assays. Virology Journal, 3: 63. DOI: 1186/1743-422X-3-63.
    2. Monschein, M., Reisinger, C. and Nidetzky, B. 2013. Enzymatic hydrolysis of microcrystalline cellulose and pretreated wheat straw: A detailed comparison using convenient kinetic analysis. Bioresource Technology, 128: 679–687.
    3. Nishiyama Y, Langan P, Chanzy 2002. Crystal structure and hydrogen- bonding system in cellulose Iβ from synchrotron X-ray and neutron fiber diffraction. J Am Chem Soc, 124(31):9074-82.
    4. Ohwoavworhua FO, Kunle OO, Ofoefule 2004. Extraction and characterization of microcrystalline cellulose derived from Luffa cylindrica plant. African Journal of Pharmaceutical Research and Development, 1:1-6.
    5. Ohwoavworhua, F. O., Ogah, and Kunle, O. O. 2005. Preliminary investigation of physicochemical and functional properties of alpha cellulose obtained from waste paper – A potential pharmaceutical Excipient. Journal of Raw Materials Research, 2: 84-93.
    6. Ohwoavworhua, F. O. and Adelakun, T. A. 2010. Non-wood fibre production of microcrystalline cellulose from Sorghum caudatum: Characterisation and tableting properties. Indian Journal of Pharmaceutical Science. 72 (3): 295–301.
    7. Padmadisastra, Y. and Gonda, I. Preliminary studies of the development of a direct compression cellulose excipient from bagasse. Journal of Pharmaceutical Sciences , 78 (6): 508-521.
    8. Paralikar, K. M. and Bhatawdekar, S. P. 1988. Microcrystalline cellulose from bagasse pulp. Biological Wastes, 24: 75–77.
    9. Shah, D. A., Shah, Y. D. and Trivedi, B. M. 1993. Production of microcrystalline cellulose from sugar cane bagasse on pilot plant and its evaluation as pharmaceutical adjunct. Research and Industry, 38 (3): 133–137.

     

    1. Suvachittanont, S. and Ratanapan, P. 2013. Optimization of Micro Crystalline Cellulose Production from Corn Cob for Pharmaceutical Industry Investment. Journal of Chemistry and Chemical Engineering, 7 (2013): 1136-1141.
    2. Szcześniak, , Rachocki, A. and Tritt-Goc, J. 2008. Glass transition temperature and thermal decomposition of cellulose powder. Cellulose 15(3):445-451.
    3. Tang, -G., Hon, D. N.-S., Pan, S.-H., Zhu, Y.-U., Wang, Z., & Wang, Z.-Z.
    4. Evaluation of microcrystalline cellulose. I. Changes in ultrastructural characteristics during preliminary acid hydrolysis. Journal of Applied Polymer Science, 59: 483–488.
    5. Thoorens, , Krier, F., Leclercq, B. , Carlin, B., Evrard, B. 2014. Microcrystalline cellulose, a direct compression binder in a quality by design environment: A review. International Journal of Pharmaceutics, 473 (1–2): 64–72.
    6. Train 1958. Some aspects of the property of angle of repose of powders. J Pharm Pharmacol, 10: 127T-34T.
    7. Turbak, A.F.S., F. W.; Sandberg, K. R., 1983. Microfibrilated cellulose, a new cellulose product: properties, uses, and commercial potential. Journal of Applied Polymer Science: Applied Polymer Symposium, 37: 815-827.
    8. Uesu, N. Y., Pineda, E. A., Hechenleitner, A. A. 2000. Microcrystalline cellulose from soybean husk: effects of solvent treatments on its properties as acetylsalicylic acid carrier. International Journal of Pharmaceutics, 206: 85-96.
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