Production of biodegrable plastic films from cassava starch used in food packaging, using various additives and plasticizers | Blazingprojects Postgraduate Thesis
Home / Biochemistry / Production of biodegrable plastic films from cassava starch used in food packaging, using various additives and plasticizers

Production of biodegrable plastic films from cassava starch used in food packaging, using various additives and plasticizers

 

Table Of Contents


Chapter ONE

INTRODUCTION

  • 1.1Introduction
  • 1.2Background of Study
  • 1.3Problem Statement
  • 1.4Objective of Study
  • 1.5Limitation of Study
  • 1.6Scope of Study
  • 1.7Significance of Study
  • 1.8Structure of the Research
  • 1.9Definition of Terms

Chapter TWO

LITERATURE REVIEW

  • 2.1Overview of Biodegradable Plastics
  • 2.2Cassava Starch as a Raw Material
  • 2.3Additives for Biodegradable Plastic Films
  • 2.4Plasticizers in Biodegradable Plastics
  • 2.5Properties of Biodegradable Plastic Films
  • 2.6Environmental Impact of Biodegradable Plastics
  • 2.7Market Trends in Biodegradable Packaging
  • 2.8Innovations in Biodegradable Plastics
  • 2.9Regulations and Standards for Biodegradable Plastics
  • 2.10Future Prospects in Biodegradable Packaging

Chapter THREE

RESEARCH METHODOLOGY

  • 3.1Research Design and Methodology
  • 3.2Selection of Cassava Starch
  • 3.3Formulation of Biodegradable Plastic Films
  • 3.4Testing Methods for Film Properties
  • 3.5Evaluation of Additives and Plasticizers
  • 3.6Data Collection and Analysis
  • 3.7Experimental Setup and Procedures
  • 3.8Statistical Analysis Techniques

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • 4.1Analysis of Film Composition
  • 4.2Mechanical Properties of Biodegradable Films
  • 4.3Barrier Properties Evaluation
  • 4.4Thermal Characterization of Films
  • 4.5Compatibility of Additives with Cassava Starch
  • 4.6Degradation Studies of Biodegradable Films
  • 4.7Comparison with Conventional Plastics
  • 4.8Discussion on Sustainability and Cost-effectiveness

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • 5.1Summary of Findings
  • 5.2Conclusion and Recommendations
  • 5.3Implications for Future Research
  • 5.4Contribution to the Field
  • 5.5Practical Applications of the Study

Thesis Abstract

Abstract
The demand for sustainable packaging materials is on the rise due to environmental concerns over the disposal of traditional plastics. In this study, biodegradable plastic films were produced from cassava starch for use in food packaging applications. Various additives and plasticizers were incorporated into the starch films to improve their mechanical and barrier properties. The effects of different additives such as glycerol, citric acid, and nanoclay on the film properties were investigated. The plasticizers were used to enhance the flexibility and stretchability of the films, making them suitable for packaging applications. The production process involved the blending of cassava starch with water and the additives, followed by casting the mixture into films using a film applicator. The films were then dried at controlled conditions to obtain the desired thickness and properties. Mechanical tests, such as tensile strength and elongation at break, were conducted to evaluate the film's strength and flexibility. Barrier properties, including water vapor permeability and oxygen transmission rate, were also measured to assess the film's ability to protect packaged food products. The results showed that the addition of glycerol as a plasticizer improved the flexibility and stretchability of the cassava starch films. Citric acid acted as a crosslinking agent, enhancing the mechanical strength of the films. Nanoclay additives improved the barrier properties of the films, reducing water vapor permeability and oxygen transmission rates. The combination of these additives resulted in biodegradable plastic films with improved mechanical and barrier properties suitable for food packaging applications. Overall, the study demonstrates the feasibility of producing biodegradable plastic films from cassava starch with enhanced properties using various additives and plasticizers. The use of sustainable materials like cassava starch offers an eco-friendly alternative to traditional plastics, reducing environmental impact and promoting a circular economy. The findings contribute to the development of biodegradable packaging materials that meet the increasing demand for sustainable solutions in the food packaging industry.

Thesis Overview

<p> </p><div><p><strong>1.1 &nbsp;</strong><strong>&nbsp;Background study</strong></p><p>&nbsp; &nbsp; Packagingvusing plasticvmaterialsvhas rapidly increasedvin recent times. Its vusevcovers a wide area of applicationvfromvautomobile parts, food, drinks, water, snacks, cloths, fresh and sea foods, vfarm products, vmedicals and pharmaceuticals, to mention but a few. The use of such bombasticvamount of schematicvplastics and itsvadvantage overvother packaging materialsvis due tovits diversevandvadvancevpropertiesvofvlongevity.Thevproperties include resistance tovchemicalvreaction, vthermal strength, mechanical and its tensile strength, vespeciallyvenzymaticvreactions (Ezeoha and Ezenwanne, 2013.).</p><p>&nbsp; &nbsp; For example it willvtake avveryvlongvtimevsay avhundredvyears to degradevjustva piece of plastic film (polyethene) used to package snacks (gala) at standard environmental conditions. vBasically, two challenges have been cited with the of conventional polyethene usevits dependence on vpetroleum and the problem vof waste disposal. Most of today’s conventionalvsynthetic polymers vare producedvfromvpetrochemicals that vare not biodegradable. Thesevstable vpolymers are a significant vsourcevof venvironmental pollution, vharming vorganic naturevwhen vthey are dispersedvin thevenvironment, changes thevcarbon dioxide cycle, problemvassociatedvwith increasedvtoxic emission. The sources of synthetic polymersvsuch as fossilvfuel and gas arevnow stimulated by environmental concerns. Scientists arevresearchingvdifferentvmethods ofvimprovingvplastics thatvcanvbevusedvmorevefficientlyvsuchvthat they could be recycled, vreused and to possiblyvdegradevafter use.</p><p>&nbsp; &nbsp; &nbsp; Alternationvisvtowardsvgreenervagriculturalvsources, &nbsp; vwhich valsovwouldvlead &nbsp; vto &nbsp; the &nbsp; reduction of CO2 emissions (Narayan, 2001). According to the Biodegradable &nbsp; ProductsvInstitutev (BPI), avbiodegradable plastics isvone in which degradation &nbsp; results from &nbsp; the vactionvofvnaturallyvoccurring &nbsp; vmicro-organismsvsuch as bacteria, vfungi or algae. Degradablevplastics are classified byvAmericanvSociety forvTesting and Materials &nbsp; (ASTM) into four these are:-</p><p>(1) Photodegradablevplastics: Degradation of the plastic results from natural daylight. &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;</p><p>&nbsp;(2) Oxidativevdegradable plastics: A degradation of plastics as a result of oxidation.</p><p>(3) hydrolytically degradable plastics: – The degradability resultsvfromvhydrolysis, vand</p><p>&nbsp;(4) BiodegradablevPlastics: – Degradablevplastics invwhich there isvbreakdown of long chain polymervmoleculevinto smaller or shorter lengths. It undergoes oxidationvwhich is triggered by heat, ultraviolent light (UVlight), and mechanical stress. Itvoccurs in thevpresencevof moisture and actions from naturallyvoccurringvmicroorganismsvsuch asvbacterial, fungi and algae. (ASTM Standards, 1998)</p><p>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; Thevvariousvdegradablevplastics definitions classified above offers the onlyvproducts whichvarevnaturallyvdegradable. Starch isvbeenvdiscoveredvamongst all biopolymers as a high potentialvmaterial for biodegrablevfilms. Starchvconsists of two types of polysaccharides, amylose and amylopectinvdepending on the sucrose (10-20%) amylase and (80-90%) amylopectin. The hydrophlicity ofvstarch canvbe used tovincrease the biodegrability of starch-basedvplastics. Amylosevis avlinearvmolecule with a fewvbranches, whereasvamylopectinvis avhighlyvbranchedvmolecule. Therefore, vamylosevcontentvis an importantvfactor to biodegrable plastic filmvstrength. Branchedvstructure of amylopectin generallyvleads to filmvwith lowvmechanical properties. To improve thevflexibilityvof plastics, plasticizers arevadded tovreduce internalvhydrogen bondvbetweenvpolymer chainsvwhile increasing molecular space. The mostvcommonly used starchvplasticizers are polyols, sorbitol and glycerol. Thevkey emphasisvin biodegrability is thatvbiopolymer materialsvbreakdownvintovsmaller compounds, either chemically or byvorganisms sooner than synthetic plastics (Bastioli, 2005.). Biodegradablevpackagingvmaterials are materials that degrades back tovthe earth surfacevharmlessly when disposed. This help largely in reducingvthe amount of packaging materialsvthat goes back into landfills andvfurthermore, saves energy, as the biodegrable route requires little or novexternal source of energy its endothermic.</p><p>&nbsp;Biodegrable polymervsources are fromvreplaceable agriculturalvfeed socks, vanimal sources, vmarinevfoodvprocessingvindustriesvwaste, or microbial sources. In addition to replenshiable raw agricultural ingredients, biodegrable materials breakdownvinto environmental friendlyvproducts such; as carbon dioxide, vwater and quality compost. </p><p>&nbsp; &nbsp; &nbsp; Biodegradationvtakesvplace in two-steps: vdegradation/defragmentationvinitiated by heat, moisture, or microbial enzymes, andvsecond step – biodegradation – where the shorter carbonvchains passvthrough the cellvwalls of the microbesvand are used as anvenergy source. Biodegrable plastics are made from cellulose-based starchvand has been in existence for decades, with first exhibitionvof a cellulose-basedvstarch (which initiated thevbiodegradable plasticvindustry in 1862). Cellophanevisvthevmost cellulose-basedvbiopolymer. vStarch-based biopolymer, which swellvandvdeformvwhen exposedvtovmoisture, include amylose, hydroxyalkanote (PHA), polyhydroxybuterate (PHB), and avcopolymer of PhB and valeric acid (PhB/V). These are made from lactic acid formed fromvmicrobial fermentation of starch derivatives, polylactide does not degrade when exposed tovmoisture (Auras.et al, 2007) PHA, PHB, andvPHB/V are formedvby bacterial actionsvonvstarch (Krochta, 1997). In addition, biodegrable films can also bevproduce from chitosan, vwhich isvderivedvfromvchitin of crustacean and insectvexoskeletons. Chitin is a biopolymervsimilar tovcellulose structure. Therevare variousvwaysvstarchvcan be used for biodegrable polymervproduction; </p><ol><li>Starchvcompostvcontainingvmore than half byvmass of thevplasticizers.</li><li>&nbsp;Biodegrable polymers preparationvusing thevextrusion process of mixtures of granularvstarch.</li><li>&nbsp;Compositionvof starchvwith othervplastics of little quantityvof agricultural based material to enhance the biodegrability of conventional synthetic polymer.</li></ol><p>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; Synthetic polymers can alsovbe madevpartially degradablevbyvblending with biopolymers, vincorporating biodegrable components such as starch, or by adding bioactive compounds. vThe bio compoundsvare degradedvto break thevpolymervinto smaller chains. Bioactivevcompounds work through diverse mechanisms. For example, theyvmay be mixed with swelling agents tovincrease thevmolecular structure ofvthe plastic whichvupon exposure tovmoisture vallow the bioactivevcompounds to breakdownvthe plastics.</p><p>&nbsp;<br><strong>1.2 Problem statement</strong></p><p>&nbsp; &nbsp; &nbsp; Therevisvbasically, vtwo harmsvconnected to the wide applicationvof synthetic polymer plastics for packaging sincevits inventionvin the 1930s: They arevtotalvreliance on petrochemicalvproduct as itsvmain feedvstockvand the problemvof wastevdisposal. Most of today’s conventional synthetic polymers arevproduced from petrochemicalsvandvare not biodegradable. Thesevstable polymers are avsignificant source ofvenvironmentalvpollution, harmfulvtovorganicvnaturevwhen they are dispersed in the environment. The rawvmaterials such as fossil fuelvand gasvcould be replaced by greenervagriculturalvsources, which contributevto the reductionvof Co2vemissions (Narayan, 2001). Basedvon the abovevit becomes ofvvalue to producevplastics that are biodegradable,vin excess of the past few years syntheticvpolymer usersvhave been introducingvvarious forms ofvbiodegradablevplastics. Thevalternative rawvmaterialsvare nowvfrom plants products, the main amongvmanyvothers is cornvstarch.</p><p><strong>1.3Justification</strong></p><p>&nbsp; &nbsp; Biovplasticsvwere too expensive for considerationvof replacementvfor petroleumvbased plastics. The lowervtemperature needed for the production of bio plastics and the more sTable supply of biomass combined withvthevincreasing cost of crude oil make bio plastics prices morevcompetitivevwithvregular plastics. Starch isvinexpensivevand abundancevin nature, Nigeriavbeing the world largestvproducer of cassava (FAO, 2009) and being a root crop that canvbe grown in every part of the nation, Starchvis totally biodegradable in a wide range of environmentsvand can be usedvin the developmentvof biodegrable packaging products for variousvmarket uses. Incineration of starch product is a way of recycling, the atmosphericvCO2 trapped by starch-producingvplant duringvgrowth, thusvclosing the biological carbonvcycle (Ceredav<em>et al</em>).</p><p><strong>1.4 &nbsp;</strong><strong>Aim</strong>v<strong>and</strong>v<strong>objectives</strong></p><p>&nbsp; &nbsp; The aimvof thisvresearch is to produce biodegrable plastic films from cassava starch used in food packaging, using various additives and plasticizers. This will be achieved via the following objectives.</p><ol><li>Extraction of starch from fresh cassava.</li><li>Improving the extracted starch with addition of plasticizers and various additives,</li><li>&nbsp;Determining the biodegrability and tensile strength of the produced biodegradable products and comparing with that of synthetic polyethene.</li><li>&nbsp;Testing for the validity of the produced biodegradable film.</li></ol><p><strong>1.5 Scope of study</strong></p><p>The scope of theses work is strictly limited to:</p><p>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; I. &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; Extraction of starch from cassava.</p><p>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; II. &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; Physical and chemical properties of plasticizers and additives in resumption.</p><p>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; III. &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;Cost estimation.</p><p>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; IV. &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; Biodegrability test, and the characterization of the produced film.</p><p></p></div><h3></h3><br> <br><p></p>

Blazingprojects Mobile App

📚 Over 50,000 Research Thesis
📱 100% Offline: No internet needed
📝 Over 98 Departments
🔍 Thesis-to-Journal Publication
🎓 Undergraduate/Postgraduate Thesis
📥 Instant Whatsapp/Email Delivery

Blazingprojects App

Related Research

Medical Laboratory S. 3 min read

A Framework for Standardizing Quality Control Practices in Clinical Laboratory Testi...

This research focuses on developing a clear and practical framework to standardize quality control practices in clinical laboratory testing. Quality control in ...

BP
Blazingprojects
Read more →
Mechanical engineeri. 2 min read

A Framework for Parametric Modeling of Additive Manufacturing Mechanical Properties...

This research focuses on developing a systematic framework to model the mechanical properties of materials produced through additive manufacturing (AM), also kn...

BP
Blazingprojects
Read more →
Mathematics. 4 min read

A Framework for Modeling Nonlinear Dynamics in Chaotic Systems...

This research aims to develop a comprehensive framework for understanding and modeling nonlinear dynamics in chaotic systems. Chaotic systems are complex system...

BP
Blazingprojects
Read more →
Materials and Metall. 3 min read

A Framework for Predicting Corrosion Resistance in Aluminum Alloy Composites...

This research focuses on developing a structured way to predict how well aluminum alloy composites resist corrosion, which is a common challenge in many industr...

BP
Blazingprojects
Read more →
Mass communication. 3 min read

A Framework for Analyzing the Impact of Social Media Influencers on Youth Political ...

This research examines how social media influencers affect the way young people engage with politics. In recent years, social media influencers—individuals wi...

BP
Blazingprojects
Read more →
Marketing. 3 min read

A Framework for Integrating Social Media Engagement into Customer Loyalty Models...

This research explores how social media engagement influences customer loyalty, aiming to create a new framework that combines these two areas. Customer loyalty...

BP
Blazingprojects
Read more →
Linguistics. 2 min read

A Framework for Analyzing Code-Switching as a Pragmatic Competence...

This research is focused on understanding how people switch between languages or dialects in everyday conversation, a phenomenon known as code-switching. Specif...

BP
Blazingprojects
Read more →
Library Science Educ. 3 min read

A Framework for Enhancing Critical Teaching Skills in Library Science Education...

This research focuses on developing a clear and practical framework that can help improve the way library science educators teach critical thinking skills. Crit...

BP
Blazingprojects
Read more →
Library and informat. 2 min read

A Framework for Assessing Information Literacy Development in Academic Libraries...

This research is about creating a clear and practical framework that can be used to assess how well students in universities develop their information literacy ...

BP
Blazingprojects
Read more →
WhatsApp Click here to chat with us