SlideShare a Scribd company logo

PHB presentation 2

Download as PPT, PDF
Rahul Negi
Rahul Negi
1 of 11
IntroductionIntroduction  Degradable polymers that are naturally degradedDegradable polymers that are naturally degraded by the action of microorganisms such as bacteria,by the action of microorganisms such as bacteria, fungi and algaefungi and algae  What are Bioplastics?What are Bioplastics?  Benefits Include:Benefits Include:  100 % biodegradable100 % biodegradable  Produced from natural, renewable resourcesProduced from natural, renewable resources  Able to be recycled, composted or burned withoutAble to be recycled, composted or burned without producing toxic byproductsproducing toxic byproducts
ApplicationsApplications  IndustryIndustry  Products, films, paper laminates & sheets,Products, films, paper laminates & sheets, bags and containersbags and containers  AutomobilesAutomobiles  MedicalMedical  Sutures, ligament replacements, controlledSutures, ligament replacements, controlled drug release mechanisms, arterial grafts…drug release mechanisms, arterial grafts…  HouseholdHousehold  Disposable razors, utensils, diapers, feminineDisposable razors, utensils, diapers, feminine hygiene products, containers…hygiene products, containers…
Production of BioplasticProduction of Bioplastic BacteriaBacteria Physical stress ( PH, temperature)Physical stress ( PH, temperature) PHB synthesisPHB synthesis PHB recovery from bacterial extractPHB recovery from bacterial extract Purification of PHBPurification of PHB
PHA BiosynthesisPHA Biosynthesis  It consist three enzymatic reactionIt consist three enzymatic reaction  Contestation of two acetyl coenzyme A intoContestation of two acetyl coenzyme A into acetoacetyl-coA byacetoacetyl-coA by ββ-ketoacyl CoA thiolase (phb A)-ketoacyl CoA thiolase (phb A)  Reduction of actoactyle CoA to ®-3-hydroxybutyryl-Reduction of actoactyle CoA to ®-3-hydroxybutyryl- CoA by NADPH dependent acetoacetyl CoACoA by NADPH dependent acetoacetyl CoA dehydrogenase (phb B)dehydrogenase (phb B)  ®-3-hydroxybutyryl CoA monomer polymerized®-3-hydroxybutyryl CoA monomer polymerized into PHB by P(3HB) polymerase (phbC)into PHB by P(3HB) polymerase (phbC) (huisman(huisman et alet al., 1989)., 1989)
Bioplastic PropertiesBioplastic Properties  Some are stiff and brittleSome are stiff and brittle  Crystalline structureCrystalline structure  rigidityrigidity  Degrades at 185°CDegrades at 185°C  Moisture resistant, water insoluble, opticallyMoisture resistant, water insoluble, optically pure, impermeable to oxygenpure, impermeable to oxygen  Must maintain stability during manufacture andMust maintain stability during manufacture and use but degrade rapidly when disposed of oruse but degrade rapidly when disposed of or recycledrecycled
ConclusionsConclusions  Need for bioplastic optimization:Need for bioplastic optimization:  Economically feasible to produceEconomically feasible to produce  Cost appealing to consumersCost appealing to consumers  Question:Question: How many of you would be willing to pay 2-3How many of you would be willing to pay 2-3 times more for plastic products because theytimes more for plastic products because they were “environmentally friendly”?were “environmentally friendly”?
 Rahul Negi, Dr Vikas Babu “Scientist C”Rahul Negi, Dr Vikas Babu “Scientist C”  Department of Biotechnology Graphic EraDepartment of Biotechnology Graphic Era University DehradunUniversity Dehradun
Abstract-Abstract- Polyhydroxybutyrates (PHBs) are a potential alternative to thePolyhydroxybutyrates (PHBs) are a potential alternative to the environment polluting non degradable plastics. These compounds areenvironment polluting non degradable plastics. These compounds are non- toxic, biodegradable, highly crystalline, optically active,non- toxic, biodegradable, highly crystalline, optically active, isotactic and insoluble polymers. PHBs are storage compoundsisotactic and insoluble polymers. PHBs are storage compounds produced by variety of micro organisms under nutrient stressproduced by variety of micro organisms under nutrient stress conditions. About 75 genera of gram positive and gram negativeconditions. About 75 genera of gram positive and gram negative bacteria are known to produce PHBs when grown in carbon andbacteria are known to produce PHBs when grown in carbon and nitrogen limited media. Some important examples of PHB producingnitrogen limited media. Some important examples of PHB producing bacteria arebacteria are Ralstonia eutrophaRalstonia eutropha,, Alcaligenes eutrophus, PseudomonasAlcaligenes eutrophus, Pseudomonas pseudomallei, E. coli, Halomonas campisalispseudomallei, E. coli, Halomonas campisalis etc.etc. The major challenge is to make the extraction process economicallyThe major challenge is to make the extraction process economically viable to be used on an industrial scale that can compete with theviable to be used on an industrial scale that can compete with the cheap prices of the synthetic non biodegradable plastics such ascheap prices of the synthetic non biodegradable plastics such as polyethylens. The by-products formed during PHB formation likepolyethylens. The by-products formed during PHB formation like HAME (hydroxy alkanoate methyl ester) that have alternative fuelHAME (hydroxy alkanoate methyl ester) that have alternative fuel applications can be used to enhance the industrial application andapplications can be used to enhance the industrial application and economic feasibility of these compounds.economic feasibility of these compounds.

Recommended

PHB production by bacteria and its applications
PHB production by bacteria and its applicationsPHB production by bacteria and its applications
PHB production by bacteria and its applications
ಶಂತನು ಕೆ. ಗೌಡ
 
Polyhydroxybutyrate IP
Polyhydroxybutyrate IPPolyhydroxybutyrate IP
Polyhydroxybutyrate IP
Bernard Chung
 
Production of PHB
Production of PHBProduction of PHB
Production of PHB
Sonia Patel
 
Polyhdroxyalkanoates
PolyhdroxyalkanoatesPolyhdroxyalkanoates
Polyhdroxyalkanoates
Mohamed M. Abdul-Monem
 
bioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyrate
bioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyratebioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyrate
bioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyrate
Pramod Pal
 
Biopolymer
BiopolymerBiopolymer
Biopolymer
kishorsalvatore
 
Biodegradation of xenobiotics
Biodegradation of xenobioticsBiodegradation of xenobiotics
Biodegradation of xenobiotics
sajjad mughal
 
Airlift fermenter
Airlift fermenterAirlift fermenter
Airlift fermenter
Ravi Rastogi
 

Recommended

PHB production by bacteria and its applications
PHB production by bacteria and its applicationsPHB production by bacteria and its applications
PHB production by bacteria and its applications
ಶಂತನು ಕೆ. ಗೌಡ
 
Polyhydroxybutyrate IP
Polyhydroxybutyrate IPPolyhydroxybutyrate IP
Polyhydroxybutyrate IP
Bernard Chung
 
Production of PHB
Production of PHBProduction of PHB
Production of PHB
Sonia Patel
 
Polyhdroxyalkanoates
PolyhdroxyalkanoatesPolyhdroxyalkanoates
Polyhdroxyalkanoates
Mohamed M. Abdul-Monem
 
bioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyrate
bioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyratebioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyrate
bioplastics by microorganisms Polyhydroxyalkanoates And Polyhydroxybutyrate
Pramod Pal
 
Biopolymer
BiopolymerBiopolymer
Biopolymer
kishorsalvatore
 
Biodegradation of xenobiotics
Biodegradation of xenobioticsBiodegradation of xenobiotics
Biodegradation of xenobiotics
sajjad mughal
 
Airlift fermenter
Airlift fermenterAirlift fermenter
Airlift fermenter
Ravi Rastogi
 
An overview of the animal & plant cell reactors used in laboratories
An overview of the animal & plant cell reactors used in laboratoriesAn overview of the animal & plant cell reactors used in laboratories
An overview of the animal & plant cell reactors used in laboratories
Erin Davis
 
Biodegradation of xenobiotics
Biodegradation of xenobioticsBiodegradation of xenobiotics
Biodegradation of xenobiotics
Sushmita Pradhan
 
Degradation of lignin and cellulose using microbes
Degradation of lignin and cellulose using microbesDegradation of lignin and cellulose using microbes
Degradation of lignin and cellulose using microbes
Dr. Naveen Gaurav srivastava
 
Airlift fermenter
Airlift fermenterAirlift fermenter
Airlift fermenter
parnavi kadam
 
Bio plastic from bacteria.
Bio plastic from bacteria.Bio plastic from bacteria.
Bio plastic from bacteria.
Mona Othman Albureikan / King Abdulaziz University
 
Biodegradation
BiodegradationBiodegradation
Biodegradation
SureshKumar Pandian
 
Bioplastics
BioplasticsBioplastics
Bioplastics
Rachna Sinha
 
Screening
ScreeningScreening
Screening
Muskan Bhardwaj
 
Single cell protein
Single cell proteinSingle cell protein
Single cell protein
Firdous Ansari
 
Biopolymer
BiopolymerBiopolymer
Biopolymer
Dr NEETHU ASOKAN
 
BIOSENSOR FOR ENVIRONMENTAL MONITORING
BIOSENSOR FOR ENVIRONMENTAL MONITORINGBIOSENSOR FOR ENVIRONMENTAL MONITORING
BIOSENSOR FOR ENVIRONMENTAL MONITORING
ijiert bestjournal
 
Biodeterioration of paper and leather ppt..
Biodeterioration of paper and leather ppt..Biodeterioration of paper and leather ppt..
Biodeterioration of paper and leather ppt..
ShaistaKhan60
 
MEDIA FORMULATION
MEDIA FORMULATIONMEDIA FORMULATION
MEDIA FORMULATION
sachinhalladamani
 
Metabolic engineering
Metabolic engineeringMetabolic engineering
Metabolic engineering
Soumitra Paul
 
Bioplastic
BioplasticBioplastic
Bioplastic
Jatin Garg
 
BIOREACTORS OR FERMENTERS
BIOREACTORS OR FERMENTERSBIOREACTORS OR FERMENTERS
BIOREACTORS OR FERMENTERS
Archana Shaw
 
Biodeterioration
Biodeterioration Biodeterioration
Biodeterioration
Bharati Vidhyapeeth University , Pune
 
strain improvement techniques
strain improvement techniquesstrain improvement techniques
strain improvement techniques
jeeva raj
 
Bioreactors
BioreactorsBioreactors
Bioreactors
HARINATHA REDDY ASWARTHA
 
Bioreactors
BioreactorsBioreactors
Bioreactors
deyasetty
 
L’importanza dei manufatti compostabili nella raccolta della frazione organica
L’importanza dei manufatti compostabili nella raccolta della frazione organicaL’importanza dei manufatti compostabili nella raccolta della frazione organica
L’importanza dei manufatti compostabili nella raccolta della frazione organica
Mater-Bi
 
Tesina bioplastiche
Tesina bioplasticheTesina bioplastiche
Tesina bioplastiche
Marcello Giuliano
 

More Related Content

What's hot

Degradation of lignin and cellulose using microbes
Degradation of lignin and cellulose using microbesDegradation of lignin and cellulose using microbes
Degradation of lignin and cellulose using microbes
Dr. Naveen Gaurav srivastava
 

What's hot (20)

An overview of the animal & plant cell reactors used in laboratories
An overview of the animal & plant cell reactors used in laboratoriesAn overview of the animal & plant cell reactors used in laboratories
An overview of the animal & plant cell reactors used in laboratories
 
Biodegradation of xenobiotics
Biodegradation of xenobioticsBiodegradation of xenobiotics
Biodegradation of xenobiotics
 
Degradation of lignin and cellulose using microbes
Degradation of lignin and cellulose using microbesDegradation of lignin and cellulose using microbes
Degradation of lignin and cellulose using microbes
 
Airlift fermenter
Airlift fermenterAirlift fermenter
Airlift fermenter
 
Bio plastic from bacteria.
Bio plastic from bacteria.Bio plastic from bacteria.
Bio plastic from bacteria.
 
Biodegradation
BiodegradationBiodegradation
Biodegradation
 
Bioplastics
BioplasticsBioplastics
Bioplastics
 
Screening
ScreeningScreening
Screening
 
Single cell protein
Single cell proteinSingle cell protein
Single cell protein
 
Biopolymer
BiopolymerBiopolymer
Biopolymer
 
BIOSENSOR FOR ENVIRONMENTAL MONITORING
BIOSENSOR FOR ENVIRONMENTAL MONITORINGBIOSENSOR FOR ENVIRONMENTAL MONITORING
BIOSENSOR FOR ENVIRONMENTAL MONITORING
 
Biodeterioration of paper and leather ppt..
Biodeterioration of paper and leather ppt..Biodeterioration of paper and leather ppt..
Biodeterioration of paper and leather ppt..
 
MEDIA FORMULATION
MEDIA FORMULATIONMEDIA FORMULATION
MEDIA FORMULATION
 
Metabolic engineering
Metabolic engineeringMetabolic engineering
Metabolic engineering
 
Bioplastic
BioplasticBioplastic
Bioplastic
 
BIOREACTORS OR FERMENTERS
BIOREACTORS OR FERMENTERSBIOREACTORS OR FERMENTERS
BIOREACTORS OR FERMENTERS
 
Biodeterioration
Biodeterioration Biodeterioration
Biodeterioration
 
strain improvement techniques
strain improvement techniquesstrain improvement techniques
strain improvement techniques
 
Bioreactors
BioreactorsBioreactors
Bioreactors
 
Bioreactors
BioreactorsBioreactors
Bioreactors
 

Viewers also liked

Lezione 3 polimeri i
Lezione 3 polimeri iLezione 3 polimeri i
Lezione 3 polimeri i
lab13unisa
 
Peran Promosi Kesehatan Dalam Pencapaian MDGs
Peran Promosi Kesehatan Dalam Pencapaian MDGsPeran Promosi Kesehatan Dalam Pencapaian MDGs
Peran Promosi Kesehatan Dalam Pencapaian MDGs
Cut Ampon Lambiheue
 
Pengantar promosi kesehatan
Pengantar promosi kesehatanPengantar promosi kesehatan
Pengantar promosi kesehatan
om_wiez
 

Viewers also liked (20)

L’importanza dei manufatti compostabili nella raccolta della frazione organica
L’importanza dei manufatti compostabili nella raccolta della frazione organicaL’importanza dei manufatti compostabili nella raccolta della frazione organica
L’importanza dei manufatti compostabili nella raccolta della frazione organica
 
Tesina bioplastiche
Tesina bioplasticheTesina bioplastiche
Tesina bioplastiche
 
Le bioplastiche
Le bioplasticheLe bioplastiche
Le bioplastiche
 
Pecha kucha
Pecha kuchaPecha kucha
Pecha kucha
 
Sap phbs
Sap phbsSap phbs
Sap phbs
 
Bioplastica
BioplasticaBioplastica
Bioplastica
 
Lezione 3 polimeri i
Lezione 3 polimeri iLezione 3 polimeri i
Lezione 3 polimeri i
 
Polimeri
PolimeriPolimeri
Polimeri
 
Peran Promosi Kesehatan Dalam Pencapaian MDGs
Peran Promosi Kesehatan Dalam Pencapaian MDGsPeran Promosi Kesehatan Dalam Pencapaian MDGs
Peran Promosi Kesehatan Dalam Pencapaian MDGs
 
Biodegradable polymer
Biodegradable polymerBiodegradable polymer
Biodegradable polymer
 
Promkes
PromkesPromkes
Promkes
 
PROMOSI KESEHATAN
PROMOSI KESEHATANPROMOSI KESEHATAN
PROMOSI KESEHATAN
 
2/08 Presentation on Biodiesel and Yokayo Biofuels
2/08 Presentation on Biodiesel and Yokayo Biofuels2/08 Presentation on Biodiesel and Yokayo Biofuels
2/08 Presentation on Biodiesel and Yokayo Biofuels
 
Pengantar promosi kesehatan
Pengantar promosi kesehatanPengantar promosi kesehatan
Pengantar promosi kesehatan
 
Biodiesel
BiodieselBiodiesel
Biodiesel
 
Biofuels
BiofuelsBiofuels
Biofuels
 
298058252 juknis-phbs-rumah-tangga
298058252 juknis-phbs-rumah-tangga298058252 juknis-phbs-rumah-tangga
298058252 juknis-phbs-rumah-tangga
 
Biodegradable polymers
Biodegradable polymersBiodegradable polymers
Biodegradable polymers
 
Biodegradable polymers
Biodegradable polymersBiodegradable polymers
Biodegradable polymers
 
Biodegradable polymers by madhuri phute
Biodegradable polymers by madhuri phuteBiodegradable polymers by madhuri phute
Biodegradable polymers by madhuri phute
 

Similar to PHB presentation 2

What Is Biodegradable
What Is BiodegradableWhat Is Biodegradable
What Is Biodegradable
Iqbal Mulla
 
Biodegradable Polymers By CHITRANSH
Biodegradable Polymers By CHITRANSHBiodegradable Polymers By CHITRANSH
Biodegradable Polymers By CHITRANSH
CHITRANSH JUNEJA
 
Bio on think-beyond_plastic_pitch_deck_final
Bio on think-beyond_plastic_pitch_deck_finalBio on think-beyond_plastic_pitch_deck_final
Bio on think-beyond_plastic_pitch_deck_final
Diego Torresan
 
Biodegradable Polymers
Biodegradable PolymersBiodegradable Polymers
Biodegradable Polymers
Saurabh Shukla
 
2012 0121 platt bioplastics101 uscc jan212
2012 0121 platt bioplastics101 uscc jan2122012 0121 platt bioplastics101 uscc jan212
2012 0121 platt bioplastics101 uscc jan212
spickell
 
BioEnzyme Technologies Presentation
BioEnzyme Technologies PresentationBioEnzyme Technologies Presentation
BioEnzyme Technologies Presentation
Pars Kutay
 
evaluvation of food by conventional and microwave cooking
evaluvation of food by conventional and microwave cookingevaluvation of food by conventional and microwave cooking
evaluvation of food by conventional and microwave cooking
fathimarose
 
bioplasticfinal-150313052258-conversion-gate01.pptx
bioplasticfinal-150313052258-conversion-gate01.pptxbioplasticfinal-150313052258-conversion-gate01.pptx
bioplasticfinal-150313052258-conversion-gate01.pptx
RAJESHKUMAR428748
 

Similar to PHB presentation 2 (20)

Biopolymers presentation
Biopolymers presentation Biopolymers presentation
Biopolymers presentation
 
bioplastics and biotechnology for sustainable future
bioplastics and biotechnology for sustainable futurebioplastics and biotechnology for sustainable future
bioplastics and biotechnology for sustainable future
 
bioplastics and biotechnology: Green Plastics.pdf
bioplastics and biotechnology: Green Plastics.pdfbioplastics and biotechnology: Green Plastics.pdf
bioplastics and biotechnology: Green Plastics.pdf
 
Biodegradable plastic plant biotech.
Biodegradable plastic plant biotech.Biodegradable plastic plant biotech.
Biodegradable plastic plant biotech.
 
Bioplastic
BioplasticBioplastic
Bioplastic
 
What Is Biodegradable
What Is BiodegradableWhat Is Biodegradable
What Is Biodegradable
 
261252851 biodegradable-materials-ppt
261252851 biodegradable-materials-ppt261252851 biodegradable-materials-ppt
261252851 biodegradable-materials-ppt
 
Biodegradable Polymers By CHITRANSH
Biodegradable Polymers By CHITRANSHBiodegradable Polymers By CHITRANSH
Biodegradable Polymers By CHITRANSH
 
Bio on think-beyond_plastic_pitch_deck_final
Bio on think-beyond_plastic_pitch_deck_finalBio on think-beyond_plastic_pitch_deck_final
Bio on think-beyond_plastic_pitch_deck_final
 
Bio plastics presentation
Bio plastics presentationBio plastics presentation
Bio plastics presentation
 
Biodegradable Polymers
Biodegradable PolymersBiodegradable Polymers
Biodegradable Polymers
 
Biopolymers Information
Biopolymers InformationBiopolymers Information
Biopolymers Information
 
2012 0121 platt bioplastics101 uscc jan212
2012 0121 platt bioplastics101 uscc jan2122012 0121 platt bioplastics101 uscc jan212
2012 0121 platt bioplastics101 uscc jan212
 
BioEnzyme Technologies Presentation
BioEnzyme Technologies PresentationBioEnzyme Technologies Presentation
BioEnzyme Technologies Presentation
 
Biopolymers
BiopolymersBiopolymers
Biopolymers
 
BIOPLASTICS .pptx
BIOPLASTICS .pptxBIOPLASTICS .pptx
BIOPLASTICS .pptx
 
evaluvation of food by conventional and microwave cooking
evaluvation of food by conventional and microwave cookingevaluvation of food by conventional and microwave cooking
evaluvation of food by conventional and microwave cooking
 
Bioplastic
Bioplastic Bioplastic
Bioplastic
 
bioplasticfinal-150313052258-conversion-gate01.pptx
bioplasticfinal-150313052258-conversion-gate01.pptxbioplasticfinal-150313052258-conversion-gate01.pptx
bioplasticfinal-150313052258-conversion-gate01.pptx
 
Ppt of biodegradable packaging
Ppt of biodegradable packagingPpt of biodegradable packaging
Ppt of biodegradable packaging
 

PHB presentation 2

  • 1. IntroductionIntroduction  Degradable polymers that are naturally degradedDegradable polymers that are naturally degraded by the action of microorganisms such as bacteria,by the action of microorganisms such as bacteria, fungi and algaefungi and algae  What are Bioplastics?What are Bioplastics?  Benefits Include:Benefits Include:  100 % biodegradable100 % biodegradable  Produced from natural, renewable resourcesProduced from natural, renewable resources  Able to be recycled, composted or burned withoutAble to be recycled, composted or burned without producing toxic byproductsproducing toxic byproducts
  • 2.
  • 3. ApplicationsApplications  IndustryIndustry  Products, films, paper laminates & sheets,Products, films, paper laminates & sheets, bags and containersbags and containers  AutomobilesAutomobiles  MedicalMedical  Sutures, ligament replacements, controlledSutures, ligament replacements, controlled drug release mechanisms, arterial grafts…drug release mechanisms, arterial grafts…  HouseholdHousehold  Disposable razors, utensils, diapers, feminineDisposable razors, utensils, diapers, feminine hygiene products, containers…hygiene products, containers…
  • 4.
  • 5.
  • 6. Production of BioplasticProduction of Bioplastic BacteriaBacteria Physical stress ( PH, temperature)Physical stress ( PH, temperature) PHB synthesisPHB synthesis PHB recovery from bacterial extractPHB recovery from bacterial extract Purification of PHBPurification of PHB
  • 7. PHA BiosynthesisPHA Biosynthesis  It consist three enzymatic reactionIt consist three enzymatic reaction  Contestation of two acetyl coenzyme A intoContestation of two acetyl coenzyme A into acetoacetyl-coA byacetoacetyl-coA by ββ-ketoacyl CoA thiolase (phb A)-ketoacyl CoA thiolase (phb A)  Reduction of actoactyle CoA to ®-3-hydroxybutyryl-Reduction of actoactyle CoA to ®-3-hydroxybutyryl- CoA by NADPH dependent acetoacetyl CoACoA by NADPH dependent acetoacetyl CoA dehydrogenase (phb B)dehydrogenase (phb B)  ®-3-hydroxybutyryl CoA monomer polymerized®-3-hydroxybutyryl CoA monomer polymerized into PHB by P(3HB) polymerase (phbC)into PHB by P(3HB) polymerase (phbC) (huisman(huisman et alet al., 1989)., 1989)
  • 8. Bioplastic PropertiesBioplastic Properties  Some are stiff and brittleSome are stiff and brittle  Crystalline structureCrystalline structure  rigidityrigidity  Degrades at 185°CDegrades at 185°C  Moisture resistant, water insoluble, opticallyMoisture resistant, water insoluble, optically pure, impermeable to oxygenpure, impermeable to oxygen  Must maintain stability during manufacture andMust maintain stability during manufacture and use but degrade rapidly when disposed of oruse but degrade rapidly when disposed of or recycledrecycled
  • 9. ConclusionsConclusions  Need for bioplastic optimization:Need for bioplastic optimization:  Economically feasible to produceEconomically feasible to produce  Cost appealing to consumersCost appealing to consumers  Question:Question: How many of you would be willing to pay 2-3How many of you would be willing to pay 2-3 times more for plastic products because theytimes more for plastic products because they were “environmentally friendly”?were “environmentally friendly”?
  • 10.  Rahul Negi, Dr Vikas Babu “Scientist C”Rahul Negi, Dr Vikas Babu “Scientist C”  Department of Biotechnology Graphic EraDepartment of Biotechnology Graphic Era University DehradunUniversity Dehradun
  • 11. Abstract-Abstract- Polyhydroxybutyrates (PHBs) are a potential alternative to thePolyhydroxybutyrates (PHBs) are a potential alternative to the environment polluting non degradable plastics. These compounds areenvironment polluting non degradable plastics. These compounds are non- toxic, biodegradable, highly crystalline, optically active,non- toxic, biodegradable, highly crystalline, optically active, isotactic and insoluble polymers. PHBs are storage compoundsisotactic and insoluble polymers. PHBs are storage compounds produced by variety of micro organisms under nutrient stressproduced by variety of micro organisms under nutrient stress conditions. About 75 genera of gram positive and gram negativeconditions. About 75 genera of gram positive and gram negative bacteria are known to produce PHBs when grown in carbon andbacteria are known to produce PHBs when grown in carbon and nitrogen limited media. Some important examples of PHB producingnitrogen limited media. Some important examples of PHB producing bacteria arebacteria are Ralstonia eutrophaRalstonia eutropha,, Alcaligenes eutrophus, PseudomonasAlcaligenes eutrophus, Pseudomonas pseudomallei, E. coli, Halomonas campisalispseudomallei, E. coli, Halomonas campisalis etc.etc. The major challenge is to make the extraction process economicallyThe major challenge is to make the extraction process economically viable to be used on an industrial scale that can compete with theviable to be used on an industrial scale that can compete with the cheap prices of the synthetic non biodegradable plastics such ascheap prices of the synthetic non biodegradable plastics such as polyethylens. The by-products formed during PHB formation likepolyethylens. The by-products formed during PHB formation like HAME (hydroxy alkanoate methyl ester) that have alternative fuelHAME (hydroxy alkanoate methyl ester) that have alternative fuel applications can be used to enhance the industrial application andapplications can be used to enhance the industrial application and economic feasibility of these compounds.economic feasibility of these compounds.