3d printing is a new technique in pharma sector which shows a wide range of advantages like personalised medicine, one step process, reduce errors of production.
it has various methods which are shown in presentation
3D Printing - shaping the future of formulation developmentMerck Life Sciences
Watch the presentation of this webinar here: https://bit.ly/3pLd4cq
In our webinar we will take you on a journey to discover the latest trends in additive manufacturing for developing pharmaceutical dosage forms. We provide you a fundamental understanding of the different technologies currently evaluated in pharmaceutical industry. A clear definition of the key aspects of the individual technologies ensure a strong basis for future implementation of this technology in pharmaceutical manufacturing.
We will review the existing technologies and outline the potential for the targeted application.
An important aspect will be the filament-based 3D printing technology.
A case study will be presented on how a hot melt extrusion process can be optimized for filament production. Material properties as well as down-stream equipment drive a successful implementation.
We will also present a novel melt-based 3D printing approach, which can directly create the final dosage form out of powder. A drop-based deposition of the polymer melt ensures a new level of accuracy and individualization when it comes to the finishing of the final form.
In this webinar, you will learn:
• Additive manufacturing: Basics and potential application fields
• Overview of existing 3D printing approaches and their relevance in Pharmaceutical Industry
• Background and advantages of extrusion-based 3D printing
• Requirements for FDM (fused deposition modeling) based technologies
• New advanced technical approaches for direct shaping of 3D printed tablets
3D Printing - shaping the future of formulation developmentMilliporeSigma
Watch the presentation of this webinar here: https://bit.ly/3pLd4cq
In our webinar we will take you on a journey to discover the latest trends in additive manufacturing for developing pharmaceutical dosage forms. We provide you a fundamental understanding of the different technologies currently evaluated in pharmaceutical industry. A clear definition of the key aspects of the individual technologies ensure a strong basis for future implementation of this technology in pharmaceutical manufacturing.
We will review the existing technologies and outline the potential for the targeted application.
An important aspect will be the filament-based 3D printing technology.
A case study will be presented on how a hot melt extrusion process can be optimized for filament production. Material properties as well as down-stream equipment drive a successful implementation.
We will also present a novel melt-based 3D printing approach, which can directly create the final dosage form out of powder. A drop-based deposition of the polymer melt ensures a new level of accuracy and individualization when it comes to the finishing of the final form.
In this webinar, you will learn:
• Additive manufacturing: Basics and potential application fields
• Overview of existing 3D printing approaches and their relevance in Pharmaceutical Industry
• Background and advantages of extrusion-based 3D printing
• Requirements for FDM (fused deposition modeling) based technologies
• New advanced technical approaches for direct shaping of 3D printed tablets
3d printing is a new technique in pharma sector which shows a wide range of advantages like personalised medicine, one step process, reduce errors of production.
it has various methods which are shown in presentation
3D Printing - shaping the future of formulation developmentMerck Life Sciences
Watch the presentation of this webinar here: https://bit.ly/3pLd4cq
In our webinar we will take you on a journey to discover the latest trends in additive manufacturing for developing pharmaceutical dosage forms. We provide you a fundamental understanding of the different technologies currently evaluated in pharmaceutical industry. A clear definition of the key aspects of the individual technologies ensure a strong basis for future implementation of this technology in pharmaceutical manufacturing.
We will review the existing technologies and outline the potential for the targeted application.
An important aspect will be the filament-based 3D printing technology.
A case study will be presented on how a hot melt extrusion process can be optimized for filament production. Material properties as well as down-stream equipment drive a successful implementation.
We will also present a novel melt-based 3D printing approach, which can directly create the final dosage form out of powder. A drop-based deposition of the polymer melt ensures a new level of accuracy and individualization when it comes to the finishing of the final form.
In this webinar, you will learn:
• Additive manufacturing: Basics and potential application fields
• Overview of existing 3D printing approaches and their relevance in Pharmaceutical Industry
• Background and advantages of extrusion-based 3D printing
• Requirements for FDM (fused deposition modeling) based technologies
• New advanced technical approaches for direct shaping of 3D printed tablets
3D Printing - shaping the future of formulation developmentMilliporeSigma
Watch the presentation of this webinar here: https://bit.ly/3pLd4cq
In our webinar we will take you on a journey to discover the latest trends in additive manufacturing for developing pharmaceutical dosage forms. We provide you a fundamental understanding of the different technologies currently evaluated in pharmaceutical industry. A clear definition of the key aspects of the individual technologies ensure a strong basis for future implementation of this technology in pharmaceutical manufacturing.
We will review the existing technologies and outline the potential for the targeted application.
An important aspect will be the filament-based 3D printing technology.
A case study will be presented on how a hot melt extrusion process can be optimized for filament production. Material properties as well as down-stream equipment drive a successful implementation.
We will also present a novel melt-based 3D printing approach, which can directly create the final dosage form out of powder. A drop-based deposition of the polymer melt ensures a new level of accuracy and individualization when it comes to the finishing of the final form.
In this webinar, you will learn:
• Additive manufacturing: Basics and potential application fields
• Overview of existing 3D printing approaches and their relevance in Pharmaceutical Industry
• Background and advantages of extrusion-based 3D printing
• Requirements for FDM (fused deposition modeling) based technologies
• New advanced technical approaches for direct shaping of 3D printed tablets
Advanced Additive Manufacturing by Sumanth A.pptxSumanth A
Advanced additive manufacturing, also known as advanced 3D printing,
refers to a set of advanced techniques and technologies that go beyond traditional
3D printing methods. It incorporates new materials, designs, and technologies that
allow for greater customization, complexity, and efficiency in the production of
three-dimensional objects.
Latest advancements of melt based 3D printing technologies for oral drug deli...MilliporeSigma
Watch the presentation of this webinar here: https://bit.ly/3A2WcH4
The application of polymer excipients in 3D printing manufacturing is usually limited due to the concerns of filament strength, high processing temperature and large scale manufacturing.
Latest technology developments are targeting a direct melt deposition to simplify the process and enable a constant and efficient process. Two different processing approaches will be presented:
The advanced melt drop deposition, where individual three dimensional geometries can be created by depostition of polymer droplets and the MED® 3D printing technology which allows by precise layer-by-layer deposition to produce objects with well-designed geometric structures.
In this webinar, you will learn:
• Latest advancements of melt based 3D printing approaches
• Application examples for the individual technologies
• Deep dive in the MED® 3D printing technology to design dedicated drug release profiles
Presented by:
Dr. Thomas Kipping, Head of Drug Carriers
Dr. Xianghao Zuo, Deputy Director of R&D, Triastek
Latest advancements of melt based 3D printing technologies for oral drug deli...Merck Life Sciences
Watch the presentation of this webinar here: https://bit.ly/3A2WcH4
The application of polymer excipients in 3D printing manufacturing is usually limited due to the concerns of filament strength, high processing temperature and large scale manufacturing.
Latest technology developments are targeting a direct melt deposition to simplify the process and enable a constant and efficient process. Two different processing approaches will be presented:
The advanced melt drop deposition, where individual three dimensional geometries can be created by depostition of polymer droplets and the MED® 3D printing technology which allows by precise layer-by-layer deposition to produce objects with well-designed geometric structures.
In this webinar, you will learn:
• Latest advancements of melt based 3D printing approaches
• Application examples for the individual technologies
• Deep dive in the MED® 3D printing technology to design dedicated drug release profiles
Presented by:
Dr. Thomas Kipping, Head of Drug Carriers
Dr. Xianghao Zuo, Deputy Director of R&D, Triastek
APPROACHE OF 3D PRINTING IN CURRENT DRUG DELIVERY
INTRODUCTION to 3d printing
How it is coming in pharmacy or in health care.
How 3d printing providing the new ways to formulate new dosage form of medicine. ADDITIVE MANUFACTURING, RAPID PROTOTYPING
HISTORY OF 3D PRINTING IN PHARMACY
ADVANTAGES of 3d printing
DISADVANTAGES of 3d printing
BASIC WORK PRINCIPLE of 3D modelling
PROCESS of 3d printing
TYPES OF PRINTERS:
PRINTING BASED INKJET SYSTEM
Continuous inkjet printing (CIJ) and Drop on demand printing (DOD).
BINDER APLIED JETTING PRINTING
FUSED DEPOSITION MODELLING
HOT MELT EXTRUSION
STEREOLITHOGRAPHY
SELECTIVE LASER SINTERING
FORMULATION OF DRUG DOSAGE FORM
3D PRINING USES IN PHARMACY
PERSONALIZED DRUG:
APRECIA ZIP DOSE
Personalized 3D printed medicine
CHALLENGES OF 3D PRINTING
SELECTION OF RAW MATERIAL
Nozzle mechanism
Mechanical resistance
Surface Imperfection.
This presentation from JEC World 2019 composites trade show and conference highlights different forms of graphene that are used in composites applications with examples of actual products.
Course Objectives:
Students undergoing this course would
Understand different methods of 3D Printing.
Gain knowledge about simulation of FDM process
Estimate time and material required for manufacturing a 3D component
Course Outcomes:
Upon the successful completion of course, students will be able to
Explain different types of 3d Printing techniques
Identify parameters for powder binding and jetting process
Determine effective use of ABS material for 3D Printing
Apply principles of mathematics to evaluate the volume of material require.
Module 1:
Introduction to Prototyping, Working of 3D Printer, Types of 3D printing Machines:
Exp 1: Modelling of Engineering component and conversion of STL format.
Exp 2: Slicing of STL file and study of effect of process parameter like layer thickness,
Orientation and infill on build time using software.
Exercise 1 : Component-1
Exercise 2 : Component-2
Module 2:
Exp 1 : 3D Printing of modeled component by varying layer thickness.
Exp 2 : 3D Printing of modeled component by varying orientation.
Exp 3: 3D Printing of modeled component by varying infill.
Module 3:
Study on effect of different materials like ABS, PLA, Resin etc, and dimensional accuracy.
Module 4:
Identifying the defects in 3D Printed components.
Module 5
Exp1: Modelling of component using 3D Scanner of real life object of unknown dimension
in reverse engineering.
Exp 2: 3D Printing of above modeled component.
Its about the 3D printing technologies to fabricate 3D structures. Short overview of different technologies their advantage and disadvantage with each other, materials choice for certain printing.
Advanced Additive Manufacturing by Sumanth A.pptxSumanth A
Advanced additive manufacturing, also known as advanced 3D printing,
refers to a set of advanced techniques and technologies that go beyond traditional
3D printing methods. It incorporates new materials, designs, and technologies that
allow for greater customization, complexity, and efficiency in the production of
three-dimensional objects.
Latest advancements of melt based 3D printing technologies for oral drug deli...MilliporeSigma
Watch the presentation of this webinar here: https://bit.ly/3A2WcH4
The application of polymer excipients in 3D printing manufacturing is usually limited due to the concerns of filament strength, high processing temperature and large scale manufacturing.
Latest technology developments are targeting a direct melt deposition to simplify the process and enable a constant and efficient process. Two different processing approaches will be presented:
The advanced melt drop deposition, where individual three dimensional geometries can be created by depostition of polymer droplets and the MED® 3D printing technology which allows by precise layer-by-layer deposition to produce objects with well-designed geometric structures.
In this webinar, you will learn:
• Latest advancements of melt based 3D printing approaches
• Application examples for the individual technologies
• Deep dive in the MED® 3D printing technology to design dedicated drug release profiles
Presented by:
Dr. Thomas Kipping, Head of Drug Carriers
Dr. Xianghao Zuo, Deputy Director of R&D, Triastek
Latest advancements of melt based 3D printing technologies for oral drug deli...Merck Life Sciences
Watch the presentation of this webinar here: https://bit.ly/3A2WcH4
The application of polymer excipients in 3D printing manufacturing is usually limited due to the concerns of filament strength, high processing temperature and large scale manufacturing.
Latest technology developments are targeting a direct melt deposition to simplify the process and enable a constant and efficient process. Two different processing approaches will be presented:
The advanced melt drop deposition, where individual three dimensional geometries can be created by depostition of polymer droplets and the MED® 3D printing technology which allows by precise layer-by-layer deposition to produce objects with well-designed geometric structures.
In this webinar, you will learn:
• Latest advancements of melt based 3D printing approaches
• Application examples for the individual technologies
• Deep dive in the MED® 3D printing technology to design dedicated drug release profiles
Presented by:
Dr. Thomas Kipping, Head of Drug Carriers
Dr. Xianghao Zuo, Deputy Director of R&D, Triastek
APPROACHE OF 3D PRINTING IN CURRENT DRUG DELIVERY
INTRODUCTION to 3d printing
How it is coming in pharmacy or in health care.
How 3d printing providing the new ways to formulate new dosage form of medicine. ADDITIVE MANUFACTURING, RAPID PROTOTYPING
HISTORY OF 3D PRINTING IN PHARMACY
ADVANTAGES of 3d printing
DISADVANTAGES of 3d printing
BASIC WORK PRINCIPLE of 3D modelling
PROCESS of 3d printing
TYPES OF PRINTERS:
PRINTING BASED INKJET SYSTEM
Continuous inkjet printing (CIJ) and Drop on demand printing (DOD).
BINDER APLIED JETTING PRINTING
FUSED DEPOSITION MODELLING
HOT MELT EXTRUSION
STEREOLITHOGRAPHY
SELECTIVE LASER SINTERING
FORMULATION OF DRUG DOSAGE FORM
3D PRINING USES IN PHARMACY
PERSONALIZED DRUG:
APRECIA ZIP DOSE
Personalized 3D printed medicine
CHALLENGES OF 3D PRINTING
SELECTION OF RAW MATERIAL
Nozzle mechanism
Mechanical resistance
Surface Imperfection.
This presentation from JEC World 2019 composites trade show and conference highlights different forms of graphene that are used in composites applications with examples of actual products.
Course Objectives:
Students undergoing this course would
Understand different methods of 3D Printing.
Gain knowledge about simulation of FDM process
Estimate time and material required for manufacturing a 3D component
Course Outcomes:
Upon the successful completion of course, students will be able to
Explain different types of 3d Printing techniques
Identify parameters for powder binding and jetting process
Determine effective use of ABS material for 3D Printing
Apply principles of mathematics to evaluate the volume of material require.
Module 1:
Introduction to Prototyping, Working of 3D Printer, Types of 3D printing Machines:
Exp 1: Modelling of Engineering component and conversion of STL format.
Exp 2: Slicing of STL file and study of effect of process parameter like layer thickness,
Orientation and infill on build time using software.
Exercise 1 : Component-1
Exercise 2 : Component-2
Module 2:
Exp 1 : 3D Printing of modeled component by varying layer thickness.
Exp 2 : 3D Printing of modeled component by varying orientation.
Exp 3: 3D Printing of modeled component by varying infill.
Module 3:
Study on effect of different materials like ABS, PLA, Resin etc, and dimensional accuracy.
Module 4:
Identifying the defects in 3D Printed components.
Module 5
Exp1: Modelling of component using 3D Scanner of real life object of unknown dimension
in reverse engineering.
Exp 2: 3D Printing of above modeled component.
Its about the 3D printing technologies to fabricate 3D structures. Short overview of different technologies their advantage and disadvantage with each other, materials choice for certain printing.
1. Junhua Wei
10932 Caminito Alvarez, San Diego, CA, 92126 • (312) 618-9755 • junhua.austin.wei@gmail.com
SUMMARY OF QUALIFICATIONS:
3 years of working experience in additive manufacturing: fused deposition modeling (FDM), syringe dispersing, and screen printing;
Excellent skills in designing and printing devices: Organic LED (OLED), strain sensor, thermoelectric generator (TEG), circuitry;
Deep understanding of the physics and chemistry of polymers and the dispersion of fillers;
Expert in preparing, printing, and solidifying liquid materials: liquid metal, solution, ionic, photo- and thermal curable ink/gel/paste;
EXPERIENCE:
Contractor, Graphene 3D lab Inc., Calverton, NY 07/2015 to now/2015
Building 3D Printers for solid/liquid materials
A 3D printer was designed and built with an open platform to hold exchangeable deposition units and adapters were designed
and built to connect and control the spray deposition, syringe dispersing, inkjet printing, and FDM units by the printer;
Commercial 3D printers were attached with syringe dispersing units to print both solid filament and liquid materials in sequence;
Printing electronic devices
Ablinking cubic was designed and fabricated by soldering LED lights, batteries, and microcontroller onto a printed 3D circuitry;
An OLED was printed layer-by-layer using ultrasonic spraying, syringe dispersing, vacuum pickup, and FDM units;
A strain sensor, its resistance changed with the bending angle, was printed by dispersing silver ink onto a FDM printed sheet;
Preparing Conductive inks
High conductive and stable silver/polymer solution was tested by the adhesion tape and used to print 2D patterns;
AUV curable ink was prepared by mixing silver nanoparticles with thermal curable epoxy resin to print 3D electronic circuitry;
Research Assistant, Texas Tech University, Lubbock, TX 08/2011 to 06/2015
Printing Flexible TEGs
A syringe dispersing 3D printer was built to fabricate TEGs by printing PEDOT and graphene inks onto a polyimide film;
The graphene ink was prepared by dispersing nitrogen doped graphene and surfactant in solvent and cured by oven burning;
The wettability of the polyimide film was optimized for printing by using plasma and chemical treatment;
3D Printing Meniscus Substitutes
A syringe dispersing 3D printer with a heating pad wrapped steel syringe was built to print thermal sensitive hydrogel;
A meniscus shaped hydrogel with high shape fidelity and compatible toughness was printed as the substitute;
The hydrogel formulation and the printing parameters were optimized according to the ink’s rheological conditions;
Reinforcing Thermoplastic Filaments by Carbon Fiber
By using thermoplastic filament reinforced by carbon fiber, mechanically improved structures were printed by FDM;
Better filler-polymer interaction was achieved by surface oxidation of carbon fiber using chemical and ionic method;
Thermoplastic was integrated with carbon fiber by solvent mixing and formed into filament by using an extruder;
Enhancing Rubber by Graphene
Rubber was integrated with chemical modified graphene during thermal curing by covalently polymer-filler interaction;
Rubber/graphene composites with better mechanical and barrier properties was produced by solvent than mechanical mixing.
TECHNICAL SKILLS:
Applications: Arduino, MATLAB, Simplified 3D, Kisslicer, Pronterface, gcode, Solidworks, AutoCAD, Inventor;
Characterization tools: HPLC, DLS, ODR, TEM, SEM, XRD, XPS, FTIR, AFM, TEM, DSC, TGA, and DMA;
Polymer composites preparation: solvent mixing, roll mill mixing, rheometer mixing, extruder, and melt mixing;
Thin film growth: spray coating, sputter coating, thermal evaporation, and spin coating.
EDUCATION:
Texas Tech University, Lubbock, TX Ph.D in Mechanical Engineering 08/2015
Illinois Institute of Technology, Chicago, IL ME in Mechanical Engineering 05/2011
Beihang University, Beijing, China BE in Mechanical Engineering 07/2009