Track1: Bio compatible Material

Biocompatibility is described because the capability of a fabric to carry out with the precise host reaction in a selected utility In a simple sense, substances are biocompatible after they exert the anticipated beneficial tissue reaction and clinically relevant overall performance. The other additives of biocompatibility are cytotoxicity, genotoxicity, mutagenicity, carcinogenicity and immunogenicity. A biomaterial is a substance that has been engineered to interact with organic systems for a medical reason, both a healing (treat, augment, repair, or update a tissue function of the frame) or a diagnostic one. As a technology, bio materials is set fifty years antique.

Track2: Autonomous Self-Assembly

Biological cells routinely reconfigure their form the usage of dynamic signalling and regulatory networks that direct self-assembly strategies in time and space, via molecular additives that sense, process and transmit facts from the environment. A similar strategy could be used to enable lifestyles-like behaviours in artificial materials. Nucleic acid nanotechnology offers a promising route toward this intention via a variety of sensors, common sense and dynamic additives and self-assembling structures. Here, by using harnessing both dynamic and structural DNA nanotechnology, we display dynamic control of the self-meeting of DNA nanotubes—a famous class of programmable DNA nanostructures.

Track3: Biomimicry

Velcro is arguably the most well-known example of biomimicry. When George de Mestral, an engineer, discovered burrs (just like the ones shown below) sticking to both of them, he started walking his dog. He saw that the burrs' adhering properties were the consequence of thousands of tiny hooks when he magnified the images of them. A technical strategy called "biomimicry" aims to put nature's lessons to use. Biomimicry, in the words of Janine Benyus, uses nature as: A model. In order to create ideas or processes that can help solve human issues, it studies the models found in nature and copies them, uses them as inspiration, or both. a level. Designs that visually imitate elements of nature are referred to as biomorphism, whereas biomimetic designs focus on feature.

Track4: 3d Bioprinting Strategies

Complex geometric shapes are abundant in biology. Print techniques to copy those shapes often require contour printing functionality. BAB, together with her human-like robot arm, makes use of six-tiers of motion to uniquely empower you to precisely 3-d print, inject into, and construct complex geometries. Three-D bioprinting has enabled the advent of biomimetic tissue constructs for regenerative medication and in vitro model systems. Large-scale manufacturing of 3-d structures on the micron-scale resolution is accomplished through bioprinting using custom bioinks. Stability and 3D construct compliance play an crucial function in offering cells with biomechanical cues that regulate their conduct and enable in vivo implantation.

Track5: Extrusion

Extrusion is a manner wherein a fabric undergoes plastic deformation by way of the utility of a pressure causing that cloth to flow through an orifice or die. The material adopts the pass-sectional profile of the die and if the material has suitable houses, that shape is retained inside the final extrudate. Extrusion is a manufacturing system that generates profiles having a fixed cross-sectional location by pushing the billet material thru a die. Extrusion is a producing manner that includes forcing base metal through a pre-formed die to create objects with a particular shape and profile. As the metallic passes thru the die, it's shape adjustments to mirror the die's shape. The approaches encompass cloth practise, preprocessing, extruding, cutting, and reforming. The porous products can be obtained after drying, pre-sintering, and sintering of the extruded inexperienced body. It is an powerful manner to produce an extended porous tube with a small diameter.

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Track6: Stereo Litho graphics Based 3d  Bioprinting

Development  of a multi-fabric bio printer for hydrogel stereo lithography. SLA is a mild-primarily based 3D printing approach that may be used to fabricate both mobile and acellular systems. Three-D bioprinting is a technology wherein bioinks, combined with living cells, are published in 3-D to assemble herbal tissue-like three-dimensional systems. Currently, this generation can be utilized in various research areas, along with tissue engineering and new drug improvement There are several distinct bioprinting strategies that can be used to sample biomaterials with cells to create 3D tissue fashions. The most famous strategies consist of 2D and 3-d, inkjet-, laser-, or extrusion-primarily based bioprinting.

Track7: Bio printed Scaffolds

Bio printing is the system of creating 3-dimensional systems which include biomaterials, cells, and biomolecules. The contemporary additive manufacturing strategies, inkjet-, extrusion-, and laser-based totally, create hydrogel systems for mobile encapsulation and  suppor  Bio printing can produce living tissue, bone, blood vessels and, potentially, whole organs for use in clinical techniques, schooling and testing. The cell complexity of the residing frame has ended in three-D bio printing developing extra slowly than mainstream 3-D printing Scaffolds are systems of synthetic or natural substances on which new tissue can be grown to update broken tissue. Such scaffolds might be prepared outdoor the body—as an example, to start developing a bit of bone within the laboratory that would then be surgically implanted

Track8: Bio Ink For 3d Printing

Bio inks comprise living cells and biomaterials that mimic the extracellular matrix surroundings, helping cellular adhesion, proliferation, and differentiation after printing. In contrast to tradtional 3-d printing substances, bio inks have to have: Print temperatures that don't exceed physiological temperatures. In bioprinting, a bio ink is any natural or synthetic polymer decided on for its biocompatible components and favorable rheological homes. These traits temporarily or permanently support dwelling cells to facilitate their adhesion, proliferation and differentiation in the course of maturation.

Track9: Stereo Lithography

Stereo Lithography Apparatus (SLA) is an additive production process and an example of a 3-d printing technique. This technology uses an ultraviolet (UV) laser to turn light-touchy resin (a liquid fabric that becomes difficult when ultraviolet mild is shined on it) into strong 3D gadgets, layer with the aid of layer Stereo lithography (SLA) is an commercial 3-d printing manner used to create idea fashions, beauty prototypes, and complex elements with complicated geometries in as rapid as 1 day. A wide selection of materials, extremely high feature resolutions, and quality floor finishes are feasible with SLA Stereo lithography (SLA) is an commercial 3D printing technique used to create idea fashions, beauty prototypes, and complex elements with problematic geometries in as speedy as 1 day. A huge selection of substances, extraordinarily excessive characteristic resolutions, and quality floor finishes are feasible with SLA

Track10: Allevi  Bio print

Allevi bio printers are 3-d extrusion-primarily based printers that deposit bio inks in a layer-via-layer style from a syringe using compressed air. But even within this one class, there are masses of different bio printing techniques and methods. “3-D Bio printing” or “bio printing” is a form of additive production that uses cells and biomaterials instead of traditional metals and plastics to create 3-d constructs which are purposeful 3D tissues. These biomaterials are referred to as bio inks, and they mimic the composition of our tissues. Bio printing may be implemented to a spread of areas inclusive of but no longer limited to regenerative remedy, drug discovery and improvement, and 3D mobile culture.

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Track11: Extracellular Matrix

Simplify your research desires with accurate and reliable consequences. Order nowadays. Providing the nice-in-elegance lab materials, technologies &services to allow your research. The structure of the extracellular matrix differs in composition between tissue sorts however is basically made of collagen fibers, proteoglycans and multi adhesive matrix proteins which are secreted by means of cells The extracellular matrix (ECM) is an elaborate network composed of an array of multi domain macromolecules organized in a cellular/tissue-precise manner. Components of the ECM hyperlink collectively to  shape a structurally solid composite, contributing to the mechanical properties of tissues. The ECM can be described as the non-mobile aspect of tissues, which has been likened to 'glue'   that binds cells together in connective tissues, in which it's far a chief constituent of the tissue.

Track12: Synthetic Polymers

Synthetic polymers are derived from petroleum oil, and made by means of scientists and engineers. Examples of synthetic polymers include nylon, polyethylene, polyester, Teflon, and epoxy. Natural polymers arise in nature and can be extracted. They are frequently water-based. Although there's a extensive sort of synthetic polymers with wonderful properties due to the variations in the principal chain and facet chains, they're categorised into 4 fundamental categories based on their capability: thermoplastics, thermosets, elastomers, and synthetic fibers. The polymer referred to as Polyethylene is utilized in plastic luggage and film wraps. Polyvinyl Chloride (PVC) is used in siding, pipes, flooring functions. The artificial polymer Polystyrene is used in shelves and in packaging. Polyvinyl acetate is utilized in adhesives and latex paints.

Track13: Bio inks

During the bio printing process, a solution of a biomaterial or a mixture of several biomaterials inside the hydrogel shape, normally encapsulating the preferred mobile types, termed the bio ink, is used for creating tissue constructs. Bio printers paintings in nearly the precise same manner as 3-d printers, with one key difference. Instead of delivering substances including plastic, ceramic, steel or meals, they deposit layers of bio cloth which can encompass dwelling cells, to build complex structures like blood vessels or skin tissue. Bio inks are created through combining cultured cells and various bio compatable substances. Bio inks can then be 3D bio published into practical tissue constructs for drug screening, disorder modeling, and in vitro transplantation.

Track14: 3d Bioprinting Of Skin And Cardiac Tissues

Tissue engineering has superior relatively over recent decades thru the generation of realistic tissue analogs. Traditional approaches based totally on seeding cells into scaffold are restrained of their potential to supply tissues with precise biomimetic residences. Three-dimensional (three-D) bioprinting is one kind of fabrication era used to precisely dispense cell-laden biomaterials for the construction of realistic tissues or organs. Print velocity, print stress, and transferring distance immediately have an impact at the cell viability at some stage in 3-D bioprinting. Researchers combined the cells with bioink so that you can keep their viability. The number one position of bioink is to load cells and offer them with an external useful resource environment just like the extracellular matrix in the course of printing Bio-printing is a novel method, a growing field that is major to the global revolution in scientific sciences that has gained tremendous attention. Bio-printing has the capability for use in producing human engineered tissues like bone and skin which then in the long run may be used in the clinics. In this paper, the three-d bio-printing programs of the engineered human tissues that are to be had (skin and bone) are reviewed.

Track15: Reconstructive Surgery

The disciplines of 3d bio printing and surgical procedure have witnessed incremental ameliorations over the past century. 3d bio printing is a convergence of biology and engineering technology, mirroring the scientific want to provide viable biological tissue thru advancements in printing, regenerative medication and substances science. To outline the cutting-edge and future challenges of 3d bio printing  generation in surgical procedure. Techniques and Applications examines the mixed use of materials, approaches and equipment vital for developing structural tissue constructs for reconstructive functions. Offering a extensive evaluation of the sector, the first set of chapters evaluation the range of biomaterials which may be used to create 3-D-revealed tissue constructs

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The global 3D bio printing market size was valued at USD 1.7 billion in 2021 and is expected to expand at a compound annual growth rate (CAGR) of 15.8% from 2022 to 2030. The growth of this market is attributed to a limited number of organ donors, and an increasingly aging population with chronic respiratory disease. Rising R&D investment, technological advancement, and increasing incidence of chronic diseases are other vitally impacting attributes likely to boost market growth during the forecast period. The 3D printing community has responded to the COVID-19 crisis, pledging to support the production of vital medical equipment for hospitals grappling with this pandemic. 

 

The recent COVID-19 pandemic has taken hold over the globe, with even the healthcare systems being overburdened. Hence, as a reaction to the rising cases of coronavirus, various 3D Bioprinting communities are responding to the worldwide crises by offering their respective skills to ease the burden on the supply chain and governments. As the cases of COVID-19 are increasing day by day, there has been a shortage of materials for the medical professionals as well as for the general public. One of the biggest issues is the lack of availability of test kits for COVID-19. Hence, various 3D bioprinting companies are manufacturing 3D printers and related software on a large scale. For example, Formlabs company based in Massachusetts, U.S. reportedly manufactures 100,000 nasal swabs for COVID-19 testing each day. Due to the ever-increasing cases of COVID-19, the demand for 3D bioprinters is increasing and the global 3D bioprinting market is slated to showcase exponential growth.

Abstract Submission Guidelines

Abstract submissions are welcome for all topics related to the BIO PRINTING-2022. Please see the submission guidelines below.

All accepted abstracts for registered participants will be published in the open access conference support journal and in the conference souvenir.

1. Abstracts can be submitted via the online link ABSTRACT SUBMISSION.

2. Abstracts should be submitted in English and be between 250 and 300 words in length, together with a 60 – 70 word biography of the presenter.

3. Submissions are welcome for all BIO PRINTING -related topics.

4. The author of the presentation must provide the following details: Full name of the author, affiliation details: department, institution/hospital, country, telephone number and email address and photograph.

5. For co-authors, the following details are required: Full names and affiliation details such as department, institute/organization name, country must be included.

6. All abstracts will be reviewed by a review committee approved by the BIO PRINTING Review Committee. The decision of the committee is final.

7. All accepted abstract presenters will be required to register and pay for their attendance at the conference.

Please note that your affiliation and abstract title in the final program and journal will appear exactly as you submitted them. Please follow the guidelines provided for the required format and the acceptance letter does not imply any travel subsidy or bursary.

Next steps:

An email confirmation of the submitted abstract will be sent if the abstract is accepted. If the abstract is accepted, presenters must confirm the presenter(s) and pay the applicable registration fee. Failure to do so may result in your paper being excluded from the BIO PRINTING  program.

How do I complete the registration?

To complete registration, visit the ONLINE REGISTRATION page. The following registration categories are available.

Participants with a university or teaching background should register in the academic category.

Registration options available in this category: Oral Presentation | Poster Presentation | Delegate Registration | Package A (includes your registration and 2 nights accommodation) | Package B (includes your registration and 3 nights accommodation) | Webinar

For professionals, they must register in the "Business" category.

Registration options available in this category: Speaker Registration | Delegate Registration | Package A (includes your registration and 2 nights accommodation) | Package B (includes your registration and 3 nights accommodation) | Advertising | Exhibitor

Participants who are still studying must register in the student category.

Registration options available in this category: Speaker Registration | Poster Presentation | Delegate Registration | Package (includes registration and 2 nights accommodation)

Outside of the above categories, please email: johnhill4557@gmail.com for GROUP REGISTRATION, additional night's accommodation, advance payment of TOKEN, more than one presentation, etc. .... These options are available upon special request and after discussion with the management.