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Volume 7, Issue 6 (Suppl)

J Biotechnol Biomater, an open access journal

ISSN: 2155-952X

World Biotechnology 2017

December 04-05, 2017

2

nd

World Biotechnology Congress

December 04-05, 2017 | Sao Paulo, Brazil

BioCAE: A multiscale framework for complex biological systems and biofabrication of tissues and

organs

Janaina de A Dernowsek

1

, Maria Bolina Kersanach

2

, Rodrigo Alvarenga Rezende

3

, Pedro Yoshito Noritomi

1

and

Jorge Vicente Lopes da Silva

1

1

Centro de Tecnologia da Informação Renato Archer, Brazil

2

University of Campinas, Brazil

3

Federal University of Campina Grande, Brazil

Statement of Purpose

: 3D bioprinting process can be adapted to produce tissues in a variety of formats, structural complexities, such

as material types, cell types, growth factors and differentiation, extracellular matrix composition, mechanical properties, macro and

microvasculature and technical challenges associated with the creation of biomodels that mimic real vascularized tissues. In recent

years,

in silico

approaches have been practiced in several fields, and offers new opportunities for medical discovery and investigation,

helping and improving the storage, organization, and classification of the large data sets of digital biological information that is

available. The purpose of this work is to present different approaches to predict the development and behavior of several biological

processes, such as molecular networks, gene interactions, diffusion, cell differentiation, tissue and organ development, beyond to

provide new perspectives and strategies in the biofabrication of tissues and organs.

Methods:

A range of multiscale strategies was employed to develop a BioCAE for biofabrication of tissues and organs. Here we

describe some approaches in steps, which may be part of the BioCAE, thereby preventing a significant amount of trial and error

experiments in laboratories.

In silico

study focuses on the biological process of the angiogenesis of an aggregate of endothelial cells.

The software CompuCell3D (CC3D) was used to mimic angiogenesis

in silico

. CC3D is an open-source environment for multi-cell

and single-cell-based modeling of tissues, organs, and organisms.

Results &Conclusions:

The emergence of integrated platforms on different systems levels to understand complex biological processes

will enable the prediction and creation of biofabricated biological structures. We emphasize here that BioCAE is work-in-progress

and there are a vast number of possible additions to the multiscale models for the biofabrication.

Biography

Janaina de A Dernowsek is currently working on a Postdoc Scholarship at the Center for Information Technology Renato Archer (CTI), Campinas, Brazil. She has

obtained the MSc and PhD degrees in Genetics from the University of São Paulo (USP). During her PhD studies (2010–2014), she acquired knowledge and skills in

posttranscriptional interactions between the miRNAs and mRNAs during the osteoblastic differentiation of human immature dental pulp stem cells. Currently, she is involved

in the Biofabrication group at CTI Renato Archer working with several steps of biofabrication, mainly on the multiscale representation of tissue and organs for a blueprint.

This hybrid 3D blueprint will contain all the necessary information for all bioprinting steps.

janaina.dernowsek@cti.gov.br

Janaina de A Dernowsek et al., J Biotechnol Biomater 2017, 7:6 (Suppl)

DOI: 10.4172/2155-952X-C1-085