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11th Euro Tissue Science and Regeneration Congress, will be organized around the theme “Latest Scientific Advances in Tissue science and Regenerative Medicine”

TISSUE REGEN 2020 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in TISSUE REGEN 2020

Submit your abstract to any of the mentioned tracks.

Register now for the conference by choosing an appropriate package suitable to you.

Tissue is a cellular organisational level between cells and a complete organ. A tissue is an ensemble of similar cells and their extracellular matrix from the same origin that together carry out a specific function. Organs are then formed by the functional grouping together of multiple tissues. Tissue used for research can be called many different things: specimen, biological samples or human biological material. All of these terms refer to a small piece or sample of tissue or fluid and are used interchangeably. When researchers say tissue they can mean blood, urine, saliva, feces, fluid from the spine and brain, organ tissue, bone marrow, tumor tissue, lymph nodes, lymphatic fluid, and many others.

 

Regenerative Medicine goes for helping the body to shape new tissue to replace lost ones.  This will give curative treatment to conditions .The human body has an endogenous arrangement of recovery through foundational microorganisms, where undeveloped cells are discovered nearly in every kind of tissue. The thought is that upgrading of capacity is best proficient by these cells. Regenerative prescription involves the utilization of tissue designing and undifferentiated organism innovation.

 

  • Track 2-1Ethics and applications of Regenerative Medicine
  • Track 2-2Translational Medicine in Cancer Pharmacology
  • Track 2-3Biomedical Engineering Techniques & Biomedicine
  • Track 2-4Biomarkers in Translational Medicine
  • Track 2-5Cardiovascular Regenerative Medicine
  • Track 2-6Immunology and Regenerative Medicine
  • Track 2-7Clinical Trials and Regenerative Medicine
  • Track 2-8Global market scenario of the Regenerative Medicine

Cellular therapy (CT) is the transplantation of human cells to replace or repair damaged tissue and/or cells. With new technologies, innovative products, and limitless imagination, many different types of cells may be used as part of a therapy or treatment for a variety of diseases and conditions.  Some of the cells that may be used include hematopoietic (blood-forming) stem cells (HSC), skeletal muscle stem cells, mesenchymal stem cells, lymphocytes, dendritic cells, and pancreatic islet cells. It is used to treat a variety of blood cancers and hematologic conditions.

Gene therapy is the introduction, removal, or change in the content of a person’s genetic code with the goal of treating a disease, and hereditary diseases in which a defective mutant allele is replaced with a functional one. The transferred genetic material changes how a single protein or group of proteins is produced by the cell. Gene therapy can be used to reduce levels of a disease-causing version of a protein, increase production of disease-fighting proteins, or to produce new/modified proteins. 

 

Stem cell therapy is the use of stem cells to treat disease. It is the treatment of various disorders, non-serious to life threatening, by using stem cells. These stem cells can be procured from a lot of different sources and used to potentially treat more than 80 disorders, including neuromuscular and degenerative disorders. Bone marrow transplantation is the most used stem-cell therapy, but some therapies derived from Umbilical cord blood are also in use. Research is proceeding to develop various sources for stem cells and to put on stem-cell treatments for Neurogenerative disease and conditions such as diabetes, heart disease, and other conditions. Stem-cell therapy has become controversial following developments such as the ability of scientists to isolate and culture embryonic stem cell to create stem cells using somatic nuclear transfer and their use of techniques to create Induced pluripotent stem cell.

 

  • Track 4-1Embryonic stem cells
  • Track 4-2Non-Embryonic stem cells
  • Track 4-3Tissue-specific stem cells
  • Track 4-4Mesenchymal stem cells
  • Track 4-5Induced pluripotent stem cells

Biomedical engineering is the application of the principles and problem-solving techniques of engineering to biology and medicine. This is evident throughout healthcare, from diagnosis and analysis to treatment and recovery, and has entered the public conscience though the proliferation of implantable medical devices, such as pacemakers and artificial hips, to more futuristic technologies such as stem cell engineering and the 3-D printing of biological organs. Biomedical engineering prominence's on the developments that surge the human health and health care at all levels. Biomedical Engineering also referred to as Bioengineering, BioMed or BME, is a multidisciplinary STEM field that combines biology and engineering, applying engineering principles and materials to medicine and healthcare.

 

Biomaterials are being used for the healthcare applications from ancient times. But subsequent evolution has made them more versatile and has increased their utility. Biomaterials have revolutionized the areas like bioengineering and tissue engineering for the development of novel strategies to combat life threatening diseases. Together with biomaterials, stem cell technology is also being used to improve the existing healthcare facilities. These concepts and technologies are being used for the treatment of different diseases like cardiac failure, fractures, deep skin injuries, etc.

Tissue Engineering is addressed to create functional tissues which include cells, scaffolds, and bioactive molecules. It is the development of biological substitutes that maintains, improves or restores tissue functions resulting in sidestepping the problems associated with tissue damage. In the present, it is treated with transplants, mechanical devices or surgical reconstructions, these three medical therapies have saved and improved countless patients’ lives with few associated problems. For example, transplantation in organs shows limitations such as transplant rejections and lack of donor to cover all the worldwide demand. Mechanical devices are not capable of accomplishing all the functions related to the tissue and also the prevention of progressive deterioration in patients.  Thus it has informed that Tissue Engineering arises from the need to provide more definitive solutions to tissue repairs.

 

  • Track 6-1Bio-materials in Tissue Engineering
  • Track 6-2Tissue Microarray
  • Track 6-3Biomimetic materials
  • Track 6-4Scaffold Designs
  • Track 6-5Surface ligands and Molecular architecture
  • Track 6-6Porous Scaffolds
  • Track 6-7Biomaterials for Drug delivery
  • Track 6-8Bone Tissue Engineering
  • Track 6-9Engineering in Plastic Surgery

Artificial organs that have been designed to be used as an alternative to transplants, which are always in short supply. Failure of human's vital organs leads to death unless a replacement is found. The replacement can either be a transplant from another person or an artificial man-made organ. Use of transplants has the disadvantage of a limited supply and problems with immunorejection. Tissue Engineers started working on artificial organs for transplantation into the patients. Tissue engineering based tissues could allow to regenerate the whole organ or even to produce several organs for the purpose of grafting’s. Recently researchers are working on this field to develop and provide the tissue engineered organs and tissues to overcome the scarcity of the organs for transplants. 

 

Stem cells are feasible to design and test interventions to slow aging and improve health and longevity. It is believed that stem cell failure contributes to a decline in health during aging; so the development of effective methods to induce and differentiate pluripotent stem cells via cell replacement therapy provides an exciting avenue for the treatment of degenerative age-related diseases. It is believed that the regenerative potential of these cells is due to their high differentiation and proliferation capabilities, paracrine activity and immune privilege. Therefore, the stem cells can be used for cell replacement therapy as a therapeutic intervention aimed at mitigating the effects of aging.

 

  • Track 8-1Reverse Cellular Aging
  • Track 8-2Protection against Brain Aging
  • Track 8-3Stem Cell Therapies Produce Rejuvenation
  • Track 8-4Applications of Rejuvenation

Tissue Engineering has evoked new hopes for the cure of failure of Organs and loss tissue by creating functional substitutes in laboratory. TE provides new technology platforms to study the mechanism of angiogenesis and tumour cell growth and potentially tumour spreading in cancer research. The synthesis of TE with innovative methods of molecular biology and stem-cell technology may help investigate and potentially modulate principal phenomena of tumour growth and spreading, as well as tumour-related angiogenesis. TE can be applied to cure the cancer in Breast, Skin, Melanoma, Bone, Prostate, Liver and brain.

  • Track 9-1Surgery
  • Track 9-2Radiation Therapy
  • Track 9-3Chemotherapy
  • Track 9-4Immunotherapy
  • Track 9-5Targeted Therapy
  • Track 9-6Hormone Therapy
  • Track 9-7Stem Cell Transplant
  • Track 9-8Precision Medicine

Wound is an injury involving an external or internal break in body tissue, usually involving the skin. It occurs when the skin is broken or damaged because of injury. Causes of injury may be the result of mechanical, chemical, electrical, thermal, or nuclear sources. The skin can be damaged in a variety of ways depending upon the mechanism of injury. Wounds fall into two broad categories: open or closed. In a closed wound, tissue damage and bleeding occur under the surface of the skin. Examples of closed wounds include bruises. An open wound involves a break in the skin that leaves the internal tissue exposed. Open wounds may result from falls, blunt trauma, and surgery.

 

  • Track 10-1Abrasion
  • Track 10-2Laceration
  • Track 10-3Avulsion
  • Track 10-4Puncture
  • Track 10-5Incision

Bio banking  is the process of storage of biological samples that can be a piece of human tissue taken from a healthy or a diseased part of the body, it can also be a sample of bodily fluid such as blood, urine or saliva. Tissue banking is the activity of processing, storage, and distribution of transplantable human tissues. Tissues retrieved from the human body are used to repair and or replace the diseased or lost tissues of living human body and have saved many precious lives. The common tissues used are cornea, skin, bones, cartilage, joints, heart valves, fascia, tendons and a human cadaver.

 

  • Track 11-1Organ Donation
  • Track 11-2Clinical application of banked tissue
  • Track 11-3Trends in Biobanking and Preanalytics

Regenerative rehabilitation is the values as of rehabilitation and regenerative medicine, with the ultimate goal of developing innovative and operative methods that promote the restoration of function through tissue regeneration and repair. In order to provide an optimal microenvironment for healing tissues, physical therapists use directed therapy to maximize the productivity of the body's innate healing processes. Rehabilitation coupled with regenerative medicine surgeries has shown improved outcomes for tissue regeneration. With innovative findings from medical researchers in tissue engineering and cellular therapies, physical therapies play an important role in translating these findings.

 

  • Track 12-1Cardiac Rehabilitation Practice
  • Track 12-2Clinical Grade Biotherapies
  • Track 12-3Physical Therapy

Regenerative rehabilitation is the values as of rehabilitation and regenerative medicine, with the ultimate goal of developing innovative and operative methods that promote the restoration of function through tissue regeneration and repair. In order to provide an optimal microenvironment for healing tissues, physical therapists use directed therapy to maximize the productivity of the body's innate healing processes. Rehabilitation coupled with regenerative medicine surgeries has shown improved outcomes for tissue regeneration. With innovative findings from medical researchers in tissue engineering and cellular therapies, physical therapies play an important role in translating these findings.