Track 1: Gene and Cell Therapy 

Gene therapy is defined as the transfer of genetic material typically in the form of a carrier or vector, and the uptake of the gene into the proper cells of the body. Cell therapy is defined introduction of cells with the proper function into a patient. In certain programs both gene therapy and cell treatment.   

• Somatic gene therapy
• Prenatal gene therapy
• TCR Therapy
• CAR T cell Therapy

Track 2: Stem Cell and Regenerative Medicine

Stem cell treatment, also known as regenerative medicine, involves employing stem cells or their products to stimulate the repair of sick, dysfunctional, or wounded tissue. It is the next step in organ transplantation, replacing donor organs with cells, which are in short supply. Stem cell are undifferentiated cells found in the embryonic, foetal, and adult phases of life that give rise to differentiated cells that form tissue and organs.

• Unipotent stem cell
• Multipotent stem cell
• Pluripotent stem cell
• Totipotent stem cell

Track 3: Tissue Engineering and 3D Cell Culture

Three-dimensional cell culture is an artificially constructed environment in which biological cells are allowed to grow and interact in all three dimensions. In contrast to 2D environments, 3D cell culture permits cells to grow in all directions in vitro, much as they would in vivo. Cell culture has numerous advantages in the field of biomaterials. It is simple to control and monitor the environment in order to study cell responses to biomaterials and cell–biomaterial interactions. It also eliminates the necessity for animal testing at different phases of biomaterial development.

• Autologous cells
• Allogenic cells
• Reparative cells
• Bio reactive molecules

Track 4: Biomedicine

Modern health care and laboratory diagnostics rely heavily on biomedicine. It encompasses a wide range of scientific and technological approaches, ranging from in vitro diagnostics to in vitro fertilization, from cystic fibrosis molecular mechanisms to HIV virus population dynamics, from molecular interactions to carcinogenesis research, and from a single-nucleotide polymorphism (SNP) to gene therapy..

•  Molecular biology
• Vitro fertilization

Track 5: Clinical Trials on Stem Cell & Gene Therapy

Clinical preliminaries are research concentrates on that as cist specialists with deciding if a quality treatment approach is ok for individuals. Foundational microorganism treatment is the utilization of undifferentiated cells to treat or forestall an infection or condition. This normally appears bone marrow transplantation, however the cells can likewise be gotten from umbilical string blood. Research is in progress to foster different hotspots for undifferentiated organisms as well as to apply undeveloped cell medicines for neurodegenerative sicknesses. Undifferentiated cells from the patient are modified by quality treatment in culture to communicate the applicable useful protein.

• Bone-marrow
• Neurodegenerative
• Undeveloped cell medicine

Track 6: Cell and Organ Regeneration

Cell recovery is the science where the strategy of restoration, recovery and improvement that makes genomes, cells, residing creatures and organic systems. Organ recovery is the method involved with embedding or coordinating man-made material into a human to supplant normal organs or tissues. Its motivation is to reestablish a particular capacity or gathering of related capacities, so the patient might get back to a typical life.

• Genomes
• Organic 

Track 7: Diseases and Stem Cell Treatment

Undifferentiated organisms are at the front of one of the most entrancing and progressive areas of medication today. Specialists perceive that undifferentiated organisms can possibly assist with treating various sicknesses by creating sound new cells and tissue. There are a wide scope of sicknesses that are treatable with foundational microorganisms gotten from rope blood and different wellsprings of comparable kind of undifferentiated organisms  Hematopoiesis Undifferentiated organism like bone marrow and fringe blood, including undeveloped cell issues, intense and constant types of leukemia ,myeloproliferative problems, and some more.

• Solid Tumors Malignancies
• Leukemia
• Anemia
• Blood Disorders

Track 8: Regenerative Medicine and Therapeutics

Regenerative medication might be characterized as the method involved with supplanting or "recovering" human cells, tissues or organs to reestablish or lay out typical capacity. In the event that you have coronary illness, these lab-made heart muscle cells might be utilized as relocated tissue to help fix or supplant harmed heart cells. Cooperating, these activities do great work of easing torment that undeveloped cells and platelets as platelet-rich plasma (PRP) might be utilized.

• Platelet-rich plasma
• Muscle cells
• Heart cells

Track 9: Scaffolds and Tissue Regeneration

Implanted scaffolds with inductive niches can facilitate the recruitment and differentiation of host cells, thereby enhancing endogenous tissue regeneration. Extracellular matrix scaffolds derived from cultured cells or natural tissues exhibit superior biocompatibility and trigger favorable immune responses. Scaffolds are three-dimensional porous solid biomaterials designed which. Provide a spatially correct position of cell location Promote cell-biomaterial interactions, cell adhesion, and ECM deposition.

• Fibrous tissue
• Porous tissue
• Hydrogel scaffolds

Track 10: Cancer Stem cell

Cancer cells found in tumors or hematological cancers  have features similar to normal stem cells, such as the ability to generate all cell types seen in a given cancer sample. CSCs are thus tumorigenic (cancer-forming), maybe in contrast to other cancer cells that are not tumorigenic. Because CSCs make up such a small percentage of the tumor, medications that target the stem cells may not be chosen. Conventional chemotherapy, according to this view, kill differentiated or differentiating cells, which make up the bulk of the tumor but do not create new cells.

• Colon
• Pancreas
• Lung
• Melanoma

Track 11: Embryonic Stem cell

Undeveloped immature microorganisms Embryonic Stem Cell (ESCs) are pluripotent undifferentiated organisms gotten from the inward cell mass of a blastocyst, a beginning phase pre-implantation embryo. Human undeveloped organisms arrive at the blastocyst stage 4-5 days post treatment, when they comprise of 50-150 cells. Undeveloped immature microorganisms of the inward cell mass are pluripotent, meaning they can separate to produce crudeectoderm.

• Pluripotency
• Primitive ectoderm
• Endoderm
• Mesoderm

Track 12: Emerging Nanotechnology for Stem Cell Therapy

Atomic Imaging for Following Undeveloped cell Treatment in Cardiovascular disease research.  This large number of imaging advances including   BLI, FMI, PET, SPECT, and X-ray have been utilized in following foundational microorganism treatment in cardiovascular, which will advance the improvement of undifferentiated organism treatment. Presently, progress in the field of undifferentiated cells is exceptionally encouraging with reports of clinical outcome in dealing with different illnesses like; neurodegenerative sicknesses and macular degeneration advancing quickly.

• Cardiovascular
• Neurodegenerative
• Macular degeneration

Track13: Stem cells in regenerative biology

In science, recovery is the course of reestablishment, reclamation, and tissue development that makes genomes, cells, living beings, and environments versatile to regular variances or occasions that cause aggravation or harm. Each specie is fit for recovery, from microorganisms to people. Recovery can either be finished where the new tissue is equivalent to the lost tissue, or in complete where after the necrotic tissue comes fibrosis.

• Microorganisms
• Necrotic tissue
• Genomes
• Fibrosis

Track 14: Stem Cell Therapy for Musculoskeletal Diseases

The outer muscle recovery research group in the Middle for Regenerative Medication fills in as a helpful pipeline from biomedical revelation to clinical execution, further developing therapies for patients with states of the muscles, ligaments, meniscus and bone musculoskeletal repair.

• Bone growth
• Stem cell therapy
• Whole-body biomechanics
• Tissue recycling

Track 15: 3D Bio-Printing and Organ Printing

3D bio printing is an innovation where bio inks, blended in with by resident cells, are imprinted in 3D to develop regular tissue-like three-layered structures. At present, this innovation can be utilized in different examination regions, for example, tissue designing and new medication improvement. Organ printing uses methods like customary 3D printing where a PC model is taken care of into a printer that sets down progressive layers of plastics.

• Tissue Resident memory cells
• Cellular material
• Selective laser sintering

Track 16: Biomaterials and Biomedical Applications

Biomaterials are used by doctors, researchers, and bioengineers for a variety of purposes: Medical implants, such as  disorders of heart valves, stents and grafts, artificial joints, ligaments, and tendons, hearing loss implants; dental implants; and nerve stimulation devices are all examples of medical implants. Thermal spray techniques and coatings are being used in biomedical applications for the first time. To produce non oxidized titanium coatings, metallic coatings, titanium and its alloys, are sprayed onto metal prostheses in vacuum techniques.

• Stents and grafts
• Artificial joints
• Ligaments and tendons

Track 17: Clinical Tissues Analysis

Tissue can be used to diagnose and classify diseases, such as cancer cell to determine whether or not a patient has cancer, as well as the type of cancer and its characteristics. Tissue engineering is distinguished by its ability to regenerate a patient's own tissues and organs that are completely free of poor bio compatibility limited bio functioning and severe immune rejection. Tissue engineering is frequently regarded as the ultimate medical treatment because to its numerous advantages.

• Muscular tissue
• Connective tissue 
• Epithelial tissue
• Nerve tissue

Track 18: Tissue-Engineered Disease Models

Increasingly complex synthetic tissues serving as in vitro models of human disease will be used to support research on disease mechanisms. Biomedical research relies heavily on small-animal models. Organ typic models, which have been developed for a range of tissues such as the skin, liver, stomach, kidney, and lung, have a realistic micro-anatomy, imitate organ function, and provide insight into cell-to-cell interactions.

• Micro-anatomy,
• Mimic organ function
• Cell-to-cell interactions

Track 19: Epigenetics and Stem Biology

Stem cell homeostasis is maintained by epigenetic processes that regulate chromatin shape and specific gene transcription programmed in a highly dynamic manner. Changes in gene expression that are heritable through modifications that do not impact the DNA sequence are referred to as epigenetics. Depending on their location in the body, embryonic stem cells are capable of self-renewing and differentiating to the intended fate. Stem cell homeostasis is maintained by epigenetic processes that regulate chromatin shape and specific gene transcription programmed in a highly dynamic manner. Changes in gene expression that are heritable through modifications that do not impact the DNA sequence are referred to as epigenetics.

• Stem cell
• Embryonic stem cell
• Epigenetics

Track 20: Ageing Theories in Stem Cell

As stem cells age, their renewal ability deteriorates and their ability to differentiate into the various cell types is altered. Accordingly, it is suggested aging-induced deterioration of stem cell functions may play a key role in the pathophysiology of the various aging-associated disorders. The stem cell theory of aging postulates that the aging process is the result of the inability of various types of stem cells to continue to replenish the tissues of an organism with functional differentiated cells capable of maintaining that tissues or organs original function.

• Secondary aging
• Maladaptive aging
• Assisted death
• Senemorphic aging

 

Stem Cell Treatment:

The market for stem cell treatment is expected to increase at a CAGR of 27.99 percent from 2019 to 2025, approaching USD 167.34 million. The factors that affect the global market for stem cell therapy are increasing and flourishing, with the majority of clinical trials taking place in nations like the United States, Iran, South Korea, and others targeting heart disease, diabetes, neurodegenerative diseases, musculoskeletal disorders, spinal cord injury, stroke, autoimmune diseases, major trauma, and their therapeutics. However, Germany and many other nations forbid stem cell research involving human embryos.

Cell Analysis:

The cell analysis market is divided into regions based on geography: North America, Europe, Asia Pacific, Latin America, the Middle East, and Africa. In terms of revenue, North America came in first place in 2021, followed by Europe. The dominant position in the region is a result of the favourable economic climate, strong government backing, and well-established pharmaceutical and biotechnology businesses in the US. Through 2022 to 2027, the Asia Pacific cell analysis market is anticipated to expand at the quickest rate. The economies of APAC nations are consistently growing, as are their disposable incomes.

Global Market Analysis on Stem Cells:

The global market for cell analysis is divided into segments based on product and service, including reagents & consumables, instruments, accessories, software, and services. In 2021, the reagents & consumables sector held the biggest market share for cell analysis. While over the predicted period, the software category recorded the greatest CAGR. The creation of datasets with intricate patterns and several modalities has increased the demand for computational solutions.

List of Stem Cell Therapy Universities in Germany:

• Heidelberg University
• Humboldt University Berlin
• Technical University Berlin
• Humboldt University of Berlin
• Free University of Berlin

List of Stem Cell Therapy Universities in around the world:

• University of Oxford.
•  University of Cambridge.
•  Karolina Institute.
•  Kyoto University.
• University of Oslo.
• Utrecht University.
• Imperial College London.
• University of Toronto
• Black Family Stem Cell Institute
• Centre for Regenerative Medicine Stefano Ferrari
•  IMBA – Institute of Molecular Biotechnology,
• Institute for Stem Cell and Regenerative Medicine
• Austrian Academy of Sciences
• McEwen UHN Stem Cell Institute

List of Stem Cell Hospitals in Germany:

• World Stem Cells Clinic
• DVC Stem
• Global Stem Cells Group
• Wake Forest Institute for Regenerative Medicine
• Harley Street Skin Clinic
• Stem Cells Treatment Clinic Swiss Medica

List of Stem Cell Hospitals Around the World:

• Mayo Clinic Transplant Center, USA
• Valiant Clinic & Hospital, Dubai
• COR Clinic of Regenerative Medicine
• Stem Cell Treatment Center, Ukraine
• Stem Cells Treatment Clinic ,Swiss Medica
• NuaCell
• Seattle Sports & Regenerative Medicine, Washington
• NW Regenerative Medicine and Anti-aging Institute of Post Falls
• Este Medical Group, England
   

Related Societies:

United States: Applied Stem cell Inc, UC Davis Institute for Regenerative Cures, Bio Informant Worldwide, LLC, Advanced Sports & Spine, Dana-Farber Cancer
Institute, Department of Cellular and Molecular Medicine, Midwest Stem Cell Therapy Center, TruStem Cell Therapy, Regener wave Clinic, Regen America – Philadelphia

Europe: MEOCLINIC – Privatpraxen und Privatklinik in Berlin Mitte, EW Villa Medica Germany, Clinic St. Georg, Booking Health, Aesthetic Clinic, Belgian society for stem cell research, Danish Stem Cell Society, Euro stem cell, German Stem Cell Network

Asia Pacific: Japanese Society for Regenerative Medicine, Korean Society for Stem Cell Research, Stem Cells Australia, The National Stem Cell Foundation of Australia, Taiwan Society for Stem Cell Research, Stem Cell Society Singapore, Australian Society for Stem Cell Research

Middle East: Mena Forum Dubai, The Event Company, Hematopoietic stem cell transplantation in Algeria, Cryopreservation of hematopoietic stem/progenitor cells, Stem Cell Research in the Kingdom of Bahrain, International Society for Stem Cell Research QBRI Partners With Harvard Stem Cell Institute Qatar

We gratefully thank all our wonderful Keynote Speakers, Speakers, Conference Attendees, Students, Organizing Committee Members, Associations and Media Partners for making STEMGEN2021 Conference the best ever Webinar!

The 14^th International Stem cell Conference, hosted by the Conference series LLC Ltd was held during December 09, 2021 as a Webinar based on the theme “Exploring the Recent Innovations in the field of Stem cell”

Our sincere thanks to Organizing Committee Members for their gracious presence, support and assistance towards Stem Cell and Regenerative Medicine 2022 conference, and with enormous feedback from the participants and supporters of Stemgen 2022, Conference series LLC Ltd is glad to announce 15th Annual Conference: STEMGEN Berlin, Germany. Let us meet again @ STEMGEN 2022