MNB.09 Intro to Regenerative Medicine PDF

Summary

This presentation introduces regenerative medicine, a field combining life sciences and engineering to repair or regenerate cells, tissues, or organs. It highlights the clinical need for this approach, discusses tissue grafts and biomaterials, and describes methods for obtaining therapeutic cell populations and the role of signaling molecules. The presentation touches upon the growing market of regenerative medicine and strategies for implementing such medicine.

Full Transcript

Musculoskeletal System,
Nervous System & Bioelectricity

MNB.9 Introduction to
regenerative medicine
D r. To m H o d g k i n s o n
Learning outcomes

ALO 1: Outline the clinical need for regenerative medicine as an alternative to conventional approaches.
ALO 2: Discuss the various types of tissue graft and issues surrounding donor site morbidity and donor
availability/ matching.
ALO 3: Describe different approaches to regenerative medicine involving materials, cells and signaling
molecules.
ALO 4: Describe the properties required by a successful biomaterial – biocompatibility, biodegradability,
architecture, immune response, mechanical properties.
ALO 5: Describe the options available for obtaining therapeutic cell populations – allogeneic, autologous,
somatic cells, stem cells, induced pluripotent stem cells, genetically engineered cells.
ALO 6: Discuss the role of signaling molecules in regenerative medicine.

MNB.9 Introduction to Regenerative Medicine 2
 What is regenerative medicine?
Interdisciplinary field bringing together life sciences and engineering.

Replacing, engineering or regenerating cells, tissues or organs to restore or establish normal
function.

Has the potential to repair previously difficult to heal or irreparable tissues and organs.

Also includes growing of tissues/ organs or models of them in the lab for study or implantation
(Tissue Engineering).

Concept of producing new cells to replace malfunctioning or damaged cells to treat disease or
injury.

Particular promise for diseases or injuries with no current effective treatment.

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Why do we need regenerative medicine?

Organ donation shortage, organ transplantation rejection

Donor site morbidity

Models of healthy tissue and disease

Drug discovery and testing

Targeting of diseases with genetic component

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Clinical Need for Regenerative Medicine
2023
The global regenerative medicine market size
was valued at USD 30.43 billion in 2023 and
Statistics
is expected to grow at a compound annual
growth rate (CAGR) of 16.79% from 2024 to
2030.
Factors influencing the market include
1. Longevity & population increase
2. Advancements in cell biology, genomic
research, and gene editing technology
3. Stem cell-based regenerative therapies and
attitudes towards embryonic stem cell
therapy
4. Post COVID reflection and industry support
(e.g. Novartis continuing in CAR-T therapy)
https://www.grandviewresearch.com/industry-analy
sis/regenerative-medicine-market
MNB.9 Introduction to Regenerative Medicine 5
Strategies for Regenerative Medicine
Large diversity in approaches. Heart valve
Mimic the structures and properties seen in natural extracellular matrix- tissue
dependent – components, architecture, mechanical properties, biochemical properties.
Can try to mimic mature tissue or provisional/ wound healing tissue stage to enhance
healing responses.
Can be acellular structures or cell-based therapies.
Biomaterials can provide instructive cues and gradients to instruct cell behaviour.

Spinal cord repair Bone-to-cartilage interface Intestine model

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Types of grafts and Graft Substitutes
Historically, damaged tissue was surgically treated via forms of mechanical
closure to reduce bleeding and infections like septicaemia.
Less attention was given to tissue regeneration or the recovery of organ
function beyond patient survival.

Traditional Approaches to replace ‘missing’ or damaged organs
Autograft (60%) Allograft (30%) Xenograft ( 99%

Arlyng Gonzalez-Vazquez et al,
Biomaterials, 2021
hMSCs

JNK3* free JNK3* Scaffold

JNK3*/F-Actin

JNK3* scaffold enhanced the osteogenic capacity of A-MSCs by activating JNK3
Development Of Jnk3* Scaffold For Bone Repair
4 weeks

Empty BMP2 JNK3*Free JNK3* Scaffold

Arlyng Gonzalez-Vazquez et al, Biomaterials,
Learning outcomes
ALO 1: Outline the clinical need for regenerative medicine as an alternative to conventional
approaches.
ALO 2: Discuss the various types of tissue graft and issues surrounding donor site morbidity
and donor availability/ matching.
ALO 3: Describe different approaches to regenerative medicine involving materials, cells and
signaling molecules.
ALO 4: Describe the properties required by a successful biomaterial – biocompatibility,
biodegradability, architecture, immune response, mechanical properties.
ALO 5: Describe the options available for obtaining therapeutic cell populations – allogeneic,
autologous, somatic cells, stem cells, induced pluripotent stem cells, genetically engineered
cells.
ALO 6: Discuss the role of signaling molecules in regenerative medicine.

MNB.9 Introduction to Regenerative Medicine 25
 Laiva A, O’ Brien, F.J., Keogh M.B "Innovations
in Genes and Growth Factor delivery systems
for Diabetic Wound Healing." (2018) Journal of
Tissue Engineering and Regenerative

Learning
Medicine, 12(1), e296-e312.

Resources Hustedt JW, Blizzard DJ. The controversy
surrounding bone morphogenetic proteins in
the spine: a review of current research. Yale J
Biol Med. 2014 Dec 12;87(4):549-61. PMID:
25506287; PMCID: PMC4257039.

Curtin et al. (2012) Advanced Materials
24(6):749-54
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Thank you
F O R M O R E I N F O R M AT I O N P L E A S E C O N TA N T
To m H o d g k i n s o n
E M A I L : To m h o d g k i n s o n @ R C S I. C O M

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