Bioengineering: Difference between revisions
From Intelligent Materials and Systems Lab
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== Our vision and goal == | == Our vision and goal == | ||
We are researching how biopolymeric electroactive systems based on cellulose, chitosan, silk etc. can be used as delivery platforms for medication such as chemotherapy that would take the medication precisely to the target area and not have it be circulated throughout the entire body (release-capture), where its toxicity can hurt patients as much as help them. These biopolymers are known for "fooling" the body into thinking it is part of its system, it is delivering medicine in a focused, pinpoint way what that could greatly accelerate regeneration and healing. | We are researching how biopolymeric electroactive systems based on cellulose, chitosan, silk etc. can be used as delivery platforms for medication such as chemotherapy that would take the medication precisely to the target area and not have it be circulated throughout the entire body (release-capture), where its toxicity can hurt patients as much as help them. These biopolymers are known for "fooling" the body into thinking it is part of its system, it is delivering medicine in a focused, pinpoint way what that could greatly accelerate regeneration and healing. | ||
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We of soft biopolymeric electroactive platform for therapeutic applications | We of soft biopolymeric electroactive platform for therapeutic applications | ||
# Biocompatible 3-D matrix for doping | # Biocompatible 3-D matrix for doping | ||
# Controlled delivery and | # Controlled delivery and release mechanisms | ||
# Trapping and capture of bioorganic compounds | # Trapping and capture of bioorganic compounds | ||
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== Primary contacts == | == Primary contacts == | ||
{{Team| | |||
{{TeamMember|Janno|Janno Torop|head of the group}} | |||
{{TeamMember|Alvo|Alvo Aabloo|head of the lab}} | |||
}} | |||
== Some completed student projects == | == Some completed student projects == | ||
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* Measurement device for mechanical properties of soft laminates | * Measurement device for mechanical properties of soft laminates | ||
== Possible topics for | == Possible topics for student projects == | ||
[[Soft | * [[Student projects in Soft Robotics|List of currently active and timely projects]] | ||
== Porfolio == | == Porfolio == | ||
=== Research Projects === | |||
... | |||
=== Selected Publications === | === Selected Publications === | ||
Latest revision as of 10:38, 14 August 2019
Our vision and goal
We are researching how biopolymeric electroactive systems based on cellulose, chitosan, silk etc. can be used as delivery platforms for medication such as chemotherapy that would take the medication precisely to the target area and not have it be circulated throughout the entire body (release-capture), where its toxicity can hurt patients as much as help them. These biopolymers are known for "fooling" the body into thinking it is part of its system, it is delivering medicine in a focused, pinpoint way what that could greatly accelerate regeneration and healing.
Highlights
- Creation of ‘designer’ biopolymers that can be used inside the body
- We have developed a ionic muscle-like structures from natural cellulose
- We can build soft manipulators for accommodation and delivery of therapeutic compounds
Capabilities
We of soft biopolymeric electroactive platform for therapeutic applications
- Biocompatible 3-D matrix for doping
- Controlled delivery and release mechanisms
- Trapping and capture of bioorganic compounds
Tools we use
- Additive fabrication methods for building soft electroactive laminates and 3-D structures
- Electrochemical and electro-visio-mechanical impedance spectroscopy
- Electrodeposition and -coating of soft actuators
Equipment
- Customized spray-coating set-up
- Electromechanical testbenches with full electronic control
- Computer vision set-up for robotics materials characterization
- In-situ characterization of robotic materials using scanning electron microscopy
- Dynamic mechanical analysis of robotic materials in a controlled atmosphere
- Thermal imaging of robot's action
Primary contacts
Janno Torophead of the group
Alvo Aabloohead of the lab
Some completed student projects
- A self-rolling wheel based on artificial muscles
- An insect-inspored walking robot with artificial muscles
- Spray-fabrication of artificial muscles on glass fiber cloth
- Measurement device for characterization of mechano-sensing laminates
- Measurement device for mechanical properties of soft laminates
Possible topics for student projects
Porfolio
Research Projects
...
Selected Publications
- D. Nevstrueva, K. Murashko, V. Vunder, A. Aabloo, A. Pihlajamäki, M. Mänttäri, J. Pyrhönen, T. Koiranen, J. Torop, (2018) Natural cellulose ionogels for soft artificial muscles, Colloids and Surfaces B: Biointerfaces 161 244-251
- Janno Torop; Alvo Aabloo; Edwin W.H. Jager (2014) Novel actuators based on polypyrrole/carbide-derived carbon hybrid materials Carbon, 80,387–395.