Neuroplasticity

1. Neuroplasticity Dr. Michael P. Gillespie

2. Neuroplasticity • Neuroplasticity is the ability of the brain to change, for better or for worse, throughout the individual’s life span. • It involves forming neuronal connections in response to information derived from experiences in the environment, sensory stimulation, and normal development (Doidge, 2007; Merzenich, 2001; Nudo, 2008). Dr. Michael P. Gillespie

3. Neuroplasticity • Neuroplasticity refers to the moldable structure of the brain and nerves that results from changes in neural pathways and synapses. These changes stem from changes in behavior, environment, neural processes as well as changes from bodily injury. • The brain does change throughout life. Dr. Michael P. Gillespie

4. Neuroplasticity Dr. Michael P. Gillespie

5. Girl Living With Half Her Brain • http://www.youtube.com/watch?v=2MKNsI5CWoU Dr. Michael P. Gillespie

6. Positive Outcomes of Neuroplasticity • New skills • Better cognition • More efficient communication between sensory and motor pathways • Improved function of the aging brain • Slowing down pathological processes • Promoting recovery of sensory losses • Improved motor control • Improved memory • (Mahncke, Bronstone & Merzenich, 2006; Mahucke & Merzenich, 2006; Nudo 2007; Stein & Hoffman, 2003). Dr. Michael P. Gillespie

7. Negative Outcomes of Neuroplasticity • Decline in brain function • Altered motor control • Impaired performance of activities of daily living • Amplified perception of pain Dr. Michael P. Gillespie

8. Neuroplasticity • http://www.youtube.com/watch?v=iAzmyB9PFt4 Dr. Michael P. Gillespie

9. Structural Changes in the Brain • Synaptic plasticity • Synaptogenesis • Neuronal migration • Neurogenesis • Neural cell death Dr. Michael P. Gillespie

10. Synaptic Plasticity • Synaptic plasticity refers to changes in the strength of connections between synapses. • Long-term potentiation (LTP) • Long-term depression (LTD) • Changes in the number of receptors for specific neurotransmitters • Up-regulation • Down-regulation • Changes in which proteins are expressed inside the cell Dr. Michael P. Gillespie

11. Neuroplasticity – Brain Remodeling • Steps to remodel the brain based upon experiences: • 1. Repetition • 2. Correct fundamentals • 3. Authentic environment Dr. Michael P. Gillespie

12. Neuroplasticity – Brain Remodeling • http://www.youtube.com/watch?v=VvZ-9ofM7Go&feature=related Dr. Michael P. Gillespie

13. Synaptogenesis & Synaptic Pruning • The creation and removal of entire groups of synapses. • This builds and destroys connections between neurons respectively. Dr. Michael P. Gillespie

14. Neuronal Migration • Neuronal migration is a process whereby neurons extend from their place of birth to connect to far reaching areas of the brain. Dr. Michael P. Gillespie

15. Neurogenesis • Neurogenesis is the creation of new neurons. • It largely occurs in the developing brain. • Limited neurogenesis occurs in the adult brain. Dr. Michael P. Gillespie

16. Neural Cell Death • Neurons die. • This can happen from either damage, over-excitation, or disease. • Natural programmed cell death including apoptosis also occurs. Dr. Michael P. Gillespie

17. Functional Reorganization • As the brain develops, certain areas of the brain become specialized for specific tasks. • If your experience changes dramatically or parts of the brain are damaged, areas previously specialized for a certain function can take on the work of other areas. Dr. Michael P. Gillespie

18. Brain Functions / Brain Regions • Contrary to common understanding, brain functions are not strictly confined to specific fixed locations as identified in this picture. Dr. Michael P. Gillespie

19. Previously Held Beliefs • Brain functions were confined to specific fixed locations of brain tissue. • Brain structure is relatively immutable after a critical period during early childhood. • * New research reveals that many aspects of the brain remain plastic in adulthood. * Dr. Michael P. Gillespie

20. Levels of Neuroplasticity • Cellular changes (result of learning) • Cortical remapping (response to injury) Dr. Michael P. Gillespie

21. Synaptic Pruning • Synaptic pruning is a neurological regulatory process that facilitates a change in neural structure by reducing the overall number of neurons and synapses. • The resulting synaptic connections are more efficient. • Pruning is believed to represent the learning process. • Synapses that are frequently used have strong connections whereas those that are rarely used are eliminated. • “Neurons that fire together, wire together. Neurons that fire apart, wire apart”. Dr. Michael P. Gillespie

22. Synaptogenesis / Synaptic Pruning • http://www.youtube.com/watch?v=tJ93qXXYRpU&feature=related Dr. Michael P. Gillespie

23. Cortical Maps • Sensory information from certain parts of the body projects to specific regions of the cerebral cortex. • As a result of this somatotrophic organization of sensory inputs to the cortex, cortical representation of the body resembles a map (or a homonculus). Dr. Michael P. Gillespie

24. The Learning Brain • http://www.youtube.com/watch?v=cgLYkV689s4&feature=related Dr. Michael P. Gillespie

25. Homunculus Dr. Michael P. Gillespie

26. Removing Sensory Inputs • If a cortical map is derived of sensory input, the adjacent segments it will become activated by adjacent sensory inputs. • Merzenich’s 1984 study involved the mapping of owl monkey hands before and after amputation of the third digit. • Before amputation, there were five distinct areas corresponding to each individual digit. • After amputation of the third digit, the area of the cortical map formerly occupied by the third digit was invaded by the previously adjacent second and fourth digit zones. • Only the regions bordering a certain area will invade it will alter the cortical map. Dr. Michael P. Gillespie

27. Sensory Site Activation • Sensory sites that are activated in an attended operant behavior increase their cortical representation (Merzenich and William Kenkins (1990)). • When a stimulus is cognitively associated with reinforcement, its cortical representation is strengthened and enlarged (Merzenich and DT Blake (2002, 2005, 2006). • Cortical representations can increase two to threefold in 1-2 days at the time in which a new sensory motor behavior is first acquired and changes are largely finished within a few weeks. Dr. Michael P. Gillespie

28. Phantom Limbs • Phantom limbs are experienced by people who have undergone amputations. • Cortical reorganization appears to play an important role in phantom limb sensation. • Mirror box therapy developed by Vilayanur Ramachandran has shown great promise in treating phantom limb pain. Dr. Michael P. Gillespie

29. Phantom Limb Pain Dr. Michael P. Gillespie

30. Mirror Box • A diagrammatic explanation of the mirror box. The patient places the good limb into one side of the box (in this case the right hand) and the amputated limb into the other side. Due to the mirror, the patient sees a reflection of the good hand where the missing limb would be (indicated in lower contrast). The patient thus receives artificial visual feedback that the "resurrected" limb is now moving when they move the good hand. Dr. Michael P. Gillespie

31. Mirror Visualization Therapy • http://www.youtube.com/watch?v=Pe8Y3YETnuY&feature=relmfu • http://www.youtube.com/watch?v=hMBA15Hu35M&feature=related Dr. Michael P. Gillespie

32. Spatial Coupling • Marian Michielsen suggested that Ramachandran’s Mirror Box therapy worked by enhancing spatial coupling between limbs. Dr. Michael P. Gillespie

33. Treatment of Brain Damage • Brain activity associated with a given function can move to a different location. • This concept allows for the treatment of acquired brain injury. • The adult brain is not hard-wired with fixed neuronal circuits. • Cortical and subcortical rewiring of neuronal circuits happens in response to training and in response to injury. Dr. Michael P. Gillespie

34. Neurogenesis • Neurogenesis is the process by which neurons are generated from neural stem cells. • Recent studies show that neurogenesis occurs in the adult mammalian brain and can persist well into old age. • This appears to occur in the hippocampus, olfactory bulb, and cerebellum. • In the rest of the brain, neurons can dies, but cannot be recreated. Dr. Michael P. Gillespie

35. Rehabilitation Techniques That Precipitate Cortical Reorganization • Constraint-induced movement therapy • Functional electrical stimulation • Treadmill training with body weight support • Virtual reality therapy Dr. Michael P. Gillespie

36. Constraint-induced Movement Therapy (CIMT) • This therapy improves upper extremity function in stroke victims and other victims with central nervous system damage. • The purpose is to combine restraint of the unaffected limb and intensive use of the affected limb. • Types of restraints: • Sling • Triangular bandage • Splint • Half glove • Mitt Dr. Michael P. Gillespie

37. Constraint-induced Movement Therapy (CIMT) • The use of the affected limb is called shaping. • Training typically involves restraining the unaffcted limb and using the affected limb for 90% of waking hours. • Receiving CIMT early (3-9 months post-stroke) results in greater functional gains than receiving delayed treatment (15-21 months post-stroke). • Factors for success of CIMT • Concentrated and repetitive practice of the affected limb. • The unaffected limb must be constrained 90% of the waking hours. Dr. Michael P. Gillespie

38. Constraint-induced Movement Therapy (CIMT) Dr. Michael P. Gillespie

39. Constraint-induced Movement Therapy (CIMT) • http://www.youtube.com/watch?v=MMTh2hWvB2g Dr. Michael P. Gillespie

40. Functional Electrical Stimulation • Functional electrical stimulation uses electrical currents to activate nerves innervating extremities affected by paralysis resulting from spinal cord injury, head injury, stroke, and other neurological disorders. • Sometimes it is referred to as Neuromuscular electrical stimulation (NMES). Dr. Michael P. Gillespie

41. Functional Electrical Stimulation Dr. Michael P. Gillespie

42. Contralaterally Controlled Functional Electrical Stimulation Stroke Therapy • http://www.youtube.com/watch?v=boz0HQXQhKg Dr. Michael P. Gillespie

43. Treatment of Learning Difficulties • Michael Merzenich developed a series of plasticity based computer programs known as Fast ForWord. • The programs consist of seven brain exercises to help with the language and learning deficits of dyslexia. • The software also improved cognitive function in adults with age related cognitive decline (ARCD). Dr. Michael P. Gillespie

44. Chronic Pain • Some people suffer chronic pain at sites that were previously injured, but are currently healthy. • Chronic pain happens as a result of maladaptive reorganization of the nervous system both peripherally and centrally. • During the period of tissue damage, prolonged nociceptive input from the periphery to the central nervous system results in somatotopic organization and central sensitization. Dr. Michael P. Gillespie

45. Meditation • Meditation has been linked to cortical thickness and the density of gray matter. • Richard Davidson performed experiments with H.H. the Dalai Lama to examine the effects of mediation on the brain. • Long term and short term practice of meditation resulted in different levels of activity in brain regions associated with qualities such as attention, anxiety, depression, fear, and anger. • Mediation also demonstrated an effect on the ability of the body to heal itself. • Changes in the physical structure of the brain appear to be responsible for these differences. Dr. Michael P. Gillespie

46. Exercise Induced Neuroplasticity • All forms of exercise appear to produce neuronal changes in the brain; however, different forms of exercise produce changes in different brain regions. • More demanding forms of exercise seem to promote change in more diverse areas of the brain. Dr. Michael P. Gillespie

47. Neuroplasticity & Occupational Therapy • Learning and memory are the result of experience driven alterations of the synaptic structures of neurons. • “Occupational Therapy practitioners set up the circumstances and situations that modify the environment and the degree of challenge for a skill set (just the right challenge) that creates an adaptive response that originates at the cellular and molecular level” (McCormack, 2009). • Neuroplasticity reflects the brain’s ability to grow and change into old age as long as it is engaged in meaningful occupations. This is the basis of occupational therapy (Christiansen & Baum, 2005). Dr. Michael P. Gillespie

48. Types of Neuroplasticity • Practice-Dependent Plasticity • Competitive Plasticity • Positive Plasticity • Negative Plasticity Dr. Michael P. Gillespie

49. Practice-Dependent Plasticity • A person performs a task repeatedly to learn or re-learn a skills set. • “The neurons that fire together, wire together” (Hebb’s concept). • http://www.youtube.com/watch?v=5iyodWeFkLE • You can incorporate constraint induced OT as well to “force” neurons to fire together and “unmask” latent neurons to activate those neuronal pathways. Dr. Michael P. Gillespie

50. Competitive Plasticity • Use or disuse of a neuronal pathway will lead to natural selection of the pathways utilized. • “Use it or lose it” • The cerebral cortex is constantly remodeling itself according to influences from the environment (Bear et al, 2007; Mahncke, Bronstone et al, 2006). Dr. Michael P. Gillespie