Lecture 7- Translational applications

Question 1

drug development phases

Answer 1

phase 1- healthy volunteers, safety and dosage
phase 2- small no. patients, effectiveness, side effects
phase 3- more patients, effectiveness, adverse reactions
phase 4-additional post-marketing testing

Question 2

biomarkers

Answer 2

can help diagnose pre-symptomatic cases

Question 3

tau CSF- biomarker

Answer 3

CSF tau- increased (dying neurons release extracellularly)

• higher concentration= greater cognitive impairment in normal-MCI-AD spectrum
• increased CSF tau not specific for AD
• similar increase not seen in pure tauopathies, indicate role of Abeta

Question 4

CSF Abeta- biomarker

Answer 4

CSF abeta- decreases over time

• Abeta42 aggregated, retained within brain, not released in soluble form into CSF
• low concentrations would match clinical diagnosis of AD

Question 5

molecular neuroimaging- biomarker

Answer 5

study normal brain function, early disease states, longitudinal studies, treatment response

Question 6

PET (positron emission tomography)

Answer 6

inject chemical ligand labelled with radio isotope, detects gamma rays

Question 7

PiB

Answer 7

PET ligand for amyloid; cross BBB, bind to amyloid, detect amyloid

Question 8

PET signal and braak staging

Answer 8

correlation- Abeta deposition/plaque location progressed

Question 9

Abeta burden in dementia in AD, HC, MCI

Answer 9

AD- SUVR above cutoff, PiB positive–>Abeta burden
HC- SUVR below cutoff, PiB positive; pre clinical cases?
MCI- PiB positive (non memory MCI), PiB negative (amnestic MCI)

Question 10

SUVR

Answer 10

standardised uptake value ratio

Question 11

ApoE4 and PiB signal

Answer 11

higher PiB signal

-higher SUVR score, E4 is a risk factor for AD, greater amyloid deposition

Question 12

neurogenetic testing

Answer 12

identify gene mutations, must be done with genetic counselling

Question 13

genetic stratification

Answer 13

very important if you know who to treat, easier during drug trials

Question 14

Parkinsons disease treating dopaminergic pathway

Answer 14

L-dopa
MAO-B inhibitors
dopamine agonists
anti-cholinergic drugs- interfere with production/uptake of ACh–>reduces tremors and muscle stiffness

Question 15

cholinergic pathway

Answer 15

project to thalamus

important role in working memory, conscious awareness and attention

Question 16

AChesterase inhibitors (Aricept)

Answer 16

enhances cholinergic activity (since inhibiting breakdown of ACh)

Question 17

5 drug targets

Answer 17

alpha secretase activator
anti-oxidant
neuroprotectants
anti inflammatory 
tau aggregation inhibitor

Question 18

tramiprosate (homotaurine)

Answer 18

sulfated glycosaminoglycan mimetic

• oligomerisation inhibitor
• maintain Abeta in non-fibrillar form
• reduces Abeta42 induced cell death
• transgenic mice- reduced amyloid plaque and soluble/insoluble Abeta 40/42 levels
• clinical trials- failed to improve cognitive performance

Question 19

MPACs

Answer 19

metal protein attentuating compounds- targets metals bound to Abeta
- e.g. Clioquinol, PBT2

Question 20

Abeta, metals and async

Answer 20

Abeta interacts with metals, drive async toxicity

Question 21

clioquinol

Answer 21

• chelates Zn and Cu, disaggregation of amyloid into smaller pieces of Abeta
• crosses the BBB
• small phase 2 human trial -reduction in amyloid load

Question 22

PBT2

Answer 22

follow up MPAC to clioquinol

• oxygen and nitrogen groups provide chelating properties
• phase 2a trial- positive outcomes
• global financial crisis- not even funds, trial design wrong

Question 23

semagacestat (eli lilly)

Answer 23

gamma secretase inhibitor

Question 24

gamma secretase inhibitor

Answer 24

semagacestat (eli lilly)

• lowered plasma, CSF and brain Abeta in animals
• lower CSF and plasma Abeta in humans
• changed both Abeta40/42 levels
• phase 3 trials- NO slow AD progression, caused worsening of clinical measures of cognition
• side effects- increased incidence of skin cancers, infections

Question 25

problem with gamma secretase inhibitors

Answer 25

non selective

- cleaver other proteins as well e.g. NOTCH0- important protein

Question 26

anti-Abeta vaccines for AD

Answer 26

• only seen as theoretical before someone did it
  Approach
• immunize AD mouse model with Abeta antigen
  Result
• reduction in amyloid plaques, and Abeta levels
  -Abs also crossed BBB

Question 27

vaccine in active immunisation against AD

Answer 27

AN1792- aggregated Abeta42 peptide antigen
-phase 2a trial- patients immunized
-no significant differences between Ab responder and placebo groups
-trials stopped- meningoencephalitis in 6% patients-T cell activation
- some patients long term followup
-Mean Abeta load 5 years later decreased
-NO evidence for improved survival or improvement in time to severe dementia
Ie- reduced amyloid plaque but no effect on progression of neurodegeneration

Question 28

3 vaccines for passive immunisation for AD

Answer 28

preformed purified Abs
1- Bapineuzumab
2- Solanezumab
3- Aducanumab

Question 29

Bapineuzumab

Answer 29

binds both soluble and fibrillary Abeta

• reduced amyloid burden in transgenic mice
• trials not promising results
• phase 3 trials- failed in AD patients with or without ApoE4 allele

Question 30

Solanezumab

Answer 30

preferentially binds soluble Abeta

• mouse model- reversed memory deficits without affecting brain Abeta load
• phase 2 trials- increased plasma and CSF levels of Abeta40/42- GOOD- plaque load decreasing
• no effect on behavioural outcomes (cognition)
• phase 3 trials- primary endpoints (congitive, functional) NOT met
• secondary analysis - modest slowing in cognitive decline

Question 31

Aducanumab

Answer 31

binds soluble oligomers and insoluble fibrils

• included PET imaging of amyloid
• phase 1b trial- reduced amyloid levels, slowed down cognitive decline
• but not powered enough to determine effect on cognition
• did bigger trials- no robust change

Question 32

anti async Ab

Answer 32

Antibody- Syn303

• wire hang test- motor performance
• did better with Syn303
• decreases number of async aggregates
• increases survival of TH positive neurons (dopaminergic)

Question 33

Syn303

Answer 33

anti asynuclein Ab

Question 34

Syn506

Answer 34

Ab that recognises misfolded async found in LBs

Question 35

anti tau Ab

Answer 35

Ab- HJ8.5

• P301S transgenic mice
• increases in plasma tau levels, decrease in phospho-tau (hitting its target)
• improves motor function

Question 36

3 mechanisms of Ab mediated therapeutics

Answer 36

1- microglial phagocytosis
2- catalytic disaggregation
3- peripheral sink mechanism

Question 37

microglial phagocytosis

Answer 37

microglial recruitment to opsonised Abeta

- Fc receptor mediated phagocytosis `

Question 38

catalytic disaggregation

Answer 38

Abs binds to fibrillar Abeta

- solubilisation of Abeta fibrils, neutralise/disaggregate

Question 39

peripheral sink mechanism

Answer 39

Ab sequestering to circulating Abeta in periphery

-increased efflux from parenchyma to blood system

Question 40

failure of major clinical trials

Answer 40

• actual mouse models not true representation
• drug target no longer critical for pathogenic/clinical phenotype
• treating subjects too advanced in the disease pathway