Metals in Medicine

Question 1

What are the problems with photofrin?

Answer 1

1. Drug purity - exist as a mixture of compounds
2. Drug targeting and cytotoxicity - localises in both cancerous and healthy cells, slowing leaves body.
3. Light interaction - absorbs strongly in blue region, for PDT blue light has little tissue penetration so red light is more efficient.
   there is a limitation to shifting the wavelength of light absorption further into the red.The photosensitiser triplet state drops, and eventually is not sufficient to generate singlet oxygen, range = >600 nm - <900 nm

Question 2

what is purpurin and why is it being studied in PDT?

Answer 2

Purpurin is a porphyrin derivative found in chlorophyll
It has a strong absorption at 600 nm and long lived triplet excited state so is a good singlet oxygen generator.
When Sn bounds abs shifted by 30 nm so has excellent optical properties.

Question 3

What are metallotexaphryin and advantages and disadvantages?

Answer 3

extended porphryins that contain longer bridges between heterocyclic rings.
When M is Zn or Cd, these show excellent PS (photosensitiser) properties.
intense abs at 730-770
high triplet state yields
low fluorescence yields.

Question 4

List the most common elements in the body and elements present in trace amounts.

Answer 4

O,C,N and H are the most common. other elements include Fe, Ca, K, P and Na. Zn and Cu exist in trace amounts for enzymes function.

Question 5

Describe the does response for any essential element

Answer 5

1. survival
2. deficiency
3. optimal
4. toxicity
5. lethaility

Question 6

How can unnatural elements be used in treatment?

Answer 6

As Antagonism. They function biologically as they are recognised by the body as natural metal elements.

Question 7

what are the attractive properties of metals?

Answer 7

1. flexible bond orders and geometries - unique geometries an a number of connectivities
2. charged (cationic and anionic) so are water soluble.useful for water soluble metallo - intercalations
3. paramagentic/ radioactive - used in imaging and trageted radiotherapy
4. redox active
5. Lewis acids/ electrophillic so can bind to many e rich sites eg DNA base sites

Question 8

what is the therapeutically active form of arsenic?

Answer 8

Arsenic oxide

Question 9

How do arsenoxides help HAT?

Answer 9

HAT is sleeping sickness. Parasite invades CNS and causes exhaustion and torpor and sleep like unconsciousness. Used a masked form of an arsenic that crosses the blood brain barrier. (draw this compound)

Question 10

how does glutathione protect the cell from oxidative stress?

Answer 10

reacts with reactive oxygen species that cause oxidative stress. GSH + ROOR - GSSG + ROH

Question 11

how do trypnosomes work?

Answer 11

They carry out the function og glutathione but use tyrponothione antimonal - drugs will interfere with the enzyme that produces antimonal and therefore target the parasite an d not the drug

Question 12

how do trypnosomes work?

Answer 12

They carry out the function og glutathione but use tyrponothione antimonal - drugs will interfere with the enzyme that produces antimonal and therefore target the parasite and not the drug

Question 13

how does APL cause cancer?

Answer 13

Genetic mutation that leads to the production of a protein that blocked the expression of the genes involved in the differentiation of white blood cells

Question 14

how does ATRA/As203 work against APL?

Answer 14

disrupts APL proteins so get differentiation

Arsenic increases ROS conc which leads to apoptosis

Question 15

how does soft tissue imaging work?

Answer 15

uses radioactive isotope

Question 16

what is the role of radio pharmaceuticals?

Answer 16

Uses gamma photons in single photon emission computerized tomography. Couples 2D images to make 3D images. Radionucletide provide output and pharmaceutical provides selectivity.

Question 17

what are the requirements for diagnostic imaging?

Answer 17

Penetrate body - alpha is too ionising and beta does damage.
short half life but live long enough to be detected and synthesised.
Detectable outside the body - needs a camera and have a high emission energy
Should be relatively cheap

Question 18

what is wrong with Carbon (11)?

Answer 18

It is too expensive as it has to be made in a cyclotron.

Question 19

what are the benefits of Tc?

Answer 19

has 20 known isotopes but 99mTc is most common as it is:
Readily available through 99Mo/99mTc generator
has a 6 hr half life and displays gamma emission at 140 KeV so an expensive instrument is not required
wide range of oxidation states

Question 20

How does the Tc generator work?

Answer 20

Mo decays into Tc (Mo from uranium in nuclear fission)

Tc increase charge of nucleus and is less held to the column. Elute column with Nacl and CL ions displace TC ions

Question 21

what are the problems with Tc?

Answer 21

Concentration is too dilute, so structure can not be inferred by NMR. the other isotope is used for that. HPLC used to infere the structure of Tc(99).

Chemistry is complex due to variable oxidation states and coordination numbers. Each ligand has to be tailored to each ion
The imaging complex needs to be produced in one step.

Question 22

what are the problems with Tc?

Answer 22

Concentration is too dilute, so structure can not be inferred by NMR. the other isotope is used for that. HPLC used to infere the structure of Tc(99).

Chemistry is complex due to variable oxidation states and coordination numbers. Each ligand has to be tailored to each ion
The imaging complex needs to be produced in one step.

Question 23

what are the two classifcation of radiopharmaceuticals?

Answer 23

Biological distribution is determined by perfusion or ultimately determined by specific interactions.

Question 24

what is perfusion?

Answer 24

Passage of fluid through the circulatory or lymphatic system.

Question 25

there are two way RFC can be if they are biologically distrubuted by specific interaction. what are they?

Answer 25

so RPC can be metal essential - distribution depends on properties of coordination complex
or Metal tagged - properties of carrier molecule determine distribution

Question 26

what are first generation Tc imaging agents?

Answer 26

They are biologically distributed by blood perfusion and this distribution is due to properties of the coordination complex. METAL ESSENTIAL. they target heart, liver, brain, bone and kidneys.

Question 27

what are the two criteria for cerebral imaging agents?

Answer 27

must cross the BBB so must be neutral and fairly lipophillic?

Question 28

how does TcOPnAO form a macrocycle?

Answer 28

It can deprotonate at neutral pH. coordination to metal centre makes it more acidic. Hydrogen bond forms an you get macrocylcle?

Question 29

what is the benfits andproblem with TcOPnAO?

Answer 29

known to corss BBB and be taken up by the brain but diffuses out the brain too quickly

Question 30

why does ceretec and neurolite cross the BBB?

Answer 30

They are lipophillic

Question 31

how important is the stereochem of neurolite in imaging the brain?

Answer 31

V important. If the ester group is pointing down it wont work. wont image brain or even cross BBB

Question 32

How does neurolite accumulate in the brain?

Answer 32

Esterase present in the brain whcih breaks down ester group in neurolite to an CA, this makes it more hydropillic so it accumulates in the brain

Question 33

What do Tc cebral images show?

Answer 33

Using single photon emission computerised tomography.
High Tc conc will appear red indicating good blood flow (2D images) and where there is poor blood flow or non at all will appear as holes (3D image)

Question 34

what are the uses for Tc based spec?

Answer 34

Diagnosing reduced blood flow areas form conditions such as a stroke.
Imagining the locus of epileptic seizures for more precise treatment
facilitating the diagnosis of psychiatric disorders such as schizophrenia.

Question 35

How is cardolite an improvement to t- butylisonitrile?

Answer 35

the latter was too readily absorbed by liver and clearance. the methoxy groups in Cardolite and hydrolysed which increases hydrophilicity and faster liver clearance.

Question 36

How does cardiolite and myoview end uo in the heart

Answer 36

At first monocationic Tc complexes used as K+ ions analogues to be used to ATP driven K+ active transport but now thought to passively diffuse and electrostatically bind to mitochondria.

Question 37

how does Tc-MAG3 image kidney function

Answer 37

the very polar and anionic complex is rapidly transported to the kidnet and cleared from the body through urine. used to test kidney function as it will accumulate in kidney if kidney is not healthy.

Question 38

What are second generation Tc agents?

Answer 38

All biologically distributed by highly specific interactions. They are designed to bind to ther target with high affinities. Distribution may or may not be dependent on the coordination complex itself.
They are classified according to their receptor site or the biological function they target.

Question 39

what are the requirements for targeting neuroreceptors ?

Answer 39

these are associated with a number of disorders. to target sites you need a Tc complex that is the right size, charge and lipophilicity and one that has a binding site.

Question 40

describe the dopamine system?

Answer 40

Dopamine receptor sites called Dopamine transporters (DAT) are found in nuerons involved in dopamine signalling. Dopamine is associated with parkinsons and schizophrenia.

Question 41

how is the dopamine system imaged?

Answer 41

using neutral 99mTc - TRODAT- 1 which crosse BBB and images dopamine receptors.
this consists of diaminodithiol ligand coordinated to a TcO3+ core

Question 42

what is hypoxic tissue and what is needed to image it?

Answer 42

Tissue with low oxygent content, hypoxia is associated with heart disease and solid cancer tumours. Cause it has a low ox content it is more reducing that normal tissue so a redox active marker is needed to image hypoxia such as imidazole.

Question 43

what us wrong with 18F-labelled imidazole imagine agents for hypoxic tissue?

Answer 43

it is too costly

Question 44

why is Bru - 52 better at imaging hypoxic tissue?

Answer 44

More hydrophillic and shows better targeting

Question 45

draw the structure of HL 92 and what is the significance of this compound?

Answer 45

it shows better imaging results that imaidazole derivatives.

Question 46

how are tumors imaged using folic acid?

Answer 46

humans need folic acid for cell division and since cancerous cells are rapidly developing they need more and so overexpress the folate receptor compared to human cells. Attach a folic acid molecule to Tc imaging agent.

Question 47

how are tumors imaged using folic acid?

Answer 47

humans need folic acid for cell division and since cancerous cells are rapidly developing they need more and so overexpress the folate receptor compared to human cells. Attach a folic acid molecule to Tc imaging agent.

Question 48

What are MDR

Answer 48

multidrug resistance. MDR tumors can pump out cytotoxic material They overexpress glycoprotein Pgp which is a trans membrane pump. they are active against lipophilic moncationic complexes

Question 49

what are MDR modulators?

Answer 49

Agents which block the action of PgP

Question 50

how are MDR cells imaged

Answer 50

monocationic Tc complexes used to image the heart can be used as they are subsrtates for pgp recognition. The peripheral methoxy groups enhance pgp recogniton. this has eld to the develpment of complexes that target MDR cells. They are taken up by MDR cells but will only image in the presencs of a MDR modulator

Question 51

Can antibodies bind to natural and non natural targets?

Answer 51

Yes only if they have been engineered to.

Question 52

How are Tc agents bound to antibodies?

Answer 52

By attaching a Tc centre to reduced disulfide linkages. The anitbody is a protein so there are lots of disulphide bridges and this can be reduced so Tc can coordinate.

Question 53

what are the benefits of using antibodies?

Answer 53

They are v specific and bind to their target with high affinity.

Question 54

what are blood clots and what feature means that they can be detected?

Answer 54

aggregation of fibrin, platelets and red blood cells. a D- dimer protein is found on the surface of a active clot (express this once clotting starts)

Question 55

how can Tc labelled antibodies be used to image clots?

Answer 55

An antibody recognizes the D- Dimer and so a lablled version of this anitbody can be used

Question 56

What inspired resenberg to grow bacterial cells in the presence of a fluctuating electromagnetic field

Answer 56

The similarly between the structures is mitosis and the field lines when poles of opposite electromagnetic polarity are brought together

Question 57

What was the experimental conditions of resenberg?

Answer 57

Medium enriched with glucose and MgCl2

Current oscillation 50- 100,000 per sec by a Pt electrode

Question 58

What were the results from Rosenberg studies?

Answer 58

Cell division stopped under application of a current (cells formed long filaments)

But only in presence of Oxygen, so thought that a new oxidising species made

Could it be from Pt???

Question 59

How could the pt complex be formed in the Rosenberg experiment

Answer 59

Pt(IV) salts from the electrolytic process

In presence of light, her diamine complexes (4cl). Only active form when amines are trans to each other

Question 60

what inspired rosenberg to grow bacterial cells under a fluctuating electromagnetic current

Answer 60

the similarity between the structures in mitosis and the field lines when poles of opposite electromagnetic polarity are brought together

Question 61

what was the experimental conditions of Rosenberg study

Answer 61

grown in a medium enriched with glucose and MgCl2

Application of current 50 -100,000 times per sec by Pt electrodes

Question 62

what can be deduced from his study?

Answer 62

Cell division stopped but only in presence of oxygen so therefore a new oxidising chemical species made. possibly Pt?

Question 63

What was the Pt complex formed in Rosenberg study?

Answer 63

Pt(IV) salts formed from the electrolytic process. In presence of light get diamine complexes (4Cl and 2 Amine) active form when amines are cis to each other

Question 64

what is the active form of cisplatin?

Answer 64

When Cl2 and ammonia groups are cis to each other - Pt(II) or Pt(IV)

Question 65

How is cisplatin used as an anticancer drug?

Answer 65

Stops cell division so can halt growth of cancerous cells

Question 66

what is the evidence that DNA is the cellular target for cisplatin?

Answer 66

Cells treated with one dose of cisplatin showed preferentially inhibition of DNA synthesis compared to RNA and protein synthesis. The effect lasted the duration of the experiment

Question 67

what is the evidence that cisplatin directly interacts with DNA

Answer 67

DNA polymerase not affected by addition of the drug and cisplatin non competitively inhibits the binding of the intercalator ethidium bromide, therefore, Pt is covalently bound to DNA

Question 68

describe the aq chemistry of cisplatin?

Answer 68

The extent of dissociation depends on the ambient chloride concentration.
In plasma: [Cl-] is high so neutral lipophillic cisplatin dominates
In cell: [Cl-] is low so hydrolysis of cisplatin occurs
low charge and lipophilicity means it can cross BBB and pass across membranes

Question 69

How does cisplatin bind to DNA

Answer 69

There are 4 coordination sites for binding Pt adducts. these are N1 on adenine, N3 on cystosine and N7 of guanine. N1 and N3 less available die to H bonding. Since the N7 of G is a stronger Lewis base than N7 in A, Therefore N7 of G is the preferred binding site for Pt
adducts.

Question 70

what are the majority of Pt adducts?

Answer 70

Binding to two sites in a single guanine and disrupting H bonding has not been observed. Intrastrand and DNA protein cross-linking only account for ~6% of all adducts.
Majority of adducts formed are intrastrand d(GpG) lesions.

Question 71

what are the structural effects of intrastrand adducts on a single strand of DNA

Answer 71

1. Guanosine base planes are destacked
2. dihedral angle of bases changed
3. sugar conformation changed
4. Restriction of conformation flexibility of DNA

Question 72

what are the structural effects of intrastrand adducts on double stranded DNA

Answer 72

1. large bend in duplex structure (GG dihedral angle is 59)
2. Structure is part compressed and part open
3. these distortions flatten and open the mino groove - more available for binding.

Question 73

Cisplatin prevent cell division but this does not give rise to its anticancer properties. What does?

Answer 73

Cisplatin prevents transcription (inhibts)

Question 74

how does cisplatin prevent transcription?

Answer 74

High mobility group domain proteins bind to cisplatin.
HMG is a DNA binding motif and is present in a large number of proteins including transcription factors. they bind to minor groove and bend DNA o binding. This means that HMG only binds 1,2 cis -GG and 1,2 cis - GA and not 1,3 intrastrand or transplatin. This is the anticancer property of Cisplatin.

Question 75

what are the problems with cisplatin?

Answer 75

1. Emetic and toxic
2. Delivered IV, requires hospital stay
3. it has low aq solubility, reaching limit of cytotoxic drugs delivered into blood stream
4. Many tumours become resistant to it or develop resistance during treatment

Question 76

which oxidation states of Pt are active in 2nd generation Pt drugs?

Answer 76

Pt(III) and Pt(II)

Question 77

what is the active form of 2nd gen Pt drugs?

Answer 77

cis-[PtX2(Am)2] or cis-[PtX2Y2 (Am)2].
amine is inert and has at least one NH moiety.
X is an anion and has an intermediate binding strength to Pt with weak trans effect. If ligands are too labile then drug is toxic but if they are inert then drug is inactive

Question 78

draw carboplatin and give its strengths and weaknesses over cisplatin

Answer 78

the chelating dicarboxylate groups mean slower aquation, less toxicity and better water solubility. All mean it can be administered in higher doses.
But tumours have shown cross resistance to cisplatin and carboplatin

Question 79

Draw oxaliplatin and give its strengths and weakneses

Answer 79

all strengths as carboplatin as it also has a dicarboxylate group. The cyclohexane means lack of cross resistance with some cisplatin resistance cancer.s
can be given in higher doses - 2 x

Question 80

criteria of satraplatin?

Answer 80

must adhere to structure function relationship. show good water sol and relatively lipophillic

Question 81

what is the mechanism for drug resistance

Answer 81

Glutathion (GSH) coordinating to drug. Coordination of ligand in sq planar Pt complexes via an associative mechanism.

Question 82

how can Pt drugs be engineered to combat drug resistance?

Answer 82

Sterically hinder the Sq plane

Question 83

draw the structure of picoplatin and gives its benefits and cons?

Answer 83

slower substution than cisplatin and reacts slowly with DNA, but does fully platinate complex. Displays enhanced toxicity to cisplatin resistant cancers

Question 84

Can trans platinum drugs be therapeutic?

Answer 84

They do bind to DNA but are too labile so are deactivated.

Question 85

Draw a trans Pt drug that shows good in vivo activity even with cisplatin resistant cancers.

Answer 85

BBR3464

Question 86

Why do we expect multinuclear pT complexes to form different DNA lesions?

Answer 86

They are oligometallic and charged, also trans

Question 87

Even though multiuclear pt complexes are highly charged how do they cross cell membranes?

Answer 87

They are relatively lipophillic

Question 88

Even though multiuclear pt complexes are highly charged how do they cross cell membranes?

Answer 88

They are relatively lipophillic

Question 89

what do DNA binding show with BBR3464?

Answer 89

1. rapidly binds to DNA, the half life is 40 mins
2. shows bifunctional DNA binding
3. Forms more intrastrand lesion than cisplatin
4. also forms long range intrastrand lesions

Question 90

what is the problem with BBR3464?

Answer 90

Too active and has been liked to renal toxicity

Question 91

what are the therapeutic properties of cis-(DMSO)4RuCl2?

Answer 91

Shown modest antitumour activity and cos for shows modest activity against solid tumours. slight inhibition on metastasis. Shows no cross resistance with cisplatin

Question 92

How is Ru(II) binding switched on cancer cells?

Answer 92

Ru (III) preferentially transported by Fe carrier proteins. Hypoxic tissue is realtovely reducing due to low oxygen content. Ru(III) - Ru (II). Ru(II) with pi donor ligands are stabilised by back bonding.

Question 93

what are NAMI and KP - 1019?

Answer 93

prevent metasis

Question 94

What is the oxidation state of the metal in Nami and KP 1019

Answer 94

Ru(II) it is stabilised by reducing conditions

Question 95

what is the evidence that KP 1019?

Answer 95

As oxygen conc decreases binding to DNA increases

Question 96

Briefly describe how NAMI works?

Answer 96

Antimetastatic agent. Increases the thickness of connective tissues around tumor and its blood vessels

Question 97

What is the known about the physiological of NAMI

Answer 97

Only a small fraction of NAMI reaches a tumour
• Its activity is largely independent of intracell concentration
• Mechanism DOES NOT involve its DNA binding properties
• It stops cell dividing, prevents blood supply to tumour developing

Question 98

What is the known about the physiological of NAMI

Answer 98

Only a small fraction of NAMI reaches a tumour
• Its activity is largely independent of intracell concentration
• Mechanism DOES NOT involve its DNA binding properties
• It stops cell dividing, prevents blood supply to tumour developing

Question 99

What Ru(II) compounds are used in chemotherapy?

Answer 99

Ones that are facially coordinated found to be as cytotoxic as carboplatin. they bind to G bases in DNA and form monoadducts

Question 100

what are the features of DNA that makes them targetable?

Answer 100

Anionically charged phosphodiester backbone
Major and minor grooves
base pair stacks

Question 101

what are the three ways in which things bind to DNA

Answer 101

Electrostatic - DNA naturallt exists as a polyanion so cationic metals eg mg can form loose complimentary electrostatically interactions with polyamines in the phosphodiester backbone. little scope for binding sequence specifity

Groove Binding - molecules approach within the VDW contact and reside in DNA groove. Hydrophobic and/Hydrogen bonds play key role in binding and provide stabilisation. Major and minor groove binders are known they show high affinity and can display good sequence selectivity, without major structure change in DNA.

Intercalation - Polycyclic aromatic rings - get stacking between base pairs. This lengthens and untwists DNA

Question 102

Why use metals complexes in DNA binding?

Answer 102

1. charged so are water sol
2. Cationic so show enhanced DNA binding
3. Metal can acts as a scaffold and arrange ligands in optimal positions for DNA binding
4. Can introduce redox and photchemically functinalities to DNA binding system

Question 103

what are Possible medical/biotechnological applications of molecules that reversibly bind to DNA

Answer 103

New treatment of cancer and genetic disease
• Medical probes for specific sequence/structures of DNA.
•New diagnostic agents testing for specific sequences
• Perhaps even gene modulation

Question 104

what did early work with Ru(phen)3]2+ show about octahedral complexes and DNA binding

Answer 104

Cation binds DNA by hydrophobic contacts in major grrove and Phen may intercalate base stacks but the latter disproved
prefer to bind the right handed isomer

Question 105

what is the significance of [Ru(bpy)2(dppz)]2+

Answer 105

Showed high binding affinity to DNA but not specificit

These are DNA light switches they are not luminescent in solution until DNA added

Question 106

why is [Ru(bpy)2(dppz)]2+ not specific?

Answer 106

NH acceptor groups

Question 107

what forms does [Ru(phen)2(dppz)]2+ resolve into

Answer 107

Λ-form and Δ form both of which show different luminescent lifetimes

Question 108

how binding modes does the Λ-form of [Ru(phen)2(dppz)]2+ show

Answer 108

2 - major (binds perpendicular) and minor (binds parallel)

Question 109

what is the evidence that changing ancillary ligands can control DNA binding?

Answer 109

Adding methyl’s groups to [Ru(phen)2(dppz)]2+, the complex can not bind DNA. cause on unfavourable steric interactions between the ancillary groups and DNA

Question 110

why does the achiral derivative show the same affinity for binding DNA as [Ru(bpy)2(dppz)]2+ but is more specific?

Answer 110

Binds to GC rich DNA sequences due to favourable anciliary and DNA interactions

Question 111

describe the binding of [Rh(phen)2(phi)]3+

Answer 111

intercalate with the long axis of the phi ligand parallel to the long axis of the base pair.
Photoexcitation leads to redox cleavage of DNA at site of intercalation
binds with some sequence specificity (CCAG - 3`)
Slots into base pairs unlike dppz which binds at right angles

Question 112

what is the effect of adding hydrogen bond donors onto ancillary ligands in phi complexes

Answer 112

Get higher binding specifity with a preference for 5- CG -3 compared to analogues containing only S showed no preference

Question 113

The phen based ligand in this complex

contains a what group

Answer 113

guanadinium group - a moeity known to bind G N7 and O6 atoms. so these would target a more extended sequence

Question 114

what base pair sequences does the two different forms of the molecule able to recognise extended sequence bind to

Answer 114

Δ-form showed a significant preference for a 6
base pair sequence; 5’-CATCTG-3’, while Λ-
form recognised 5’-CATATG-3’

Question 115

what have Consequent studies Λ-form shown (extended sequences)

Answer 115

binds with affinities that are comparable to
transcription factors and can even selectively inhibit transcription factor binding when the target contains the 5’-CATATG-3’ sequence

Question 116

what is the complex containing the 5,6-
chrysinequinone diimine (chrysi) ligand
designed to be

Answer 116

too large to easily intercalate with normal base pairs so is used to target mismatched sites. The extra ring prevents binding to base pairs

Question 117

what are the three types of mismatch in DNA

Answer 117

wrong base so no base pair formed
XS base so there is a bulge in the backbone
Missing base - no bulge, DNA is still a duplex and backbone is right length.

Question 118

how are mismatched cells detected?

Answer 118

Mismatch recognized by insertion of the
intercalator.
= The rigid inserting ligand displaces the
flexible mismatch base-pair

Question 119

How can mismatch base pairs be used to treat cancer?

Answer 119

Complexes shown below are cytotoxic to cells

that are deficient in mismatch repair (~20% of solid cancers show this deficiency)

Question 120

why is it important to Understand the dynamic organisation and structure of biomolecules like DNA
within living cell.

Answer 120

will provide an insight into important cellular process and many genetically based diseases - including cancer

Question 121

What is required to image cells and organelles?

Answer 121

A stain

Question 122

What are the problems with current organic dyes?

Answer 122

1. Low water solubility
2. photbleaches easily - can kill cells and reduces time to look at cells
3. small stoke shifts
4. often toxic
5. Emission lifetime is slow, cant tell from indogenous flourphores

Question 123

why are metal better stains?

Answer 123

1. large stoke shift
2. more photstable
3. longer emission lifetimes as from triplet state

Question 124

how are complexes used to image quadruplex DNA

Answer 124

guanine can form tetrad structures, which may function in forming four stranded DNA. Using groove binding light switch complexes which are desogned to stain duplex and quadruplex DNA. They give different emission signals.

Question 125

What is the emission wavelength of quadruplex DNA?

Answer 125

620 - 640

Question 126

how can imaging probes be used in cytoxicity?

Answer 126

Intercalting light switch complexes, imaging propeties allow the mechanism of cytotoxicity to be easily probed.

Question 127

what did injections of hematoporphyrin lead to?

Answer 127

Led to florescence in tumours

Question 128

how does PDT work

Answer 128

Excitation of molecules can lead to many processes

Draw graph

Question 129

what is PDT used to treat?

Answer 129

To treat cancers and skin conditions

Question 130

what was found about cationic metalloporphyrins?

Answer 130

Cytotoxic to cancer in vitro. But DNA scission only observed when oxygen present so toxicity thought to be PD

Question 131

how are texaphyrins used in PD

Answer 131

Based on lanthanide Lu. previous Cd complexes have poor water solubility and are toxic.
texaphyrin are water soluble and non toxic, they have a absorption max at 730nm

Question 132

why are Pc being used as photosensitisers as PDT?

Answer 132

They have a strong absorption at 670nm

Question 133

how are Metalloporphyrins conjugates cytotoxic

Answer 133

Cisplatin/PDt conjugates. In the dark they are more cytotoxic than carboplatin and cisplatin. But when light is switched on they are even more cytotoxic (more so than Hp and cisplatin mixtures)

Question 134

what is the function of NO in the body

Answer 134

NO is a signalling molecule but high levels can become harmful.
Macrophages produce high local NO concentrations (>10 µM) which are cytotoxic to the pathogen/cancer
cells.
NO reacts with O to for N2O3 which initrosation agent attacking ammines and thiols.
NO also reacts with peroxide (macrophages produce this also). They form Peroxynitrile (O=NOO–) which is an oxidising agent capable of destroying most biomolecules

Question 135

How can NO be used in PDT

Answer 135

complexes will release NO in toxic levels when when photoexcited with long wavelength visible light.

Question 136

By describing the photo-induced processes involved, with the aid of diagrams outline why PDT requires these three components (presence of light, oxygen and a photosensitizer)

Answer 136

In the PDT process light photo-excites the sensitizer into a singlet state that then undergoes ISC into a triplet state. This activated excited state can react directly with biomolecules but better still is the sensitization of ground state triplet state dioxygen either into a reactive radical species (type I mechanism) or, even better again, into the reactive singlet state (type II mechanism). The final mechanism is preferential as the sensitizer acts a catalyst to generate singlet oxygen: