40
CANCER CHEMOTHERAPY PRINCIPLES DR RASHA HAGGAG

Cancer chemotherapy

Embed Size (px)

Citation preview

Page 1: Cancer chemotherapy

CANCER CHEMOTHERAPY

PRINCIPLES

DR RASHA HAGGAG

Page 2: Cancer chemotherapy
Page 3: Cancer chemotherapy

Characteristics of Cancer Cells

• The problem:

– Cancer cells divide rapidly (cell cycle is accelerated)

– They are “immortal”– Cell-cell communication is altered– uncontrolled proliferation– invasiveness – Ability to metastasise

Page 4: Cancer chemotherapy

Cell Cycle = Growth, Division

Page 5: Cancer chemotherapy
Page 6: Cancer chemotherapy

• After completion of mitosis, the resulting daughter cells have two options:

• (1) they can either enter G1 & repeat the cycle or • (2) they can go into G0 and not participate in the cell

cycle.• The ratio of proliferating cells to cells in G0, is called

the growth fraction.

• A tissue with a large percentage of proliferating cells & few cells in G0 has a high growth fraction.

• • Conversely, a tissue composed of mostly of cells in G0

has a low growth fraction.

Page 7: Cancer chemotherapy
Page 8: Cancer chemotherapy

• Cell Cycle Specific Drugs:

• Antimetabolites• Bleomycin peptide antibiotics• Vinca alkaloids

• Cell Cycle non-Specific Drugs:

• Alkylating agents• Antibiotics (Dactinomycin)• Cisplatin

Chemotherapeutic Agents

Effective for high growth-fraction-malignancies, such as hematologic cancers.

Effective for both low-growth (solid tumors) and high growth fraction malignancies

Page 9: Cancer chemotherapy

Log kill hypothesis

• According to the log-kill hypothesis, chemotherapeutic agents kill a constant fraction of cells (first order kinetics), rather than a specific number of cells, after each dose

1. Solid cancer tumors - generally have a low growth fraction thus respond poorly to chemotherapy & in most cases need to be removed by surgery

2. Disseminated cancers- generally have a high growth fraction & generally respond well to chemotherapy

Page 10: Cancer chemotherapy

Log kill hypothesis:

Page 11: Cancer chemotherapy

Clinical Implications of Fractional Cell Kill

Page 12: Cancer chemotherapy

Role of Chemotherapy in Cancer Treatment

(1) Metastatic Cancer: Palliative or

Curative Chemotherapy

(2) Adjuvant Chemotherapy:

to eradicate or control micro-metastasis

(3) Neo-adjuvant Chemotherapy:

to make Surgery of RT possible

to alleviate surgical damage

to eradicate micro-metastasis

(4) Hematological Malignancies:

Primary Treatment

Page 13: Cancer chemotherapy

ANTICANCER DRUGS

Page 14: Cancer chemotherapy

1. Alkylating agents:

• Major interaction: Alkylation of DNA

• Binds to nucleophilic groups on various cell constituents. Including DNA

• These drugs react with carboxyl, sulfhydryl, amino, hydroxyl, and phosphate groups of cellular

constituents. • Primary DNA alkylation site: N7 position of guanine

(other sites as well) • Major Toxicity: bone marrow suppression

Chemotherapeutic Agents

CyclophosphamaideCarboplatinCisplatinOxaliplatinDacarbazine

Page 15: Cancer chemotherapy

Chemotherapeutic Agents2. Antimetabolites:

•Structurally related to normal compounds that exist within the cell.

•Interfere with the availability of normal purine or pyrimidine nucleotide precursors, either by inhibiting their synthesis or by competing with them in DNA or RNA synthesis.

•Their maximal cytotoxic effects are in S-phase and therefore are cell-cycle specific.

5-Fluoro UracilGemcitabineCyterabineMethotrexate

Page 16: Cancer chemotherapy

3. Microtubule Inhibitors:

• These are plant-derived substances .

• Cause cytotoxicity by affecting the equilibrium between the polymerized and depolymerized forms of the microtubules.

• Vinca alkaloids inhibit microtubule polymerization and increase microtubule disassembly. The mitotic spindle apparatus is disrupted, and segregation of chromosomes in metaphase is arrested.

Chemotherapeutic Agents

Vinca AlkaloidsVincristine VinblastineVinorelbine

TaxanesPaclitaxelDocetaxel

Page 17: Cancer chemotherapy

4. Antineoplastic Antibiotics:

• Interacts with DNA, leading to disruption of DNA function.

• Also Inhibit topoisomerases (I and II) and produce free radicals.

• Cell-cycle nonspecific.

• Eg: Actinomycin D binds with double-stranded DNA and blocks the action of RNA polymerase, which prevents DNA transcription.

Chemotherapeutic Agents

BleomycinDoxorubicinDactinomycinDaunorubicin

Page 18: Cancer chemotherapy

5. Hormonal Agents:

• Commonly involves the use of glucocorticoids.• Direct antitumor effects are related to their

lympholytic properties;.• Glucocorticoids can inhibit mitosis, RNA synthesis,

and protein synthesis in sensitive lymphocytes.

• Considered cell-cycle nonspecific . • Resistance to a given glucocorticoid may develop

rapidly and typically extends to other glucocorticoids.

Chemotherapeutic Agents

PrednisoneTamoxifenEstrogensFlutamideNilutamideBicalutamide

Page 19: Cancer chemotherapy

• Antibodies that are made in the lab rather than by a person's own immune system.

• Directed at specific targets and often have fewer adverse effects.

• Designed to recognise and find specific abnormal proteins on cancer cells.

• Each monoclonal antibody recognizes one particular protein.

Chemotherapeutic Agents

Rituximab TrastuzumabCetuximabBevacizumab

6. Monoclonal Antibodies:

Page 20: Cancer chemotherapy

• Three types of monoclonal A-bodies:

1. Trigger the immune system to attack and kill cancer cells. E.g. Rituximab (Mabthera)

2. Stop cancer cells from taking up proteins E.g. Trastuzumab (Herceptin).

3. Carry cancer drugs or radiation to directly to cancer cells These are called conjugated MABs.

E.g. Ibritumomab (Zevalin)

Chemotherapeutic Agents

Rituximab TrastuzumabCetuximabBevacizumab

Page 21: Cancer chemotherapy

Combination Chemotherapy

• Rationale:– minimize resistance– maximize synergy/additivity– avoid drugs of overlapping toxicity– biochemical considerations

Page 22: Cancer chemotherapy

Combination Chemotherapy

• Rationale:–biochemical considerations:

• addition of an agent to overcome drug resistance (eg MDR inhibitor & vinca alkaloid)

• cooperative inhibition (eg leucovorin & 5FU)• inhibition of drug breakdown (eg DPD inhibitor

& 5FU)• rescue host from toxic effects of drug (eg

leucovorin following high-dose methotrexate)

Page 23: Cancer chemotherapy
Page 24: Cancer chemotherapy

ROUTES OF ADMINISTRATION

• Intravenous • Oral• Intraperitoneal Therapy• Intrathecal and Intraventricular Therapy• Intra-arterial Therapy• Prolonged Intravenous Infusion Chemotherapy• Other Routes of Administration: Intravesical therapy

Intrapleurally

Page 25: Cancer chemotherapy

Dosing Chemotherapeutics

• Body surface area• mg/kg• Total dose• Dose to pharmacokinetic target

– AUC.– Therapeutic monitoring laboratory capability

required.

Page 26: Cancer chemotherapy

• DRUG INTERACTIONS WITH CHEMOTHERAPEUTIC

AGENTS

Page 27: Cancer chemotherapy

Interactions with METHOTREXATE

• Aspirin, Cotrimoxazole, Penicillin, Nsaids (Indomethacin, Ketoprofen);

Inhibition Of Tubular Secretion Of Methotrexate :

Prolonged Excretion Of Methotrexate And Enhanced Toxicity.

Page 28: Cancer chemotherapy

Interactions with 6-MERCAPTOPURINE

• 6-mercaptopurine (6-MP) or azathioprine with ALLOPURINOL.

• 6-MP (or azathioprine) toxicity (thrombocytopenia, granulocytopenia) is enhanced and may be fatal.

• The dose of 6-MP or azathioprine should be decreased to one-third to one-fourth the normal amount when allopurinol is used concurrently

Page 29: Cancer chemotherapy

Interactions with PHENYTOIN

• The initial decrease in phenytoin concentration shortly after receiving various chemotherapeutic agents and dose increase leads to phenytoin toxicity.

• Phenytoin should have blood concentrations measured 24-72 hours after receiving chemotherapy and adjust the dose accordingly.

Page 30: Cancer chemotherapy

TOXICITIES OF SOME ANTICANCER

DRUGS

Page 31: Cancer chemotherapy

ADR of Antineoplastic Drugs in Humans Tissue Undesirable Effects

Bone marrow Leukopenia and resulting infections

Immunosuppression

Thrombocytopenia

Anemia

GI tract Oral or intestinal ulceration

Diarrhea

Hair follicles Alopecia

Gonads Menstrual irregularities, including premature

menarche; impaired spermatogenesis

Wounds Impaired healing

Fetus Teratogenesis (especially during first trimester)

Page 32: Cancer chemotherapy

Distinctive Toxicities of Some Anticancer DrugsToxicity Drug(s)

Renal Cisplatin,* methotrexate

Hepatic 6-MP, busulfan, cyclophosphamide

Pulmonary Bleomycin,* busulfan, procarbazine

Cardiac Doxorubicin, daunorubicin

Neurologic Vincristine,* cisplatin, paclitaxel

Immunosuppressive

Cyclophosphamide, cytarabine, dactinomycin, methotrexate

Other Cyclophosphamide (hemorrhagic cystitis); procarbazine (leukemia); asparaginase* (pancreatitis)

*Less Bone marrow suppression – “marrow sparing”

Page 33: Cancer chemotherapy

Prevention or Management of Drug Induced toxicities

• The toxicities of some anticancer drugs can be well anticipated and hence be prevented by giving proper medications

E.g. • mesna is given to prevent hemorrhagic

cystitis by cyclophosphamide• Dexrazoxane, is used to reduce the risk of

anthracycline-induced cardiomyopathy

Page 34: Cancer chemotherapy

•Dose Modifications

Page 35: Cancer chemotherapy

Dosage Modification for Myelosuppression

PLATELET COUNT(x 109/L)

ABSOLUTE NEUTROPHIL (ANC)*(x 109/L)

> 1.8 1.5-1.8 1.0-1.5 <1.0

> 10070-10050-70<50

100%75%50%0%

75%75%50%0%

50%50%50%0%

0%0%0%0%

Page 36: Cancer chemotherapy
Page 37: Cancer chemotherapy

• BCCA Protocol Summary for Adjuvant Therapy for Breast Cancer:

using Doxorubicin and Cyclophosphamide

Page 38: Cancer chemotherapy
Page 39: Cancer chemotherapy
Page 40: Cancer chemotherapy