CHEMOTHERAPY OF NEOPLASTIC DISEASES
Outline, VPH 445

Topics

• Overview
• Cancer Biology
• Drugs

Overview

• Cancer chemotherapy challenging
• Often not curative
• Palliative treatment
• Importance of supportive therapy
• Cytotoxic drugs -- "toxic"
• Biological response modifiers -- much current research
• Expense

Factors determining therapeutic goals

Cancer Biology

Topics

• Therapeutic problem
• Tumor growth
• Tumor heterogeneity
• Cell Kill Hypothesis
• Resistance
• Modalities
• Toxicity

Therapeutic problem

• Selectivity
  • Must kill ALL cancer cells
    9 to 11 "log" kill
  • Minimal harm to normal cells
    <2 "log" kill!!!
  • Differences mostly in "rates"
• Moving target -- changes in sensitivity
  • Drug sensitivity changes during therapy
  • Cells resistant at outset may become predominant
• Key definitions -- Figure
  • [fig]Graph of results of chemotherapy
  • Cure -- Must kill ALL cancer cells
  • Remission (Complete response) -- Tumor no longer detectable
  • Induction regimen -- to induce remission
  • Maintenance regimen -- followup treatment to remove metastatic foci and microscopic remnants
  • Relapse -- tumor clinically detectable after prior remission
  • Palliative therapy -- improve quality of life
  • Curative therapy -- aimed at "cure" of cancer

Tumor growth

• Cytotoxic drugs most effective in rapidly growing tumors
  [fig] Figure (4-11, Shackney '93)
• Growth rate slows as tumor increases in size (Gompertzian Growth)
  [fig] Figure (4-1, Shackney '93)
• Growth rate (doubling time) determined by --
  • Production --
    • Fraction of tumor dividing
      Stem cells -- cells actively dividing
      Clonogenic cells -- cells that divide in culture
    • Cell cycle time
  • Loss -- Fraction of cells dieing
  • [fig] Figure -- Clinical Growth Rate -- Mathematical model
  • Cell cycle
    • G₁ phase -- highly variable
    • S phase -- 8-20 hr duration
    • G₂ phase -- ~3 hr cancer cells
    • M phase -- 1 hr
    • G₀ phase -- Not cycling
• Doubling Times and Growth Fractions of Some Humor Tumors
  

Cell Kill is First Order

• Skipper's Cell Kill Hypothesis
  "log"cell kill
• "Cure" only if all cells killed
• Killing is first order process
• Each treatment cycle kills same Fraction of cells
• Each treatment cycle kills different Number of cells
• Table: Example of values in cell-kill

Sources of Heterogeneity in Tumors

• Pharmacokinetic
• Kinetic
• Genetic

• [fig] Figure: Log Kill & Host Survival

Heterogeneity -- Pharmacokinetic

• Variation in Drug delivered to tumor cells
  • Blood supply
  • Necrosis
  • Route

Heterogeneity -- Kinetic

• Variation in Cell cycle time among cells
• Cells not all in same cell cycle-phase
• [fig] Figure: Cell cycle stages
• [fig] Figure: Bleomycin effect on different phases

Heterogeneity -- Genetic -- Resistance Mechanisms

• Defective activation
  • Cyclophosphamide requires metabolic activation
  • Methotrexate conversion to more active MTX-polyglutamate in cells
• Increased inactivation
  • e.g., aldehyde dehydrogenase -- cyclophosphamide to inactive metabolite
  • cell protective groups scavenge highly reactivte compounds -- sulfhydryl compounds -- glutathione, metallothionine
• Altered nucleotide pools
  • Can occur with antimetabolites
• Altered DNA repair
  • Repair mechanisms increased, i.e., ability to remove cross-links
  • Bleomycin and other DNA-directed drugs
• Altered target
  • Enzyme active, but less affinity for drug
  • Methotrexate
    • Dihydrofolate reductase changes
• Decreased target
  • decreased topoisomerase II
  • e.g., etoposide
• Gene amplification
  • Methotrexate (MTX)
    • Increase dihydrofolate reductase
    • Requires more MTX to block
• Decreased accumulation
  • Decreased uptake
    • Methotrexate -- carrier protein decreases
    • Mechlorethamine -- decreased choline carrier
    • Melphalan / leucine transport
  • Increased Efflux
    • Multidrug Resistance
    • usually alkaloids such as doxorubicin, etoposide, actinomycin D, vinca alkaloids
    • P-Glycoprotein (gP-170) in membrane, pumps drug out
    • Pump normally expressed in some cells e.g., bone marrow stem cells
    • Some drugs can reverse resistance -- e.g., calcium channel blockers

Treatment Modalities

• Adjuvant Therapy
• Combination Therapy
  • Minimizes development of resistance
  • Same or greater cell kill with less toxicity
  • Drugs should have different limiting toxicities
  • Timing can be important
  • Scheduled multiple drugs
    • Example: MOPP for Hodgkins
    • M: mechlorethamine; O: Vincristine (Oncovin); P: Procarbazine; P: Prednisolone
  • Alternating Combinations

Toxicities Frequently Observed

Tissues / responses

• Rapid growth rate tissues
  • Bone marrow suppression
  • GI toxicity (mucositis, stomatitis, etc.)
• Other
  • Anorexia and vomiting
  • Hypersensitivity
• See Brody, et. al., P 588-589 general and specific toxicities
• See Calabresi et al, '93, Table 21-1

Toxicities Related to Specific Drugs

• Renal
  • Cisplatin, Methotrexate (high dose)
• Hepatic
  • Folic acid antagonists (e.g., methotrexate)
• CNS
  • Vincristine (Oncovin^R)
• Cardiac
  • Doxorubicin (Adriamycin^R) and derivatives
• Long term toxicities
  • Types
    • Oncogenesis
    • Mutagenesis
    • Teratogenesis
  • Typical Drugs
    • Alkylating agents
    • Antitumor antibiotics
  • Need for care in handling

Drugs

Categories

• Antimetabolites
  • Folic Acid Analogs
    • Methotrexate, (MTX)
  • Pyrimidine analogs
    • Fluorouracil, (5-FU)
    • Fluorodeoxyuridine
    • Cytarabine
  • Purine analogs
    • 6-Mercaptopurine, (6-MP)
    • 6-Thioguanine, (6-TG)
• Alkylating agents
  • Nitrogen mustards
    • Mechlorethamine
    • Cyclophosphamide (Cytoxan^R)
    • Melphalan
    • Chlorambucil
• Natural products
  • Vinca alkaloids
    • Vincristine (Oncovin^R)
    • Vinblastine (Velban^R)
    • Vinorelbine (Navelbine^R)**
  • Epipodophylotoxins
    • Etoposide (VePesid^R, VP-16)
  • Taxol (Paclitaxel^R)
  • Antiumor antibiotics
    • Anthracyclines
      • Doxorubicin hydrochloride, (Adriamycin^R)
      • Daunorubicin
      • Idarubicin
      • Mitoxantrone
        • Actually an Anthracenedione and lacks sugar moiety
    • Bleomycin, (Blenoxane^R)
    • Dactinomycin (actinomycin D)
    • Mitomycin C
    • Plycamycin (Mithramycin)
• Miscellaneous agents
  • Cisplatin
  • Carboplatin
  • Asparaginase
  • Hydroxyurea
  • Mitotane (o,p'-DDD; Lysodren)
  • Anti-Estrogen (Tamoxifen citrate)
  • Corticosteroid (Prednisone)

Nucleic Acid Nomenclature

Antimetabolites

Group Characteristics

• Resemble NORMAL substrates
• Most inhibit DNA synthesis
• Some inhibit RNA synthesis and/or function
• Bone Marrow cell replication is profoundly inhibited
• GI toxicity great with some
• Highly cell cycle specific
  • Also "phase specific", e.g., S or M phase

Methotrexate

Structure

Mechanism of action

• Folic Acid Analogue
• Carrier transport into cell
• Binds strongly to DHFR to deplete THF
  • Decreases 1-carbon transfers in Purine synth.
  • Decreases [1-C-THF]intracellular which decreases dUMP dTMP
  • Therefore, decreases NUCLEIC ACID synthesis
• Forms polyglutamyl-MTX which traps MTX inside cell & inhibits thymidylate synthase
• [fig] Figure -- Mechanism of action

Adverse effects

• Dose limiting
  • Myelosuppression
    • Thrombocytopenia and Leukopenia
    • Nadirs 7-10 days after Rx, Recovery 14-21 days
  • GI toxicity
    • Oral mucositis is early sign of GI toxicity
    • Severe mucositis
    • Small bowel ulceration & bleeding
    • Diarrhea -- requires cessation to prevent perforation of gut
• Nephrotoxicity
  • Conventional doses, infrequent toxicity
  • High doses, toxicity can be severe
    • Precipitation of metabolites
    • Alkalinize urine & hydrate patient to dilute & increase solubility of metabolites
    • Leucovorin (folinic acid, N5-THF)
  • Reversed within 3 weeks spontaneously if exposure not prolonged
• Immunosuppression
• Hepatotoxicity
  • With chronic administration as in ALL of childhood and psoriasis Rx
  • Changes typical of portal fibrosis and cirrhosis.
• Listlessness, anorexia, nausea, vomiting
• Intrathecal administration
  • Acute meningeal irritation with attendant signs, some severe

Clinical Uses

• Broad range
• Well established
  • Acute Lymphoblastic Leukemia of childhood
  • Choriocarcinoma
  • Cancers of breast, bladder, and head & neck
• Useful in non-Hodgkin's lymphomas

Flurouracil, (5-FU)

Structure

• [fig] Figure -- Structure of 5-FU and Fluorodeoxyuridine

Mechanism of action

• Activated by conversion to nucleotide
• [fig] Inhibits DNA synthesis
  • Inhibition of Thymidylate synthase
  • Most important MOA in rapidly growing tumors (?)
• [fig] 5-FU Incorporated into RNA
  • Interfere with RNA processing - ALL types
  • May be most important MOA in slowly growing tumors

5-FU: Biotransformation

• Activation to active compounds
• Inactivation to dihydrofluorouracil
  • e.g., dihydrouracil dehydrogenase
    • rapid
    • high content in liver
    • Present in intestinal mucosa
    • Less in many GI tumor cells

Adverse effects

• Dose limiting
  • Bone marrow -- esp. with bolus admin.
    • Leukopenia & Thrombocytopenia
      • nadir 9-14 days after 5 days of Rx
      • recovery by day 21
  • GI Toxicity -- esp. with infusion admin.
    • usually Stomatitis & Diarrhea 4-7 days after Rx

Effect of route and schedule on adverse effects

• IV bolus
  • myelosuppression is dominant
  • Prolonged Rx, may cause megaloblastic anemia
• Continuous IV Infusion
  • Frequently produce, stomatitis, nausea, vomiting, and diarrhea
  • Hepatotoxicity (elevated transaminases)
  • myelosuppression less common

Effect of peak 5-FU concentration

• Acute, reversible cerebellar syndrome
  • somnolence, ataxia of trunk or extremities, unsteady gait, slurred speech, nystagmus
  • Regimens that produce high peak concentrations in CSF

Other adverse effects

• Hyperpigmentation of skin is frequent and may be accompanied by photosensitivity
• Toxic effect of radiation to skin may be enhanced
• Alopecia, acute and chronic conjunctivitis, and nail changes may be observed

Clinical Use of 5-FU

• Single agent
  • Palliative in advanced colorectal carcinoma
• Combination
  • Breast cancer
  • Carcinomas of ovary, stomach, pancreas
• Sequential MTX + 5-FU
  • Head and neck cancer
  • [fig] Figure showing MTX & FU on Thymidine kinase

Alkylating Agents

• Developed from nitrogen mustard war gases of WW I which were highly reactive vesicants
• First chemicals used for cancer Rx
• Not cell cycle specific, but still more active in dividing tissues
• "Radiomimetic" -- action on DNA resembles radiation

Mechanism of action

• [fig] Highly reactive -- form covalent bonds
  • Strong electrophilic -- carbonium ion intermediates
  • Intermediates react with nucleophiles to form covalent bonds, e.g.,
    • phosphate, amino, sulfhydryl, hydroxyl, carboxyl, and imidazole groups
• Consequences
  • Bi-functional agents
  • DNA-DNA strand and DNA-Protein cross-links
    • especially by reacting with 7-Nitrogen of guanine
  • Misreading of genetic code
    • Alkylation of guanine may shift electon configuration so it forms GT rather than GC pairs
  • DNA Chain breaks - labilized imidazole

Adverse effects of alkylating agents

• More toxic to bone marrow and gut than to liver and kidney, etc.
• Infertility to both males and females
• Mutagenic
• Carcinogenic

Tumor resistance

• Develops slowly & may require several genetic / biochemical changes
• Increased intracellular nucleophiles
  • metallothionein, glutathione
• Increased DNA repair systems
• Reduced drug accumulation
• Resistance not necessarily uniform across group

Clinical Uses

• Wide spectrum
• Lymphoreticular tissue tumors
• Limited activity against sarcomas

Cyclosphosphamide

Structure

• [fig] Structure of Cyclophosphamide

Mechanism of action

• Hepatic cytochrome P-450 system, enzymes phosphatase and phosphamidase are primary activators (hydrolyze P-N bond) to intermediate, aldophosphamide, which nonenzymatically breaks down to --
  • Phosphoramide mustard (bifunctional)
  • Acrolein

Clinical Pharmacology

• Oral bioavailability = 90-100%
• Not vesicant
• IV injection no local irritation
• Half-life --
  • cyclophosphamide -- 3-10 h
  • aldophosphamide -- 1.6 h
  • phosphoramide mustard -- 8.7 h
• Most metabolized-- < 14% unchanged in urine

Adverse effects

• Bone marrow suppression most imp.
  • leukopenia
  • thrombocytopenia
• Nausea and vomiting said to be rare

Sterile necrotizing hemorrhagic cystitis

• Acrolein is probable cause
• Associated with chronic administration
• Cause for stopping Rx
• Minimize
  • high water intake and take in AM
• Rx
  • Bladder irrigationwith thiol compounds
  • Systemic Rx with N-acetylcysteine and mesna

Mesna for Px & Rx of Cystitis

• Used prophylactically and therapeutically
• Mesna (2-mercaptoethansulfonate, Mesonex)
• injectable as inert disulfide which is reduced in renal tubules to mesna
• Mesna binds to and detoxifies urotoxc metabolites of cyclophosphamide and Ifosfamide

Clinical Applications

• Most widely used alkylating agent, in part due to availability of oral route
• Active lymphoproliferative diseases, e.g.,
  • Hodgkin's disease
  • Chronic lymphocytic leukemia
• Significant activity vs
  • multiple myeloma
  • ovarian, breast, small cell lung carcinoma
• Many combinations

Natural Products

Vinca Alkaloids

• Vincristine sulfate(Oncovin)
• Vinblastine sulfate (Velban)
• From periwinkle plant (Vinca rosea L)

Mechanism of action

• Uptake by energy dependent carrier
• Bind to tubulin in microtubules to cause their dissolution
  • Colchicine-like arrest in metaphase
  • Altered intracellular transport
• Contrast to Taxol which stabilizes tubules
• No cross resistance between vincristine and vinblastine

Adverse effects

• Severe vesicant
  • Must be careful of IV equipment to avoid slough
• Neurotoxicity
  • Mild sensory neuropathy with sensory impairment and paresthesia: Keep Rx
  • Severe paresthesias, loss of reflexes, ataxia, and muscle wasting: stop Rx
  • Constipation and abdominal pain - take laxatives
• Less hematologic effects than many other cytotoxic drugs
• Inappropriate ADH secretion

Uses

• Drug of choice for childhood leukemias in combination with prednisone
• Used for lymphoreticular neoplasms, carcinomas, and sarcomas

Antitumor Antibiotics

General characteristics

• from Streptomyces spp.
• All interact with DNA and/or RNA, but may also interact with other cellular substituents
• Schedule dependence
  • LESS "phase-specific" than antimetabolites
• Tissue necrosis is only generalizable toxicity
• All IV except bleomycin

Doxorubicin HCl (Adriamycin^R)

Mechanism of action

• Rigid, tetracyclic structure substituted with sugar -- daunosamine
• DNA topoisomerase II inhibitor
  • Crucial to DNA replication and transcription
• Traditional explanations of MOA
  • intercalates between base pairs of DNA and inhibits DNA-dependent RNA synthesis
  • Generates free radicals that cause membrane damage and DNA strand breaks

Resistance

• Alterations in Topoisomerase II act.
  • Relative importance not established
• Increased inactivation of radicals
  • Increase in glutathione-dependent enzymes, e.g., glutathione-peroxidase
  • Altered NADPH contents
• Increase drug efflux
  • Multi-drug resistance (MDR)
  • P-glycoprotein (gP-170) pump is product of mdr gene

Adverse effects

• Three categories of toxicity
  • Local toxicities
  • Acute toxicities
  • Chronic toxicity
• Local Toxicity -- Extravasation
  • Extravasation -- DON'T!
  • Severe local tissue necrosis to point of damaging underlying structures
  • If occurs, treat immediately
    • Remove blood from IV line
    • Apply ice, steroid cream
    • Locally adm. sodium bicarbonate and hydrocortisone
    • DHM3 (investigational) shows promise
• Local Toxicity -- Radiation Recall
  • Interaction of doxorubicin and radiation in some tissues to produce enhanced reactions
  • Reactions include
    • Skin: intensity from erhthema to ulceration and necrosis
    • Pulmonary: fibrosis and sloughing of esophageal mucosa
    • Heart, and intestinal mucosa may also be affected
• Acute Toxicities
  • Hematologic:
    • Leukopenia with nadir 7-10 days; recovery typically by 21 days
    • Thrombocytopenia and anemia less common
  • If give too fast
    • "Histamine-release" syndrome
    • Cardiac arrest preceded by ECG changes
• Chronic Toxicities
  • Cardiomyopathy and congestive heart failure
    • require cessation of Rx after cumulative dose of -- Human: 550 to 600 mg/m²
      Dog:: 250 mg/m²
    • Must maintain record of total dose
  • To Reduce incidence
    • Dexrazoxane (ZinecardR) Chelating agent for reducing incidence and severity of cardiomyopathy from Doxorubicin.

Clinical Indications

• Broad spectrum anti-cancer activity
• Hodgkin's disease, non-Hodgkin's lymphomas, sarcomas, acute, leukemia, and breast, lung, and ovarian carcinomas all responsive
• Activity observed in
  • bladder tumors, and carcinomas of prostate, thyroid, endometrium, head and neck, and other solid tumors

Dexrazoxane

• Chelating agent --
  • Derivative of EDTA that cross cell membranes
• May be converted intracellularly to "ring-opened" chelating agent that interferes with iron-mediated free radical formation
• Start after have reached 300 mg/m2
• Not use concurrently with initiation of FU, Doxo, Cyclophosphamide

Bleomycin

• Streptomyces verticillus produced mixture of small-molecular-weight copper-chelating glycopeptides

Mechanism of action

• To be active, must have Fe2+ replace Cu
• Has antitumor, antiviral, and antibacterial action
• DNA toxicity
  • binds to double- and single-stranded DNA
  • produces site-specific and non-specific single- and double-strand chain breaks
    • ratio single:double = 10:1
    • Cleaved at G-C and G-T sequences
  • DNA in open chromatin esp. sensitive
• Non-covalent interstrand links
• Inhib repair enzyme: DNA ligase
• Cell-cycle specific: most G2

Adverse effects

• Toxicity is UNIQUE-- no BM or GI
• Degraded by bleomycin hydrolase present most tissues except skin and lung
• Pulmonary fibrosis is dose limiting in approximately 10%
  • Stop Rx immediately
• Skin
  • desquamation, hyperpigmentation, and pruritic erythema

Clinical Uses

• Broad range of squamous cell carcnomas, including --
  • head and neck cancer
  • tumors of cervix, esophagus, skin, vulva, and lung
• Established against
  • germ cell testicular cancer
  • Hodgkin's disease, and non-Hodgkins L.
• Many combo Rx due to lack of bone marrow toxicity

Miscellaneous Drugs

Cisplatin (Platinol^R, cis-DDP)

Structure

• [fig] Structure of Cisplatin

Mechanism of action

• Enters cells by passive diffusion
• Aquated Cl- moieties react with N7 of guanine and other nucleophiles
• Intrastrand (rapidly) and Interstrand (slowly) crosslinks in DNA
• DNA - protein crosslinks
• Cell-cycle nonspecific, but may be most active in G1

Adverse effects

• Intractable, almost universal, nausea and vomiting
• Anaphylactic-like reactions
• Neurotoxicity
• Myelosuppression
  • mild compared to alkylating agents
  • thrombocytopenia (by day 7-9)
  • granulocytopenia (by day 17-19)
• Nephrotoxicity is dose-limiting
  • Dose related , cumulative, & irreversible
  • Primarily affects proximal tubuls
    • tubular degeneration & loss of brush border
    • necrosis and mineralization of tubular epithelial cells
  • Minimize
    • Hypersalination - forced infusion of hypertonic saline
    • Pre-Rx with thiol compounds may help (diethyldthiocarbamate (DDTC) or thiol sulfate)

Clinical Indications

• Effective in --
  • Testicular tumors
  • Ovarian carcinoma
  • Bladder tumors
  • Head and Neck
  • Breast cancer
  • Lung cancer
  • refractory non-Hodgkins lymphomas
• Radiosensitizer -- optimal use of this ???

L-Asparaginase (Elspar^R)

Mechanism of action

• Official name: L-asparagine amidohydrolase
• Hydrolyzes asparagine to aspartic and ammonia
• L-asparagine synthetase low in many malignant cells and must scavenge ASP from ECF

Adverse effects

• Major problem: Antigenicity of enzyme -- allergic reactions
  • experimenting with lipsomes and other means of delivery to decrease this
• Inhibition of protein synthesis
• Coagulation defect
  • decreased clotting factors
• Hepatotoxicity -- fatty metamorphosis
• Anorexia, nausea, vomiting

Clinical Indications

• Very narrow spectrum
• Almost exclusively used to treat
  • Acute lymphoblastic leukemia
• Used in combination with vincristine and prednisone
• May be useful in other T-cell or null-cell leukemias and lymphomas
• NOT effective for solid tumors

Tamoxifen citrate (Nolvadex^R)

• Antiestrogen
• Estrogen dependent disseminated mammary gland cancer
• Mild bone marrow suppression (anemia, leukopenia, anemia)
• Tumor rash
• Tumor pain

Corticosteroids, e.g., Prednisone

Adverse effects

• Iatrogenic adrenal hypocorticism
• Gastric ulcer, osteoporosis, increased susceptibility to infection
• Polydipsia and polyuria

Clinical indications

• Lymphoreticular neoplasms, brain tumors
• Secondary complications of cancer -- mood elevation, stimulate appetite, decrease reaction to dying cells

References