Chemotherapy of cancer

Cancer is basically a disease of cells characterized by a shift in the control mechanisms that govern cell proliferation and differentiation.

Cells that have undergone euplastic transformation usually express cell surface antigens that may be of normal fetal type, may display other signs of apparent immaturity, and may exhibit qualitative or quantitative chromosomal abnormalities, including various translocations and the appearance of amplified gene sequences.

Such cells proliferate excessively and form local tumors that can compress or invade adjacent normal structures.

A small subpopulation of cells within the tumor can be described as tumor stem cells. They retain the ability to undergo repeated cycles of proliferation as well as to migrate to distant sites in the body to colonize various organs in the process called metastasis.

Such tumor stem cells thus can express clonogenic or colony-forming capability.

Tumor stem cells often have chromosome abnormalities reflecting their genetic instability, which leads to progressive selection of sub clones that can survive more readily in the multicellular environment of the host.

Quantitative abnormalities in various metabolic pathways and cellular components accompany this neoplastic progression. The invasive and metastatic processes as well as a series of metabolic abnormalities resulting from the cancer cause illness and eventual death of the patient unless the neoplasm can be eradicated with treatment

Characteristics of cancer cells

1. Clonal origin
2. Immortality
3. Uncontrolled proliferation
4. Dedifferentiation
5. Invasiveness
6. Metastasis

      5.   Genetic instability

Cancer cell cycle

An understanding of cell- cycle kinetics is essential for  the proper use of anticancer drugs

Many of the potent cytotoxic agents act at specific phases of the cycle and therefore, have activity only against cells that are in the process of division

1. S phase (DNA Synthesis )

     In which synthesis of DNA occurs

     The cellular content of DNA doubles

2. G1 or Pre- DNA

     Synthetic phase in which cellular components required for DNA synthesis are  

     synthesized

      Proteins and RNA are synthesized for specialized cell functions

      In late G1, a burst of RNA syntheses occurs and many of the  enzymes necessary for  

      DNA syntheses are manufactured

3. G2 or Post DNA synthesis phase 

    DNA synthesis ceases, protein and RNA synthesis continues and the micro tubular

    precursors of the mitotic spindle are produced

4. M- phase or  Mitosis

     Mitosis occur G1 and G2 phase - Differentiation

     In the M phase , the rates of protein and RNA synthesis diminish abruptly while the

     genetic material is segregated into daughter cells.

     After completion of mitosis, the cells enter either the  G0  or the G1 phase

5. G0 phase  

     After mitosis cell may re-enter into cell- cycle or undergo in the resting phase

     Cells are generally programmed to perform specialized functions

Causes of cancer

The following factors have been implicated in the etiology of cancer

1. Viruses such as Epstein- Bari virus (EBV) , hepatitis – B virus (HBV) and human papilloma virus(HPV)
2. Environmental and occupational hazards such as exposure to ionizing and UV radiation and exposure to various chemical carcinogens like azodyes, asbestos, benzene and polyvinyl chloride
3. Diet and habits such as high fat and low- fiber diet , tobacco smoking and alcohol consumption
4. Genetic factors such as inherited genetic mutations expression of oncogenes and repression of tumor suppressor gents
5. Use of drugs like immunosuppressants and some alkylating agents 

Cancer chemotherapy

Cancer is one of eh major causes of death. The treatment of cancers is still unsatisfactory due to creation characteristics of the cancer  cells- like capacity for uncontrolled proliferation, invasiveness and metastasis

Moreover the cancer cells are our own cells unlike microbes which means that , drugs which, destroy these cells also can affect normal cells

The host defense mechanisms which help us in infections is not doing so in cancers as these cancer cells are also host cells

The cancer cells can be in a resting phase during which they are not sensitive t o anticancer drugs but can star multiplying later – resulting in recurrence .

These features have made cancer chemotherapy more difficult

Principles of cancer chemotherapy

Cancer chemotherapy is primarily used to induce and maintain a remission or response according to the following general principles

1. Drugs are used in combinations to increase efficacy inhibit the development of

    resistance and minimize overlapping toxicities

2. Drugs that produce a high –fraction cell kill are preferred

3. Drugs are usually given intermittently but in high doses. This is less

    immunosuppressive and generally more effective than continuous low-dose regiments

4. Toxicity  is considerable and frequents blood counts and intensive clinical supports are

    Essential

5. Treatment usually needs to be prolonged  

General adverse effects of anticancer drugs

Most anticancer drugs act on the rapidly multiplying cells, they are also toxic to the normal rapidly multiplying cells in the bone marrow, epithelial cells, lymphoid organs and gonads

The common adverse effects are

1. Bone marrow depression

    Resulting in leucopenia, anemia, thrombocytopenia and in higher doses- a plastic

    anemia, in such patients , infections and bleeding are common

2. Other effect

    Alopecia , reduced spermatogenesis in men and amenorrhea in women

3. Immediate adverse effects

    Nausea ,vomiting   & diarrhea are very common with most

    cytotoxic drugs . Prior treatment with powerful antiemetics is required

4. Psychiatric morbidity

5. Teratogeniciy

    All cytotoxic drugs are teratogenic and therefore contraindicated in

    pregnancy

6. carcinogenicity

    Cytotoxic drugs themselves may cause secondary cancer

    Eg- Leukemia’s are common after treatment of Hodgkin’s lymphoma

   

4. When the patient is asymptomatic with slow growing , incurable tumors , in which

   case chemotherapy should be postponed until symptoms require palliation

Clinic use of cytotoxic agents

Chemotherapy is used in the following circumstances

1. To cure certain malignancies

2. To palliate symptoms in patients with disseminated cancer when the potential benefits

    of treatment exceed the side effects of treatment

3. To treat asymptomatic patients

    

    A. When the cancer is aggressive and treatable ( acute leukemia small cell lung

          cancer)

  

    B. When treatment has been proved to decrease the rate of relapse and increase the

         disease –free interval or increase the absolute survival (stages 1 or 11 breast

         carcinoma and estrogenic sarcoma)

4. To allow less mutilating surgery by treating first with chemotherapy alone or in

    combination with radiotherapy

Classification of anti- cancer drugs

1.Alkylating agents

   A. Nitrogen mustards

        Mechlorethamine, cyclophosphamide,Chlorambucil, Melphalan

   B. Ethyleminies

        Thio-TEPA

   C. Alkyl sulfonate

        Busulfan

   D. Nitrosoureas

       Carmusstine, Lamustine, Samustine

   E. Triazine

        Dacarbazine

11. Anti-metabolites

     A. Folate antagonist

          Methotrexate

     B. Purine antagonist

          6- Marcapto-purine

    C. Pyrimidine antagonist

          5-Fluroro-uracil, cytarabine

111. Antibiotics

        Doxorubicin , Daunorubicin,  Dactinomycin  , Bleomycin, Mitomycin-C,  

        Mitoxantrone  

1V. Vinca alkaloids

        Vincristine, Vinblastin

V .Taxanes 

          Paclitaxel, Docetaxel

V1. Epi-podophyllotoxin

         Etoposide

V11 . Enzymes

       L- Asparaginase

V111 . Radioactive isotopes

         Radioiodine, Radio gold, Radio phosphorus

1X  . Hormones

      Glucocorticoids, Oestrogens,  Antioestrogens, Progestins, Androgens, Antiandrogens,

X. Miscellaneous

     Hydroxyurea, Cisplatin, Carboplatin, , procarbazine, Mitotane Tretinoin

 

 

1.Alkylating agents

E.g

Mechlorethamine, cyclophosphamide,Chlorambucil, Melphalan , Busulfan

Mechanism of action

Alkylating agents  compounds contain chemical groups that can form covalent bonds with particular nucleophilic substances in the cell

In neutral or alkaline solutions , they undergo intermolecular cyclization to form a highly reactive ethylene imonium cation (quaternary ammonium compound )and releasing the chlorine

The strained ring of the ethylene imonium intermediate opens to form a reactive carbonium ion

Such ions are highly reactive and react instantaneously with an electro donor such as amine,  hydroxyl or sulfhydroyl groups

Most of the cytotoxic anticancer alkylating agents are bifuctional means they have two alkylatng groups

The nitrogen at position 7 (N7) of guanine, being strongly nuclophilic, is probably the main molecular target for alkylaton in DNA to give 7-alkyguanine

The N7 being converted to a quaternary ammonium nitrogen

These reaction can then be repeated with the other CH₂ CH₂ Cl to give a crosslink 

A bifuctuional agent ,being able to react with two groups, can cause intra or inter-chain cross-linking

Cross linking can cause defective replication through pairing of alkyl guanine and thymine, leading to substitution of AT for GC or it can cause excision of guanine and chain breakage

This can interfere not only with transcription but also with replication which is probably the critical effect of anticancer alkylating agents

 

Mechanism of alkylation of DNA guanine. A bis(chloroethyl)amine forms an ethyleneimonium ion and a carbonium ion that react with a base such as N7 of guanine in DNA, producing an alkylated purine. Alkylation of a second guanine residue, through the illustrated mechanism, results in cross-linking of DNA strands

Cyclophosphamide

 

Mechanism of action

This is a nucleophilic alkylating agent which inhibits the DNA synthesis

Metabolism

Native drug is inactive and requires activation by liver to form an aldehyde that decomposes in plasma and peripheral tissues to yield acrolein and an alkylating metabolite ( Phosphoramide mustard)

The liver also metabolizes  to metabolites ti inactive compounds

Drugs that induce microsomal enzymes (ex – barbiturates ) may enhance toxicity , liver disease may decrease toxicity

Active and inactive metabolites are excreted in urine

Administration

The drug should be administered with a large volume of fluid in the morning or early afternoon to avoid cystitis

Dose modification may be required for hepatic or renal function impairment

Drug interactions with warfarin are known to prolong the prothrombin time and with succinyl choline to increase neuromuscular blockade

 

Toxicity

Alopecia

Bone marrow depression resulting in thrombocytopenia

Hepatotoxicity

Cystitis and bladder carcinoma

Preparation

Tab – 50 mg

Injections -100mg/gial, 200mg /vial,  599mg/vial

Dosage

Cyclophosphamide is frequently employed as part of combination chemotherapy regimens. Some common doses are 0.5 g/m²     intravenously every 3 weeks or 50- 200 mg/m² orally for 4 days every 28 days

Uses

Autoimmune disorders like SLE, rheumatoid arthritis , Wagener’s granulomatosis and other systemic vasculitis

Ifosfamide

Mechanism of action

Mechanism is alkylation and DNA cross-linking and chain breakage.

Metabolites are similar to cyclophosphamide but not cross-resistant

This is a nucleophilic alkylating agent which inhibits the DNA synthesis

Metabolism

Inactive until activated by hepatic microbial enzymes like cyclophosphamide, the drug undergoes hepatic activation to an aldehyde form that decomposes in plasma and peripheral tissues to yield acrolein and its alkylation metabolites

Acrolein is highly toxic to urothelial mucosa

The chloroacetaldehyde metabolite may be responsible for much of the neurotoxic effects, particularly in patients with  renal dysfunction.

Drug metabolites are excreted in urine

Toxicity

Alopecia

Nausea , vomiting, Neurotoxicity

Dizziness, confusion, ataxia & coma

Preparation

Injections -1g vial

Dosage

1000 – 1,200 mg/m² intravenously over 30 minutes for 5 days every 3 – 4 weeks

 

Uses

Lymphomas, sarcomas and relapsed testicular carcinoma

Nitrosoureas

E. g

Carmusstine, Lamustine, Samustine

 

Mechanism of action

Mechanism is alkylation of DNA and RNA

DNA crossing ,inhibition of DNA polymerase, DNA repair and RNA synthesis

Metabolism

It is highly lipid= soluble drugs that enter the brain. Rapid spontaneous decomposition to active and inert products , the drugs are also metabolized. Most of the intact drugs and metabolic products are  excreted in urine

Toxicity

Dose limiting

Myelosuppressions prolonged, cumulative and substantially aggravated by concurrent radiation therapy

Adverse effects

Nausea and vomiting can last up to 8  24 hours

These causes local pain during injection or it can also cause hypotension if injected too rapidly. It can also cause stomatitis , diarrhea, alopecia

Administration

It is supplied as 100 mg vials or 10, 40 and 100 mg capsules

Dosage

Carmustine  - 150 – 200 mg/m2 intravenously every 6-8 weeks

Lomustine     - 100 – 130 mg/m2 orally every 6 – 8 weeks

Uses

Brain cancer, lymphomas, multiple myeloma, melanoma and some carcinomas
 

11. Anti-metabolites

     A. Folate antagonist

        Eg- Methotrexate

Methotrexate

  

Methotrexate

Mechanism of action

Methotrexate (MTX) is a folic acid antagonist that binds to the active catalytic site of dihydrofolate reductase (DHFR), interfering with the synthesis of the reduced form that accepts one-carbon units.

Folic acid is required in the synthesis for thymidylate (pyrimidine) and purine nucleotides and for DNA synthesis

Methotrexate resembles folic acid and competes with it at the active site of the enzyme dihydro folate recuctase (DHFR)

The affinity of methotrexate for this sites is 100000 times greater than that of dihydrofolate

The enzyme binds methotrexate with high affinity, and at pH 6.0, virtually no dissociation of the enzyme-inhibitor complex occurs .

At physiologic pH, reversible competitive kinetics occur

By blocking this step, methotrexate prevents nucleic acid synthesis and causes cell death

Metabolism

It is given orally, IV or intrathecally.

50 – 70% OF methotrexate is bound to plasma protein particularly albumin and alterations in plasma binding affect the pharmacokinetics of the drug

It is partly metabolized by the gut flora

About 80 – 95 % of the drug finally undergoes renal excretion either unchanged or as metabolites

Dose

Methotrexate Tab  - 2.5 mg,

Inj – 5 ml

Drug interactions

Probeneid and salicylate increase methotrexate toxicity by competing for renal tubular secretion while simultaneously displacing it from plasma albumin binding sites

Furosemide and high dose vitamin C also block renal excretion

Gentamicin and cisplatin increase the toxicity of methotrexate by compromising renal excretion

Drug adverse effects

Nausea, vomiting , diarrhea , dermatitis , excessive lacrimation renal tubular necrosis, renal dysfunction  liver cirrhosis &osteoporosis

Uses

It is used in the treatment  of acute leukaemias, breast cancer and soft tissue sarcomas

It is also used in rheumatoid arthritis and psoriasis

B. Purine antagonist

          6- Marcapto-purine,  6-Thioguanine, Allopurinol

Mercaptopurine (6-MP)

 

Mercaptopurine (6-MP)

 

It  was the first of the thiopurine series found useful as an anticancer drug.

Mechanism of action

6-MP, 6-TG and azathioprine are structural analogues of hypoxanthine and are converted by hytpoxanthine and are converted by hypoxanthine- guanine phosphoribosyl transfere into the ribonucleotides which inhibit biosynthesis of adenylic and guanylic acid from inosinic acid and thereby suppress DNA synthesis

Like other thiopurines, it must be metabolized by hypoxanthine-guanine phosphoribosyl transferase (HGPRT) to the nucleotide form (6-thioinosinic acid), which in turn inhibits a number of the enzymes of purine nucleotide interconversion.

Pharmacokinetics

They are well absorbed from the gut, metabolized by xanthine oxides in the liver and excreted as metabolites

Allopurinol inhibits xanthine oxidase and increases the toxicity

Mercaptopurine is used primarily in the treatment of childhood acute leukemia, and a closely related analog, azathioprine, is used as an immunosuppressive agent 

 

Drug interaction

Anticoagulant action of warfarin may be inhibited by mercaptopurine. Effect influenced by allopurinol

Dose

2.5 mg/kg/day  orally

Adverse drug reaction

Bone marrow depression is the chief toxicity . Side effects also include nausea, vomiting , diarrhea& hepato toxicity

Therapeutic uses

6- MP is given orally for the treatment of acute lymphatic leukemia and in chronic myeloid leukemia refractory to busulfan

Thioguanine (6-TG)

Mechanism of action

It inhibits several enzymes in the purine nucleotide pathway.

A variety of metabolic lesions are associated with the cytotoxic action of the purinethiols.

These include inhibition of purine nucleotide interconversion; decrease in intracellular levels of guanine nucleotides, which leads to inhibition of glycoprotein synthesis; interference with the formation of DNA and RNA; and incorporation of thiopurine nucleotides into both DNA and RNA.

Dose

2  mg/kg/day  orally

Adverse effects

Myelo- suppression, immunosuppressant & hepatotoxicity

Uses

 6-TG has a synergistic action when used together with cytarabine in the treatment of adult acute leukemia.

Azathioprine

Suppresses cell mediated immunity and is used mainly for immunosuppression in rheumatoid arthritis , organ transplantation

Adverse effects

In adddition to those decreined earlier , hyper- uricaemia may occor

 

C. Pyrimidine antagonist

   

E.g

 5-Fluroro-uracil, cytarabine

5- Fluroro –uracil is a fluorine substituted analogue of uracil

Cytarabine is an analogue of cytidine in which robose has been replaced by arabinose

5- Fluorouracil

5-Fluorouracil (5-FU) is a prodrug and undergoes a complex series of biotransformation reactions to ribosyl and deoxy - ribosyl nucleotide metabolites.

5 – FU is converted in the body to its ribonucleotide which inhibits the enzyme thymidylate synthetase and blocks the formation of thymidylic acid , a crucial precursor of DNA

 

Pharmacokinetics

Fluorouracil is normally given intravenously and has a short metabolic half-life on the order of 15 minutes.

It is not administered by the oral route because its bioavailability is erratic due to the high levels of the breakdown enzyme dihydropyrimidine dehydrogenase present in the gut mucosa.

Dose

15mg/kg/d IV for 5 days by 24 hrs infusion. 15 mg/kg weekly 1V        

Drug interactions

May increase the waffarin action. Its action may be reduced by allopurinol

Adverse effects

Nausea, vomiting, diarrhea, alopecia, bone marrow depression, &  anorexia

 

Uses

A cream incorporating fluorouracil is used topically for treating basal cell cancers of the skin.

Fluorouracil is the most widely used agent for the treatment of colorectal cancer, both as adjuvant therapy as well as for advanced disease.

In addition, it has activity against a wide variety of solid tumors, including cancers of the breast, stomach, pancreas, esophagus, liver, head and neck, and anus

Cytarabine

Mechanism of action

Cytarabine  is an S phase-specific antimetabolite that is converted by deoxycytidine kinase to the 5'-mononucleotide (AraCMP).

AraCMP is further metabolized to the triphosphate (AraCTP), which competitively inhibits DNA polymerase ,blocks the generation of cytidilic acid and  results in blockade of DNA synthesis.

Cytarabine is also incorporated into RNA and DNA.

Pharmacokinetics

After intravenous administration, the drug is cleared rapidly, with most being deaminated to an inactive form.

The ratio of the anabolic enzyme deoxycytidine kinase to the inactivating catalyst cytidine deaminase is important in determining the cytotoxicity of cytarabine.

In view of cytarabine's S phase specificity, the drug is highly schedule-dependent and must be given either by continuous infusion or every 8–12 hours for 5–7 days.

Its activity is limited almost entirely to treatment of acute myelogenous leukemia, for which it is a major drug

Dose

100 mg/m² by continuous infusion given for 5 – 10 days

Drug interaction

Reduces plasma concentration of digoxin , antagonizes Gentamycin

Drug  adverse effects

Nausea , vomiting, alopecia , bone marrow depression ,stomatitis &  cerebral ataxia

Uses

It is used  in the treatment of acute leukemia , Refractory disease & leukaemic meningitis

 Gemcitabine

Gemcitabine is phosphorylated initially by the enzyme deoxycytidine kinase and then by other nucleoside kinases to the di- and triphosphate nucleotide forms, which then inhibit DNA synthesis.  

Mechanism of action

It is a synthetic pyrimidine nucleoside and cytarbine analogue

It is metabolized intravellularly to active diphosphate and triphosphate nucleosides

It inhibits DNA synthesis and induce apoptosis and is primarily active against cells in the S- phase but may also cause cellular arrest at the G1 – S border

Pharmacokinetics

It is infused  IV . It is deaminated to difluoro-deoy-uridie, which is not cytotoxic

It is excreted in urine

Dose

1000mg /m² IV  by 30 mints infusion on days 1,8 and 15 of each 28 day cycle

Drug interactions

With Alcohol produces GI irritation

Adverse effects

Myelo- suppression is the dose – limiting toxicity of gemcitabine

Other toxicities include nausea, vomiting , alopecia, rash and flu like syndrome

Uses

Gemcitabine was initially approved for use in pancreatic cancer but is now widely used in the treatment of non-small cell lung cancer and bladder cancer.

111. Antibiotics

The anthracycline antibiotics, isolated from Streptomyces peucetius var caesius, are among the most widely used cytotoxic anticancer drugs.

Two congeners, doxorubicin and daunorubicin, are FDA approved, and their structures are shown below.

Several other anthracycline analogs have entered clinical practice, including idarubicin, epirubicin, and mitoxantrone.

Daunorubicin was the first agent in this class to be isolated, and it is still used in the treatment of acute myeloid leukemia.

Doxorubicin has a broad spectrum of clinical activity against hematologic malignancies as well as a wide range of solid tumors.

 The entire class of anthracyclines exert their cytotoxic action through four major mechanisms.

 These are

(1).  Inhibition of topo - isomerase II;

 (2).  High-affinity binding to DNA through intercalation, with consequent blockade of the

        synthesis of DNA and RNA

 (3). Binding to cellular membranes to alter fluidity and ion transport;

 (4) Generation of semiquinone free radicals and oxygen free radicals through an enzyme-

     mediated reductive process.

 

 

Doxorubicin

It is a cytotoxic anthracycline antibiotic

Doxorubicin  is the hydroxylated analog of daunorunicin

Doxorubicin is one of the most important and widely used anticancer drugs

Doxorubicin has a broad spectrum of clinical activity against hematological malignancies as well as a wide range of solid tumors.

Mechanism of action

The cytotoxic action results from it s binding to DNA and inhibition of nucleic acid synthesis

  

Pharmacokinetics

In the clinical setting, anthracyclines are administered via the intravenous route .

The anthracyclines are metabolized extensively in the liver, with reduction and hydrolysis of the ring substituents

The hydroxylated metabolite is an active species, whereas the aglycone is inactive.

Up to 50% of drug is eliminated in the feces via biliary excretion, and for this reason dose reduction is required in the setting of liver dysfunction.

Dose

Treatment of metastatic breast carcinoma

Adult – 60 – 75 mg/m²  once every 3 weeks in combination with cyclophosphamide given as an infusion over 1 hr diluted in 0.9% sodium chloride or 5% glucose

Reduce dose to 50% in patients with moderate liver dysfunction

Drug interactions

Doxorubicin interacts with a number of other drugs

E.g. – Amino glycosides, steroids, aminophyline and propranolol

Drug adverse effects

Leucopoenia, thrombocytopenia, nausea , vomiting , diarrhea  

Uses

Doxorubicin is one of the most important anticancer drugs, with major clinical activity in

carcinomas of the breast, endometrium, ovary, testicle, thyroid, stomach, bladder, liver, and lung;

Daunorubicin

It is a cytotoxic anthracycline antibiotic

Daunorubicin has a far narrower spectrum of activity than doxorubicin

Mechanism of action

It forms a stable complex wit DNA and interferes with the nucleic acid synthesis

It  is a cell – cycle nonspecific effects are mostly marked to cells in the s- shape

It also has immunosuppressant and antibacterial effects

Pharmacokinetics

In the clinical setting, anthracyclines are administered via the intravenous route .

The anthracyclines are metabolized extensively in the liver, with reduction and hydrolysis of the ring substituents

The hydroxylated metabolite is an active species, whereas the aglycone is inactive.

Up to 50% of drug is eliminated in the feces via biliary excretion, and for this reason dose reduction is required in the setting of liver dysfunction.

Dose

Adult – 30 – 45 mg/m2 body surface daily for 2-3 days as a solution in 0.9% sodium chloride administered into a fast running infusion for sodium chloride or glucose

Repeated after 3 – 6 weeks

Child 25mg/m2 once a week in combination with other regiments

Drug interactions

Incompatible with heparin , aluminum and dexamethasone

Immunization with live vaccines is not recommended as daunorubicin is an immunosuppressant

Drug adverse effects

Nausea, vomiting, diarrhea, stomatitis, alopecia and dermatological reactions

Use

Daunorubicin has been mainly used for the treatment of acute lymphoblastic  leukemia,

Dactinomycin

Dactinomycin is an antitumor antibiotic isolated from a Streptomyces organism.

Mechanism of action

It binds tightly to guanine portion of DNA forming a complex which interferes with DNA and RNA synthesis as well as protein synthesis

Dose

Dactinomycin is mainly used to treat pediatric tumors such as Wilms' tumor, and Ewing's sarcoma

Adult  - 2.5 mg/m² in divided doses over 1 week, repeated every 2 weeks or 400-600 mcg/m² /daily for 5 days, repeated every 3- 6 weeks

Child more than 6 months 15 mcg/kg/day or 400 – 600 mcg /m²/day for 5 days every

3 – 6 weeks

 Drug interactions

 It may interfere with bioassay bioassay procedures for the determination of antibacterial drug levels

 Drug adverse effects

 Nausea, vomiting, diarrhea, stomatitis, GIT  ulceration, anorexia, hepatitis, anemia , alopecia, leucopoenia & thrombocytopenia.

  

Uses

 Dactinomycin is mainly used to treat pediatric tumors such as Wilms' tumor, and Ewing's sarcoma

Mitomycin

 

Mitomycin  is an antibiotic isolated from Streptomyces caespitosus.

Mechanism of action

It suppresses nucleic acid synthesis

It is a non- specific cell- cycle agent but has marked action in G1 and early S phases

Mitomycin when converted to an active metabolite , inhibits DNA synthesis as also that of RNA and protein

May be selectively toxic to hypoxic cells because it may generate super oxide and hydroxyl radical

Effects are most marked in the late G1 and early S phases of cell cycle

Dose

Adult  - Initially, 10 – 20 mg/m2 body surface area , repeated at intervals of 6 – 8 weeks

Drug interactions

Synergism with 5- fluorouracil. Enhances cytotoxic effect of radiation especially in the presence of hypoxia

Drug adverse effects

Nausea, vomiting, diarrhea, stomatitis, GIT  ulceration, anorexia, hepatitis, anemia , alopecia, leucopoenia & thrombocytopenia.

Uses

It is used in the treatment of solid tumors including  breast, cervix, eye, liver, lung and stomach

One special application of mitomycin has been in the  treatment of superficial

bladder cancer.

.

Mitoxantrone

Mitoxantrone is an anthracene compound whose structure resembles the anthracycline ring.

Mechanism of action

It binds to DNA and inhibits topoisomerase it causing DNA strand breakage leading t decreased cell replication..

Pharmacokinetics

The plasma half-life of mitoxantrone in patients is approximately 75 hours, and it is predominantly excreted via the hepatobiliary route in feces

Dose

Treatment of  acute leukemia  - 8 – 12 mg/m2/day,  once daily for 4 – 5 days

Treatment of breast prostate cancer and lymphomas  -  Adult – 12 -14 mg/m²/day for 5 days every 4 weeks .

Drug interactions

It appears to have synergistic activity with 5 – fluorouracil , vincristine,dacarbazine and methotrexate in animal studies

Drug adverse effects

Nausea ,vomiting, diarrhea, alopecia, stomatitis, fever , GI bleeding ,fatigue and blue – green urine discoloration.

Uses

It is used in the treatment of  breast cancer , prostate cancer, lymphomas  &  acute  leukemia’s

 

Bleomycin

 

Mechanism of action

Bleomycin is a small peptide that contains a DNA-binding region and an iron-binding domain at opposite ends of the molecule.

It acts by binding to DNA, which results in single-strand and double strand breaks following free radical formation, and inhibition of DNA biosynthesis.

The fragmentation of DNA is due to oxidation of a DNA-bleomycin-Fe(II) complex and leads to chromosomal aberrations.

Bleomycin is a CCS drug that causes accumulation of cells in the G2 phase of the cell cycle.

Pharmacokinetics

One advantage of this agent is that it can be given subcutaneously, intramuscularly, or intravenously

Peak blood levels of bleomycin after intramuscular injection appear within 30–60 minutes.

Intravenous injection of similar dosages yields higher peak concentrations and a terminal half-life of about 2.5 hours

Elimination of bleomycin is mainly via renal excretion; for this reason, dose modification is recommended in the setting of renal dysfunction.

Dose

Treatment of squamous cell or testicular tumors

Adult – 15000  IU – 3 times a week or 30,000 twice a week  IM/IV , repeated at usual intervals of 3 – 4 weeks up to a total cumulative dose of 500,000 IU

Treatment of lymphoma

Adult – 15000  IU – 3 times a week or 30,000 twice a week  IM/IV , repeated at usual intervals of 3 – 4 weeks up to a total cumulative dose of 225,000 IU

Drug interactions

Lomustine increases severity of leucopenia

Elimination decreased by cisplatin

Decreases plasma levels of digoxin and phenytoin

Drug adverse effects

Fever , thrombophloebitis, hyperpyrexia, stomatitis, alopecia, and hyper pigmentation.

Uses

Bleomycin is indicated for the treatment of Hodgkin's and non-Hodgkin's lymphomas, germ cell tumor, head and neck cancer, and squamous cell cancer of the skin, cervix 

1V. Vinca alkaloids

Ex- Vincristine  & vinblastine

Mitotic spindles

The mitotic inhibitors act by interfering with the mitosis of cells and thereby inducing mitotic arrest

The mitosis takes lace during the M phase of the cell cycle

Mitotic arrest is induced because of damage to the spindle apparatus

The chromatides , which are separated in the metaphase are prevented from being pulled toward opposite poles in the following anaphase

The separate threads of the spindle apparatus are built as a microtubule system

Microtubules are hollow , cylindrical structures built up of the protein tubulin , which consists of two subunits, alpha and beta – tubulin with very similar amino acid sequences

The cylinder consists of 13 rows of tubulin heterodiamers, the protofilaments

The microtubule cylinder can also be regarded as consisting of a helical array of altering arrays of tubulin subunit

Some of the drugs have  a common binding site and others a different, but probably common, binding site and others a different but probably common , binding site

Taxanes promote the assembly of tubulin to microtubules and prevent depolymerization by biding to tubulin at separate site

Microtubules are part of the cytoskeleton and take part in intracellular transport and communication

Some of the  toxic side effects of the mitotic inhibitors may be due to disturbance of these phenomena

 

VInblastine

Vinblastine is an alkaloid derived from Vinca rosea, the periwinkle plant.

Mechanism of action

Its mechanism of action involves depolymerization of microtubules, which are an important part of the cytoskeleton and the mitotic spindle.

Binds to micro tubular proteins . It inhibits RNA synthesis by affecting DNA-dependent RNA polymerases.

Cell cycle- phase specific , it arrests cells at the G2 phase and M phase interface

Pharmacokinetic

Highly bound to plasma proteins.

It is metabolized by the liver to active and inactive metabolites

It is predominantly excreted in bile

Minimum free drug is recovered in urine

Drug interactions

Mitomycin C, phenytoin , alpha interferon

Adverse effects

Toxicity includes nausea , vomiting, diarrhea, bone marrow suppression, and alopecia.

Dosage

30mg/m²  IV every weekly

Uses

It has clinical activity in the treatment of Hodgkin's disease, non-Hodgkin's lymphomas, breast cancer, and germ cell cancer.

VIncristine

Vincristine is also an alkaloid derivative of Vinca rosea and is closely related in structure to vinblastine.

Mechanism of action

Vincristine arrests cell division at the metaphase stage by inhibiting microtubule formation in the mitotic spindle

Drug interactions

It may decrease digoxin and phenytoin serum levels . 

Synergistic with methotrexate.

Adverse effects

The main dose limiting toxicity is neurotoxicity.

While myelosuppression can occur, it is generally milder and much less significant than with vinblastine.

Dose

1.5 mg/m2 IV . Maximum 2 mg  weekly

Uses

Vincristine has been effectively combined with prednisone for remission induction in acute lymphoblastic leukemia in children.

It is also active in various hematologic malignancies such as Hodgkin's and non-Hodgkin's lymphoma 

V . Taxanes

Eg- Paclitaxel and docetaxel

The mitotic spindle is part of  larger , intracellular skeleton (cytoskeleton) that is essential for the movements of structures occurring in the cytoplasm of all eukaryotic cells

The mitotic spindle consists of  -    chromatin    +   a system of microtubules compose of the protein tubulin

The mitotic spindle is essential for the equal partitioning of DNA into the two daughter cells that are formed when a eukaryotic cell divides .

Several plant –derived substances used as anticancer drugs disrupt this process by affecting the equilibrium between the polymerized and depolymerized forms of the microtubules , thereby causing cytotoxicity

 

Paclitaxel

Better known as taxol, paclitaxel is the first member o the taxane family to be used in cancer chemotherapy

It is an alkaloid ester derived from the Western yew (Taxus brevifolia) and the European yew (Taxus baccata).

 

Mechanism of action

(Taxanes bind tubulin subunits promote assembly but prevent depolymerization of microtuubles )

These are active in the G2 / M phase for the cell cycle

They bind reversibly to the BETA – tubulin subunit , but unlike the vinca alkaloids, they promote polymerization and stabilization of the polymer rather than disassembly

They shift the depolymrizaiton- polymerization process to favor the formation of microtubules

This promotion of microtubule assembly by paclitaxel occurs in the absence of microtubule-associated proteins and guanosine triphosphate and results in inhibition of mitosis and cell division.

The overly stable microtubules formed are nonfunctional and chromosome desegregation does not occur . This results in death of the cell

Pharmacokinetics

It  have a large volume of distribution but not enters the brain

It is metabolized extensively by the liver P450 system, and nearly 80% of the drug is excreted in feces.

Biliary excretion are responsible for their elimination into the stool

Dose modification is not required in patients with renal impairment but doses should be reduced in patients with hepatic dysfunction

Adverse effects

The dose – limiting toxicity of paclitaxel is neutropenia

Hypersensitivity reactions may be observed in up to 5% of patients, but the incidence can be reduced by premeditation with dexamethasone, diphenhydramine, and an H2 blocker.

Uses

Paclitaxel has significant activity in a wide variety of solid tumors, including ovarian, advanced breast, non-small cell and small cell lung, head and neck, esophageal, prostate, and bladder cancer.

  

Docetaxel

It is a semi synthetic taxane derived from the European yew tree.

Its mechanism of action, metabolism, and elimination are identical to those of paclitaxel. It is approved for use as second-line therapy in advanced breast cancer and lung cancer, and it also has major activity in head and neck cancer, gastric cancer, ovarian cancer, and bladder cancer. 

V1. Epi -podophyllotoxins

Two compounds, VP-16 (etoposide) and a related drug, VM-26 (teniposide), are semi synthetic derivatives of podophyllotoxin, which is extracted from the may apple root (Podophyllum peltatum).

Both an intravenous and an oral formulation of etoposide are approved for clinical use in the USA.

Mechanism of action

Etoposide and teniposide are similar in chemical structure and in their effects

They block cell division in the late S-G2 phase of the cell cycle.

Their primary mode of action involves inhibition of topoisomerase II, which results in DNA damage through strand breakage induced by the formation of a ternary complex of drug, DNA, and enzyme.

 

Phgarmacoketics

These agents are administered via the intravenous route

These  are rapidly and widely distributed throughout the body except for the brain.

Up to 90–95% of drug is protein-bound, mainly to albumin.

Dose reduction is required in the setting of renal dysfunction

  

Dosage

Etoposide is given in combination with other antineoplastic drugs

50 -100 mg /m2/day from days 1 -5  or  100 mg/m2 on days1,3 and 5  

  

Adverse drug  effects

 Nausea. Vomiting , anorexia, diarrhea, stomatitis, alopoecis,,CNS defects 

.

Uses

 Etoposide has clinical activity in germ cell cancer, small cell and non-small cell lung cancer, Hodgkin's and non-Hodgkin's lymphomas, and gastric cancer and as high-dose therapy in the transplant setting for breast cancer and lymphomas.

Teniposide's use is limited to acute lymphoblastic leukemia.

V11 . Enzymes

E.g

Asparaginase

Asparaginase is an enzyme that is isolated from various bacteria mainly E. Coli for clinical use.

Mechanism of action

It hydrolyzes circulating L-asparagine to aspartic acid and ammonia.

Aspargine is a non- essential amino acid normally synthesized by the mammalian tissue cells

Depletion of L-asparagine results in effective inhibition of protein synthesis

Certain malignant tumors are unable to synthesize aspargine and are dependent on supplies from the host

It acts by depleting asparagines from the host , hydrolyzing circulating  l- aspargine to aspartic acid denying the malignant cells the essential metabolite

It is relatively nontoxic to normal cells

Administration

The enzyme must be administered either  IV or intramuscularly because it is destroyed by gastric enzymes

It may cause hypersensitivity pyrogenic reactions and skin rashes  

Adverse effects

The main adverse effect of this agent is a hypersensitivity reaction manifested by fever, chills, nausea and vomiting, skin rash, and urticaria.

Severe cases can present with bronchospasm, respiratory failure, and hypotension.

and neurological toxicity with confusion, hallucinations, and coma.

Dose

20,000 IU /m2 daily IV for 5 – 10 days

  

VIII . Radioactive isotopes

       Radioiodine, Radio gold & Radio phosphorus

These are the isotopes of various elements which act because of their physical property of emitting radiation

Radiations given out produce ionization in the cells

The vital enzymes of cells are in activated and there occurs structural changes in the chromosomes

Ultimately there is cell - destruction

Radium

It is a bivalent meal . It disintegrates with emission of various types of radiations

It has been referred to as radioactive

There are three types of rays emitted by radium

Alpha rays

These consist of two  protons and two neutrons . It has very little power of penetration tissues

Beta rays

These consist of negatively or positively charged , electros

They have more penetrating power than alpha - rays

Gamma rays

These are gamma electromagnetic waves of shortwave length and have greater power to penetrate the tissues

These waves cannot pass through elements of high atomic number

Eg – lead

 

Geigy – Muller counter

Radioactive isotopes are very sensitive and can be detected by Geigy – Muller counter, electroscopes an electro radiography

Clinically useful radioactive isotopes are Radioiodine , Raiophosphorous and Radio gold

1. Radioactive iodine (I¹³¹)

It is obtained as a fission product of uranium

It can also be prepared by neutron irradiation of tellurium. Sodium radio iodine (I¹³¹)   

preparations are used orally as well as intravenously.

It acts by giving beta radiation

It is rapidly absorbed and taken up by the thyroid gland

There is no radiation sickness and does not necessitate repeated blood examination

Dose

It is given in a dose of 4- 10milli curies for thyrotoxicosis and 50-100 mill curies for thyrotoxicosis for thyroid carcinoma

Uses

It is used in hyperthyroidism ,& carcinoma of the thyroid gland  for determining functional activity for the thyroid gland

2. Radio- active isotopes ( P ³²)

It is used in the form of disodium hydrogen phosphate .

It is distributed to all parts of the body .

Uses

It is used in diseases like polycythemia  vera and chronic lymphatic leukemia

Dose

It is given in a dose of 3 – 5 mill curies I.V

3. Radio active Gold (Au ¹⁹⁸ )

It is a short lived isotopes( half life 2 – 7 days ).

It emits both beta and gamma rays .

Dose

35 – 100 mill curies is injected intrapleurally or intraperitoneally

Use

It is used in malignant pleural and  peritoned effusions

1X  . Hormones & their antagonists

Prednisone

It is a potent , synthetic , anti- inflammatory corticosteroid with less mineral corticoid activity than cortisol

The use of this compound in the treatment of lymphomas arose when it was observed that patients with cushing syndrome , which is associated with hyper secretion of cortisol, have lymphocytopenia and decreased lymphoid mass

Prednisone is primarily employed to induce remission in patients with acute lymphocytic leukemia and in the treatment of both Hodgkin and non- Hodgkin lymphomas

Mechanism of action

Prednisone itself is inactive and must first be reduced to prednisolone by 11- beta- hydroxysteroid dehydrogenase

This steroid then binds to a receptor that triggers the production of specific proteins

Pharmacokinetics

It is readily absorbed orally

Like  other gluco-corticoids it is bound to plasma albumin and transcortin

It undergoes 11 – beta – hydroxylation to prednisolone in the liver

It is the active drug

The latter is glucuronidated and excreted into the urine along with the parent compound

Adverse effects

It has many of the adverse effects  associated with glucocorticiids.

It can predispose to infection and to ulcers and pancreatitis

Other effects include hyperglycemia, cataract formation , glaucoma , osteoporosis, and change in mood

Dose

Prednisolone is generally started in doses of 60 – 100 mg daily in divided doses and them depending upon the response ,reduced to a maintenance dose of 20 – 40 mg daily

Estrogens

Estrogens, such as ethinyl estradiol or diethyl-stilbestrol had been used in the treatment of breast cancer

They have been largely replaced by the GnRH analogs because of fewer adverse effects

Estrogens inhibit the growth of prostatic tissue by blocking the production of LH, thereby decreasing the synthesis of androgens in the testis

Toxicity

Estrogen treatment can cause serious complications , such as hypertension t, MI , strokes thromboembolic, jaundice, retinal thrombosis disorder and hyjpercalcemia

Administration

It is supplied as 0.25, o.5, 1.0 & 5.0 mg tablets

Dosage

1 – 15 mg daily in divided doses

Use

Breast carcinoma

Estrogen antagonist

Eg  - Tamoxifen, Toremifene, Fulvestrant

Tamoxifen is an estrogen antagonist

It is structurally related to the synthetic estrogen di- ethyl- stilbestrol and is used for first – line therapy in the treatment of estrogen receptor – positive breast cancer

It has weak estrogenic activity and is classified  as a selective estrogen – receptor modulator

Mechanism of action

Tamoxifen & toremifene are nonsterioidal agents that bind to oestrogen receptors and may exert antioestrogenic, estrogenic or both activities

Fulvestrant is an oestrogen receptor antagonist without known agonist effects

Tamoxifen binds to the estrogen receptor, but the complex is not productive

The complex fails to induce estrogen – responsive genes and RNA synthesis does not ensue

The result is a depletion of estrogen receptors and the growth – promoting effects of the natural hormone and other growth factors are suppressed

Pharmacokinetics

Tamoxifen is effective on oral administration

It is partially metabolized by the liver

Some metabolites possess antagonist activity , whereas others have agonist activity

Unchanged drug and its metabolites are excreted predominantly through the bile into the feces

Adverse effects

It causes menstrual changes, vaginal discharge, uterine bleeding , thrombocytopenia, nausea , vomiting , skin rash ,  , hypocalcaemia  & hair loss

Preparation

Tamoxifen  -  10 mg, 20 mg tabs

Dosage

Tamoxifen             -  20 mg orally once daily

Toremifene            -  60 mg orally once daily

Fulvestrant           -  250mg intramuscularly as a 5 ml solution monthly

Use

In treatment of breast carcinoma

Androgens  (Fluoxymesterone and Methyl testosterone)

Therapeutic uses

Breast carcinoma, short- range anabolic effect and stimulation of erythropoiesis

Toxicity

It varies among preparations

Fluid retention , hepatotoxicity  &  hypocalcaemia

Administration

It issue with caution in patients with cardiac, hepatic or renal disease

Fluoxymesterone is administered in dose of 10 – 40 mg /day in 2- 4 divided doses and methyl-testosterone in dose of 50-200 mg/day in 2 or 3 divided doses

Anti- androgens

Ex    -  Flutamiide, Bicalutamide  & Nilutamide

These are synthetic , non-steroidal antiandrogens used in the treatment of prostate cancer

 

 

Mechanism of action

Nonsteroidal anti-androgens bind to cytosol androgen receptors and competitively inhibit the uptake or binding of androgens in target tissues

They compete with the natural hormone for binding to the androgen receptor and prevent its translocation into the nucleus

Flutamide is metabolized to an active hydroxyl derivative that bins to the androgen receptor

Flutamide blocks the inhibitory effects of testosterone on gonadotropin secretion causing and increase in serum LH and testosterone levels

Pharmacokinetics

Flutamide is always administered in combination with leuprolide or goserelin

These antiandrogens are taken orally

The drugs are almost totally metabolized

These agents are cleared through the kidney

Toxicity

Side effects include gynecomastia, GIT disturbances, impotence , diarrhea & liver failure in the case of flutamide .

It also causes nausea , vomiting , myalgia depression & mild hypertension

Nilutamide can cause visual problems

Administration

It is used with caution in patients with hepatic dysfunction

Flutamide                    -      250 mg divided dose orally

Bicalutamide               -      50 mg orally once daily

Nilutamide                  -      300 mg once daily orally for 30 days, then 150 mg daily

Therapeutic uses

Prostate cancer , in combination with medical therapy

Gonadotropin – releasing hormone

Eg

Leuprolide  &  goserelin

Leuprolide and goserelin

These are synthetic peptide analogs of naturally occurring gonadotropin releasing hormone (GnRH, LHRH).

Gonadotropin – releasing hormone (GnRH) is  normally secreted by the hypothalamus

These  stimulates the anterior pituitary to secrete the gonadotropic hormones, LH & FSH

The synthetic Nona peptides, leuprolide and goserelin are analogs of GnRH

Mechanism of action

As GnRH agonists they occupy the GnRH receptor in the pituitary , which leads to its desensitization and consequently , inhibition of release of FSH and LH

The both androgen and estrogen synthesis are reduced

Pharmacokinetics

Goserelin acetate is implanted intramuscularly

Levels of androgen may initially rise but then fall to castration levels

Adverse effects

The adverse effects of these drugs , including impotence, hot flushes & gynecomastia

Administration

Leuprolide and goserelin are now formulated in long-acting depot forms, which allows for administration once every 3 months.

Uses

Leuprolide and goserelin are indicated in the treatment of advanced prostate cancer and more recently these agents have been incorporated as part of neoadjuvant therapy of early-stage prostate cancer.

Aromatase Inhibitors

The aromatase reaction is responsible for the extra –adrenal synthesis of  estrogen from androstenedione, which takes place in liver, fat , muscle , skin and breast tissue

Peripheral aromatization is an important source of estrogen in post menopausal women

Aromatase inhibitors decrease the production of estrogen in these women

Eg

Aminoglutethimide ,  Anastrozole, letrozole , Exemestane

Aminoglutethimide

It was the first aromatase inhibitor to be identified for the treatment of metastatic breast cancer in postmenopausal women 

Mechanism of action

It was shown to inhibit both the adrenal synthesis of pregnenolone ( a precursor of estrogen) from cholesterol

It also inhibits the extra-adrenal synthesis of estrone and estradiol.

Aside from its direct effects on adrenal steroid genesis, aminoglutethimide is an inhibitor of an aromatase enzyme that converts the adrenal androgen androstenedione to estrone

This aromatization of an androgenic precursor into an estrogen occurs in body fat.

Aminoglutethimide is normally administered with hydrocortisone to prevent symptoms of adrenal insufficiency.

Hydrocortisone is preferable to dexamethasone because the latter agent accelerates the rate of catabolism of aminoglutethimide.

Uses

Since estrogens promote the growth of breast cancer, estrogen synthesis in adipose tissue can be important in breast cancer growth in postmenopausal women.

Aminoglutethimide is primarily used in the treatment of metastatic breast cancer in women whose tumors express significant levels of estrogen or progesterone receptors.

Dis –advantage

Due to its nonselective properties and unfavorable side effects as well as the need to concomittanity administer hydrocortisone (cortisol) , newer aromatase inhibitors has been developed

Anastrozole ,   Letrozole  &  Exemestane

Anastrozole &  Letrozole 

These are imidazole aromatase inhibitors and are non- steroidal

These are considered to be second – line  therapy after tamoxifen for hormone – dependent breast cancer in the united states

They have become first –line drugs in other countries for the treatment of breast cancer in postmenopausal women

They have better action then the aninoglutethimide due to

1.They are more potent by greater than 96 %

2. They are more selective than aminoglutethimide

3. They do not need to be supplemented with hydrocortisone

4. They do not predispose to endometrial cancer

They are orally active and cause almost a total suppression of estrogen synthesis

They are cleared primarily by liver metabolism

Exemestane

It is a steroidal hormonal agent and irreversibly inhibitor of aromatase.

It is orally will- absorbed and widely distributed

Hepatic; metabolism is by the CYP3A4 isozyme , but  todate , no interactions have been reported

Because the metabolites are excreted into the urine

The doss of the drug must be adjusted in patients with renal failure

Its major toxicities are nausea,  fatigue and loss of hair

This agent is indicated for the treatment of advanced breast cancer in postmenopausal women whose disease has progressed on tamoxifen therapy

X. Miscellaneous

Cisplatin

This is a platinum containing compound, the chemical structure of which is cis- diammine dichloro-platinum

 

Mechanism of action

Cisplatin, carboplatin and oxaliplatin are platinum containing compounds . They get converted to the active form in the cell, inhibit DNA synthesis and cause cytotoxicity

A heavy metal alkylator of DNA. Covalently bonds to proteins, RNA and especially DNA, forming DNA cross linking and intra-strand N-7 adduct.

The trans isomer has virtually no anti-tumour activity

Metabolism

It is widely distributed in the body , except for the CNS

Long half – life in plasma (upto 3 days ) may remain bound in tissues for months

Native drug (30%) and metabolites excreted in urine , biliary excretion accounts for less than 10% of the total drug excretion

Administration

The principles of cisplatin administration are as follows

1. Monitoring of serum cratinine, electrolytes , magnesium and calcium levels daily

    during therapy

2. Anti- emetics such as ondansetron  and dexamethasone should be administered

    Prophylactically

3. Hydration and diuresis are required when 40mg /m2 or more of cisplatin is given to

    maintain a urine output of 100 -150 ml /hour before administration of the drug

4. Furosemide is given to prevent fluid overload

5. Mannitol Is given if urine output is insufficient

6. Intravenous fluids are supplemented with KCL  and Mg SO₄  

Preparation

Inj  -  10 mg /20 ml ,  50 mg/100 ml

Dosage

It is available as 10 and 50 mg vials

40 – 120 mg/m² or more intravenously every 3-4 weeks or 20 – 40 mg/m2 daily for 3 – 5 days every 3 – 4 weeks

Adverse effects

It causes ototoxicity, nephrotoxicity, peripheral neuropathy, nausea, vomiting , and anemia. It is relatively less toxic to bone marrow

Dose modification

Renal function must return to normal before cisplatin can be given . One may avoid using cisplatin when the cratinine clearance is less than 40 ml/ min .

 It is relatively contraindicated in patient with documented hearing impairment

Therapeutic uses

Cisplatin is effective in advanced colorectal cancer and in other cancers like ovarian and cervical cancers

Carboplatin

It is a second-generation platinum analog that exerts its cytotoxic effects exactly as cisplatin and has activity against the same spectrum of solid tumors.

Its main dose-limiting toxicity is myelosuppression, and it has significantly less renal toxicity and gastrointestinal toxicity than cisplatin.

Moreover, vigorous intravenously hydration is not required.

As a result, carboplatin is now being used in place of cisplatin in combination chemotherapy.

Oxaliplatin

It is a third generation diaminocyclohexane platinum analog. Its mechanism of action is identical to that of cisplatin and carboplatin.

However, it is not cross-resistant to cancer cells that are resistant to cisplatin or carboplatin on the basis of mismatch repair defects.

This agent was recently approved for use as second-line therapy in metastatic colorectal cancer following treatment with the combination of fluorouracil-leucovorin and irinotecan, and it is now widely used as first line therapy of this disease as well.

Neurotoxicity is dose-limiting and characterized by a peripheral sensory neuropathy, often triggered or worsened upon exposure to cold.

While this neurotoxicity is cumulative, it tends to be reversible—in contrast to cisplatin-induced neurotoxicity 

 

Imatinib

 

Mechanism of action

It occupies the ATP biding site of eh BCR- ABL protein in the myeloma cells ( in CNL patients) and other related tyrosine kinases and thus results in subsequent inhibition of substrate phosphorylation

It is a protein and selective inhibitor resulting in inhibition of tumourigenicity of BCR – ABL positive cells and also leads to their  apoptosis

It also inhibits other receptor tyrosine kinases for platelet derived growth factor receptor (PDGFR)

Metabolism

It is eliminated mainly in faeces. The half – life is around 18 hours

Adverse effects

Nausea, vomiting , diarrhea , pulmonary oedema& myelosuppression

Pharmacokinetics

Imatinib is administered orally and is well absorbed; it is highly protein-bound in plasma.

The drug is metabolized in the  liver, and elimination of metabolites occurs mainly in feces via biliary excretion.

Administration

It is supplied as 100 mg capsules and should be taken with food and a large glass of water

The dose modifications required in patients with liver dysfunction

Dosage

400 mg/day orally for Chronic myelogenous leukemia in chronic phase and in Gastrointestinal stromal tumours, 600 – 800 mg/ day orally in accelerated phase of CML

Preparation

Imatinib – Cap  -100 mg

Uses

It is used in the treatment of chronic myelogenous leukaemia(CML) and gastrointestinal stromal tumours(GIST)

This agent is approved for use as first-line therapy in chronic phase CML, in blast crisis, and as second-line therapy for chronic phase CML that has progressed on prior intestinal stromal tumours.

 Imatinib is effective also for treatment of gastrointestinal stromal tumors expressing the

 

Gefitinib

 

Mechanism

It inhibits the enzyme tyrosine kinase associated with transmembrane cell surface receptors , including the epidermal growth factor receptor (EGFR)

Metabolism

It undergoes extensive hepatic metabolism and is excreted predominantly in faeces

Administration

It is supplied as 250 mg tablets. Dose modification s required in patients with liver dysfunction

Dosage

250 mg orally

Preparation

Gefitinib  -  Tab  - 250 mg

Adverse effects

Diarrhea, nausea, vomiting , mild rash , anorexia , peripheral oedema and corneal irritation

Uses

Advanced non small cell lung cancer and taxane – based therapies

Hydroxyurea

 

Mechanism of action

Hydroxyurea (HONHCONH2) is an analog of urea whose mechanism of action involves the inhibition of DNA synthesis in the S phase by inhibiting the enzyme ribonucleotide reductase, resulting in depletion of deoxynucleoside triphosphate pools.

Pharmacokinets

The drug is administered orally and has nearly 100% oral bioavailability.

Metabolism in liver and excreted by kidney

It is mainly used in chronic myelogenous leukemia and treatment of the blast crisis of acute myeloid leukemia.

Adverse effects

Myelosuppression is the dose-limiting toxicity, but nausea and vomiting, mucositis and diarrhea, headache and increased lethargy, and a  skin rash.

Uses

It  is also effective as an adjunct with radiation therapy for head and neck cancer and in treating essential thrombocytosis and polycythemia vera.