Cyclophosphamide (INN, trade names Endoxan, Cytoxan, Neosar, Procytox, Revimmune), also known as cytophosphane,^[1] is a nitrogen mustard alkylating agent,^[2] from the oxazophorines group.

An alkylating agent adds an alkyl group (C_nH_2n+1) to DNA. It attaches the alkyl group to the guanine base of DNA, at the number 7 nitrogen atom of the imidazole ring.

It is used to treat cancers and autoimmune disorders. A prodrug, it is converted in the liver to active forms that have chemotherapeutic activity.

Cyclophosphamide has severe and life-threatening adverse effects, including acute myeloid leukemia, bladder cancer, and permanent infertility, especially at higher doses. For autoimmune diseases, doctors often substitute less-toxic methotrexate or azathioprine after an acute crisis.^[3]

Uses[edit]

Cyclophosphamide is used to treat cancer and immune diseases.

Cancer[edit]

The main use of cyclophosphamide is with other chemotherapy agents in the treatment of lymphomas, some forms of brain cancer, leukemia^[4] and some solid tumors.^[5] It is a chemotherapy drug that works by inducing the death of certain T cells.

A 2004 study^[6] showed the biological actions of cyclophosphamide are dose-dependent. At higher doses, it is associated with increased cytotoxicity and immunosuppression, while at low, continuous doses, it shows immunostimulatory and antiangiogenic properties. A 2009 study of 17 patients with docetaxel-resistant metastatic hormone refractory prostate cancer showed a prostate-specific antigen (PSA) decrease in 9 of the 17 patients. Median survival was 24 months for the entire group, and 60 months for those with a PSA response. The study concluded low-dose cyclophosphamide "might be a viable alternative" treatment for docetaxel-resistant MHRPC and "is an interesting candidate for combination therapies, e.g., immunotherapy, tyrosine kinase inhibitors, and antiangiogenisis."^[7]

Autoimmune diseases[edit]

Cyclophosphamide also decreases the immune system's response to various diseases and conditions. Therefore, it has been used in autoimmune diseases where disease-modifying antirheumatic drugs (DMARDs) have been ineffective. For example, systemic lupus erythematosus with severe lupus nephritis^[8] may respond to pulsed cyclophosphamide. Cyclophosphamide is also used to treat minimal change disease,^[9] severe rheumatoid arthritis,^[10] Wegener's granulomatosis^[11] (with trade name Cytoxan), and multiple sclerosis^[12] (with trade name Revimmune).

glomerulonephritis^[13][edit]

DOSE IN NORMAL RENAL FUNCTION

Autoimmune disease:

—Oral: 1–2.5 mg/kg/day

—IV: Usually 0.5–1 g/m2 or 10–15 mg/kg repeated at intervals, e.g. monthly (pulse therapy)

Malignant disease:

—Oral: 50–250 mg/m2 daily or according to local protocol

DOSE IN RENAL IMPAIRMENT GFR (mL/ MIN )

20–50 Dose as in normal renal function

10–20 75–100% of normal dose depending on clinical indication and local protocol

<10 50–100% of normal dose depending on clinical indication and local protocol

DOSE IN PATIENTS UNDERGOING RENAL REPLACEMENT THERAPIES

CAP d Dialysed. Dose as in GFR<10 mL/min. Follow ing dose, do not perform CAPD exchange for 12 hours

HD Dialysed. Dose as in GFR<10 mL/min. Dose at minimum of 12 hours before HD session

HDF/high flux Dialysed. Dose as in GFR<10 mL/min. Dose at minimum of 12 hours before HDF session

CAV/VVHD Dialysed. Dose as in GFR=10–20 mL/min

Pharmacokinetics/pharmacodynamics[edit]

Cyclophosphamide is converted by mixed-function oxidase enzymes in the liver to active metabolites.^[14] The main active metabolite is 4-hydroxycyclophosphamide, which exists in equilibrium with its tautomer, aldophosphamide. Most of the aldophosphamide is oxidised by the enzyme aldehyde dehydrogenase (ALDH) to make carboxyphosphamide. A small proportion of aldophosphamide is converted into phosphoramide mustard and acrolein. Acrolein is toxic to the bladder epithelium and can lead to hemorrhagic cystitis. This can be prevented through the use of aggressive hydration and/or mesna.

Cyclophosphamide induces beneficial immunomodulatory effects in adaptive immunotherapy. Suggested mechanisms include:^{[citation needed]}

1. Elimination of T regulatory cells (CD4+CD25+ T cells) in naive and tumor-bearing hosts
2. Induction of T cell growth factors, such as type I IFNs, and/or
3. Enhanced grafting of adoptively transferred, tumor-reactive effector T cells by the creation of an immunologic space niche.

Thus, cyclophosphamide preconditioning of recipient hosts (for donor T cells) has been used to enhance immunity in naïve hosts, and to enhance adoptive T cell immunotherapy regimens, as well as active vaccination strategies, inducing objective antitumor immunity.

Mechanism of action[edit]

The main effect of cyclophosphamide is due to its metabolite phosphoramide mustard. This metabolite is only formed in cells that have low levels of ALDH.

Phosphoramide mustard forms DNA crosslinks both between and within DNA strands at guanine N-7 positions (known as interstrand and intrastrand crosslinkages, respectively). This is irreversible and leads to cell death.

Cyclophosphamide has relatively little typical chemotherapy toxicity as ALDHs are present in relatively large concentrations in bone marrow stem cells, liver and intestinal epithelium. ALDHs protect these actively proliferating tissues against toxic effects of phosphoramide mustard and acrolein by converting aldophosphamide to carboxyphosphamide that does not give rise to the toxic metabolites phosphoramide mustard and acrolein.

Side effects[edit]

Adverse drug reactions include chemotherapy-induced nausea and vomiting, bone marrow suppression, stomachache, hemorrhagic cystitis, diarrhea, darkening of the skin/nails, alopecia (hair loss) or thinning of hair, changes in color and texture of the hair, and lethargy. Hemorrhagic cystitis is a frequent complication, but this is prevented by adequate fluid intake and mesna (sodium 2-mercaptoethane sulfonate), a sulfhydryl donor which binds acrolein.

Cyclophosphamide is itself carcinogenic, potentially causing transitional cell carcinoma of the bladder as a long-term complication. It can lower the body's ability to fight an infection. It can cause temporary or (rarely) permanent sterility. A serious potential side effect is acute myeloid leukemia, referred to as secondary AML, due to it occurring secondary to the primary disease being treated. The risk may be dependent on dose and a number of other factors, including the condition being treated, other agents or treatment modalities used (including radiotherapy), treatment intensity and length of treatment. For some regimens, it is a very rare occurrence. For instance, CMF-therapy for breast cancer (where the cumulative dose is typically less than 20 grams of cyclophosphamide) seems to carry an AML risk of less than 1/2000th, with some studies even finding no increased risk compared to the background population. Other treatment regimens involving higher doses may carry risks of 1-2% or higher, depending on regimen. Cyclophosphamide-induced AML, when it happens, typically presents some years after treatment, with incidence peaking around 3–9 years. After nine years, the risk has fallen to the level of the regular population. When AML occurs, it is often preceded by a myelodysplastic syndrome phase, before developing into overt acute leukemia. Cyclophosphamide-induced leukemia will often involve complex cytogenetics, which carries a worse prognosis than de novo AML.

Other side effects include:

• gross and microscopic hematuria
• unusual decrease in the amount of urine
• mouth sores
• unusual tiredness or weakness
• joint pain
• easy bruising/bleeding
• slow-healing existing wounds
• syndrome of inappropriate antidiuretic hormone (SIADH)

History[edit]

As reported by O.M. Colvin in his study of the development of cyclophosphomide and its clinical applications,

Phosphoramide mustard, one of the principle toxic metabolites of cyclophosphamide, was synthesized and reported by Friedman and Seligman in 1954^[15] ...It was postulated that the presence of the phosphate bond to the nitrogen atom could inactivate the nitrogen mustard moiety, but the phosphate bond would be cleaved in gastric cancers and other tumors which had a high phosphamidase content. However, in studies carried out after the clinical efficacy of cyclophosphamide was demonstrated, phosphoramide mustard proved to be cytotoxic in vitro (footnote omitted), but to have a low therapeutic index in vivo.^[16]

Cyclophosphamide and the related nitrogen mustard-derived alkylating agent ifosfamide were developed by Norbert Brock and ASTA (now Baxter Oncology). Brock and his team synthesised and screened more than 1,000 candidate oxazaphosphorine compounds.^[17] They converted the base nitrogen mustard into a nontoxic "transport form". This transport form was a prodrug, subsequently actively transported into the cancer cells. Once in the cells, the prodrug was enzymatically converted into the active, toxic form. The first clinical trials were published at the end of the 1950s.^[18][19][20]

References[edit]

External links[edit]

• U.S. National Library of Medicine: Drug Information Portal - Cyclophosphamide