Aromatase inhibitors

Last updated: February 10, 2024

Aromatase inhibitors

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Anatomy of the pelvic girdle
Anatomy of the pelvic cavity
Anatomy of the male reproductive organs of the pelvis
Anatomy of the perineum
Anatomy clinical correlates: Male pelvis and perineum
Anatomy of the female urogenital triangle
Anatomy clinical correlates: Female pelvis and perineum
Development of the reproductive system
Prostate gland histology
Testis, ductus deferens, and seminal vesicle histology
Penis histology
Anatomy and physiology of the male reproductive system
Testosterone
Hypospadias and epispadias
Priapism
Prostatitis
Penile cancer
Cryptorchidism
Varicocele
Orchitis
Testicular cancer
Epididymitis
Testicular torsion
Hernias: Clinical
Vaginal and vulvar disorders: Pathology review
Cervical cancer: Pathology review
Cervical cancer
Menstrual cycle
Anatomy and physiology of the female reproductive system
Prostate cancer
Benign prostatic hyperplasia
Inguinal hernia
Ovarian cyst
Premature ovarian failure
Polycystic ovary syndrome
Ovarian torsion
Ovarian sex-cord stromal tumors
Ovarian germ cell tumors
Ovarian surface epithelial tumors
Endometritis
Endometrial cancer
Endometriosis
Endometrial hyperplasia
Choriocarcinoma
Uterine fibroid
Testicular tumors: Pathology review
Uterine disorders: Pathology review
Ovarian cysts and tumors: Pathology review
Amenorrhea
Amenorrhea: Clinical
Amenorrhea: Pathology review
Ectopic pregnancy
Virilization: Clinical
Abnormal uterine bleeding: Clinical
Haemophilus ducreyi (Chancroid)
Treponema pallidum (Syphilis)
Herpes simplex virus
Chlamydia trachomatis
Gardnerella vaginalis (Bacterial vaginosis)
Neisseria gonorrhoeae
Candida
Trichomonas vaginalis
Arteries and veins of the pelvis
Nerves and lymphatics of the pelvis
Anatomy of the inguinal region
Anatomy of the male urogenital triangle
Anatomy of the breast
Anatomy clinical correlates: Breast
Mammary gland histology
Ovary histology
Fallopian tube and uterus histology
Cervix and vagina histology
Puberty and Tanner staging
Estrogen and progesterone
Menopause
Pregnancy
Oxytocin and prolactin
Stages of labor
Breastfeeding
Erectile dysfunction
Male hypoactive sexual desire disorder
Female sexual interest and arousal disorder
Pelvic inflammatory disease
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Androgens and antiandrogens
Adrenergic antagonists: Alpha blockers
PDE5 inhibitors
Estrogens and antiestrogens
Progestins and antiprogestins
Aromatase inhibitors
Sexually transmitted infections: Clinical
Human development days 1-4
Human development days 4-7
Human development week 2
Human development week 3
Infertility: Clinical
Placenta previa
Development of the placenta
Turner syndrome
Klinefelter syndrome
Fragile X syndrome
Ovarian cysts, cancer, and other adnexal masses: Clinical
Galactosemia
Hyperemesis gravidarum
Complications during pregnancy: Pathology review
Vulvovaginitis: Clinical
Endometrial hyperplasia and cancer: Clinical
Cervical cancer: Clinical
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Vulvar cancer: Clinical
Fetal circulation
Preeclampsia & eclampsia
Hypertensive disorders of pregnancy: Clinical
Uterine stimulants and relaxants
cGMP mediated smooth muscle vasodilators
Postpartum hemorrhage: Clinical
Placenta accreta
Placental abruption
Antepartum hemorrhage: Clinical
Abnormal labor: Clinical
Gestational trophoblastic disease: Clinical
Krukenberg tumor
Breast cancer: Pathology review
Benign breast conditions: Pathology review
Breast cancer
Fibrocystic breast changes
Breast cancer: Clinical
Anatomy of the female reproductive organs of the pelvis
Precocious puberty
Delayed puberty
Androgen insensitivity syndrome
5-alpha-reductase deficiency
Kallmann syndrome
Bladder exstrophy
Orgasmic dysfunction
Genito-pelvic pain and penetration disorder
Mastitis
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Paget disease of the breast
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Miscarriage
Gestational trophoblastic disease
Fetal hydantoin syndrome
Fetal alcohol syndrome
Disorders of sex chromosomes: Pathology review
Prostate disorders and cancer: Pathology review
Congenital TORCH infections: Pathology review
Disorders of sexual development and sex hormones: Pathology review
Testicular and scrotal conditions: Pathology review

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Content Reviewers

Yifan Xiao, MD,Justin Ling, MD, MS

Aromatase inhibitors, or AIs, are a type of medication used to treat breast cancer in postmenopausal people. However, they should only be used if the breast cancer is positive for estrogen receptors.

Breast cancer, or breast carcinoma, is an uncontrolled growth of epithelial cells within the breast. It’s the most common cancer in female individuals, and the second leading cause of cancer deaths after lung cancer.

Breasts are made up of 15 to 20 lobules, and inside each of these lie a bunch of grape-like structures called the alveoli. Zooming in on the alveoli, there’s a layer of alveolar cells that secrete breast milk into the lumen, which is the space in the center of the gland. These alveolar cells have receptors for certain hormones like, estrogen and progesterone, which are released by the ovaries, and prolactin which is released by the pituitary gland. These hormones stimulate the alveolar cells to divide and increase in number, which makes the lobule enlarge.

Just like healthy alveolar cells, some breast cancer cells have hormone receptors that allow them to grow in the presence of the hormones. When breast cancer cells have estrogen receptors, the cancer is called an ER-positive carcinoma. In this case, hormonal therapy is useful for adjuvant treatment, and includes medications which block the formation or effects of estrogen.

Aromatase inhibitors block the formation of estrogen by inhibiting the aromatase enzyme that converts androgen to estrogen. Now, before menopause, estrogen is mainly synthesized by the ovaries, where there’s a lot of androgen waiting to be converted. And the amount of aromatase enzyme in the ovary depends on the stimulation by gonadotropin. So, even if we gave this medication to premenopausal people with breast cancer, gonadotropin would induce synthesis of more aromatase, which would synthesize more estrogen. However, in postmenopausal people, estrogen is synthesized by other tissues, like the adrenal glands and fat tissue. Here, aromatase levels don’t depend on gonadotropin, so AIs can decrease aromatase and lower estrogen levels in postmenopausal people.

Now, there are two main types of aromatase inhibitors. Type I aromatase inhibitors are classified as steroidal competitive inhibitors because they are structurally similar to natural substrates of these enzymes - androgens. In other words, type I aromatase inhibitors work as fake substrates that bind the active site of the enzyme, and cause irreversible inhibition, also known as “suicide inhibition”. The most important medication in this group is exemestane.

Sources

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