Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>), also known as dinoprostone, is a naturally occurring prostaglandin with oxytocic properties that is used as a medication. Dinoprostone is used in labor induction, bleeding after delivery, termination of pregnancy, and in newborn babies to keep the ductus arteriosus open. In babies it is used in those with congenital heart defects until surgery can be carried out. It is also used to manage gestational trophoblastic disease. It may be used within the vagina or by injection into a vein.
PGE<sub>2</sub> synthesis within the body begins with the activation of arachidonic acid (AA) by the enzyme phospholipase A<sub>2</sub>. Once activated, AA is oxygenated by cyclooxygenase (COX) enzymes to form prostaglandin endoperoxides. Specifically, prostaglandin G<sub>2</sub> (PGG<sub>2</sub>) is modified by the peroxidase moiety of the COX enzyme to produce prostaglandin H<sub>2</sub> (PGH<sub>2</sub>) which is then converted to PGE<sub>2</sub>.
Common side effects of PGE<sub>2</sub> include nausea, vomiting, diarrhea, fever, and excessive uterine contraction. In babies there may be decreased breathing and low blood pressure. Caution should be taken in people with asthma or glaucoma and it is not recommended in those who have had a prior C-section. It works by binding and activating the prostaglandin E<sub>2</sub> receptor which results in the opening and softening of the cervix and dilation of blood vessels.
Prostaglandin E<sub>2</sub> was first synthesized in 1970 and approved for medical use by the FDA in the United States in 1977. It is on the World Health Organization's List of Essential Medicines. Prostaglandin E<sub>2</sub> works as well as prostaglandin E<sub>1</sub> in babies.
Dinoprostone has important effects in labor by inducing softening of the cervix and causing uterine contraction, and also stimulates osteoblasts to release factors that stimulate bone resorption by osteoclasts.
Natural prostaglandins, including PGE<sub>1</sub> and PGE<sub>2</sub>, are important in the structure and function of the ductus arteriosus in fetuses and newborns. They allow the ductus arteriosus to remain open, providing the necessary connection between the pulmonary artery and descending aorta that allows the blood to bypass the fetus's underdeveloped lungs and be transported to the placenta for oxygenation. The ductus arteriosus normally begins to close upon birth due to an increase of PGE<sub>2</sub> metabolism, but in newborns with congenital heart disease, prostaglandins can be used to keep the ductus arteriosus open longer than normal to sustain healthy oxygen saturation levels in the blood. Although PGE<sub>1</sub> is more commonly used in this setting, there has been a report of oral PGE<sub>2</sub> being used to treat ductus-dependent congenital heart diseases in newborns to delay surgical treatment until the pulmonary arteries grew. In addition, PGE<sub>2</sub> was used in another report to dilate the ductus arteriosus in newborns with various cardiovascular defects to allow for better perfusion of the lungs and kidneys. On the other hand, the post-partal synthesis of PGE<sub>2</sub> in newborns is considered one cause of patent ductus arteriosus.
When administered in aerosol form, PGE<sub>2</sub> serves as a bronchodilator, but its use in this setting is limited by the fact that it also causes coughing.
PGE<sub>2</sub>, similarly to PGE<sub>1</sub>, acts as a direct vasodilator by acting on smooth muscle to cause dilation of blood vessels. In addition, PGE<sub>2</sub> inhibits platelet aggregation.
PGE<sub>2</sub> also suppresses T cell receptor signaling and proliferation, and may play a role in resolution of inflammation. In addition, PGE<sub>2</sub> limits the immune response by preventing B-lymphocyte differentiation and their ability to present antigens.
Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) has a variety of functions within the central nervous system and peripheral nervous system. When PGE<sub>2</sub> interacts with EP<sub>3</sub> receptors, it increases body temperature, resulting in fever. PGE<sub>2</sub> is also a predominant prostanoid that contributes to inflammation via enhancing edema and leukocyte infiltration from increased vascular permeability (allowing more blood flow into an inflamed area of the body) when acting on EP<sub>2</sub> receptors. The use of nonsteroidal anti-inflammatory drugs (NSAIDs) blocks the activity of COX-2, resulting in a decrease of PGE<sub>2</sub> production. NSAIDs blocking COX-2 and decreasing the production of PGE<sub>2</sub> remediates fever and inflammation.
Additionally, PGE<sub>2</sub> acting on EP<sub>1</sub> and EP<sub>4</sub> receptors are a component in feeling pain via inflammatory nociception. When PGE<sub>2</sub> binds to EP<sub>1</sub> and EP<sub>4</sub> receptors, an increase in excitability via cation channels as well as inhibition of hyperpolarizing potassium (K+) channels, increase membrane excitability. As a result, this causes peripheral nerve endings to report painful stimuli.
As mentioned previously, prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) contributes to the inflammation when bound to EP<sub>2</sub> receptors. In terms of immunity, prostaglandins have the ability to regulate lymphocyte function. PGE<sub>2</sub> affects T-lymphocyte formation by regulating apoptosis of immature thymocytes. In addition, it can suppress an immune response by inhibiting B lymphocytes from forming into antibody-secreting plasma cells. When this process is suppressed, it causes a decrease in a humoral antibody response because of the decrease in production of antibodies. PGE<sub>2</sub> also has roles in inhibition of cytotoxic T-cell function, cell division of T-lymphocytes, and the development of TH1 lymphocytes.
In response to physiologic and psychologic stress, prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) is involved in several inflammation and immunity pathways. As one of the most abundant prostaglandins in the body, PGE<sub>2</sub> is involved in almost all typical inflammation markers such as redness, swelling, and pain. It regulates these responses through binding to G coupled protein prostaglandin E<sub>2</sub> receptors (EP<sub>1</sub>, EP<sub>2</sub>, EP<sub>3</sub>, and EP<sub>4</sub>). The activation of these different EP receptors is dependent on the type of triggering stress stimuli and results in the corresponding stress response. Activation of EP<sub>1</sub> via PGE<sub>2</sub> results in the suppression of impulse behaviors in response to psychological stress. PGE<sub>2</sub> is involved in regulating illness-induced memory impairment via activation of EP<sub>2</sub>. PGE<sub>2</sub> activation of EP<sub>3</sub> results in regulation of illness induced fever. EP<sub>4</sub> is functionally similar to EP<sub>2</sub> and has also been shown in studies to have a role in hypothermia and anorexia. In addition to inflammatory effects, PGE<sub>2</sub> has been shown to have anti-inflammatory effects as well, due to its different actions on varying receptors.
Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) serves a significant role in vascular smooth muscle tone regulation. It is a vasodilator produced by endothelial cells. It promotes vasodilation of smooth muscles by increasing the activity of cyclic adenosine monophosphate (cAMP) to decrease intracellular calcium levels via the IP and EP<sub>4</sub> receptors. Conversely, PGE<sub>2</sub> can also induce vasoconstriction via activation of EP<sub>1</sub> and EP<sub>3</sub> receptors, which activates the Ca2+ pathway and decreased cAMP activity.
Within the gastrointestinal tract, PGE<sub>2</sub> activates smooth muscles to cause contractions on longitudinal muscle when acting on EP<sub>3</sub> receptors. In contrast, PGE<sub>2</sub> effects on respiratory smooth muscle result in relaxation.
Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>), along with other prostaglandins, are synthesized within the cortex and medulla of the kidney. The role of renal COX-2-derived PGE<sub>2</sub> within the kidney is to maintain renal blood flow and glomerular filtration rate (GFR) through localized vasodilation. COX-2-derived prostanoids work to increase medullary blood flow as well as inhibit sodium reabsorption within kidney tubules. PGE<sub>2</sub> also assists the kidneys with systemic blood pressure control by modifying water and sodium excretion. In addition, it is also thought to activate EP<sub>4</sub> or EP<sub>2</sub> to increase renin release, resulting in an elevation of GFR and sodium retention to raise systemic blood pressure levels within the body.
In the setting of labor and delivery, cervical ripening (also known as cervical effacement) is a natural process that occurs before labor, in which the cervix becomes softer, thinner, and dilated, enabling the fetus to pass through the cervix. A ripe cervix is favorable prior to induction of labor, which is a common obstetric practice, and increases the chances for a successful induction. Pharmacological methods are sometimes required to induce cervical ripening that does not occur naturally. The natural ripening of the cervix is mediated by prostaglandins, thus a common pharmacological method is to use external prostaglandins such as PGE<sub>2</sub>, or dinoprostone. Results of a systematic review and meta-analysis of the literature found that outpatient cervical ripening with dinoprostone or single-balloon catheters did not increase the risk of cesarean deliveries.
Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) achieves cervical ripening and softening by stimulating uterine contractions as well as directly acting on the collagenase present in the cervix to soften it. There are currently two formulations of PGE<sub>2</sub> analog available for use in cervical ripening: Prepidil, a vaginal gel, and Cervidil, a vaginal insert. PGE<sub>2</sub> is similar to oxytocin in terms of successful labor induction and the time from induction to delivery.
PGE<sub>2</sub> is a common pharmacological method of termination of pregnancy, particularly in the second trimester or for missed abortion, which is a miscarriage in which the fetus did not evacuate the uterus. However, PGE<sub>2</sub> is not feticidal, and only induces abortion by stimulating uterine contractions. It is recommended that 20 mg of dinoprostone vaginal suppository be administered every three to five hours to evacuate the uterus. The abortion should occur within 24 hours after the beginning of administration of dinoprostone; if it does not, dinoprostone should no longer be given and other interventions would be required, such as dilation and curettage.
A common side effect of prostaglandin E<sub>2</sub> is its effect on gastrointestinal smooth muscle resulting in nausea, vomiting and diarrhea. Other side effects include headache, shivering, and chills. The suppository form of prostaglandin E<sub>2</sub> is associated with increased severity of these symptoms. Fever is also a common side effect with use of prostaglandin E<sub>2</sub>. Administration of prostaglandin E<sub>2</sub> should be stopped if a person experiences side effects such as fever.
The insert and gel forms have been shown to have minimal gastrointestinal effects, but are more associated with increase stimulation of the uterus as well as fetal distress. Uterine hyperstimulation is effectively treated by stopping use of prostaglandin E<sub>2</sub>. Other monitoring parameters include sustained uterine contractions and fetal distress. In babies there may be decreased breathing and low blood pressure. Care should be taken in people with asthma or glaucoma and it is not recommended in those who have had a prior C-section.
Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) binds to G protein-coupled receptors (GPCRs) EP<sub>1</sub>, EP<sub>2</sub>, EP<sub>3</sub>, and EP<sub>4</sub> to cause various downstream effects to cause direct contractions in the myometrium. In addition, PGE<sub>2</sub> inhibits Na+ absorption within the Thick Ascending Limb (TAL) of the Loop of Henle and ADH-mediated water transport in collecting tubules. As a result, blockage of PGE<sub>2</sub> synthesis with NSAIDs can limit the efficacy of loop diuretics.
Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) should only be administered by, or under the direct supervision of, a physician and careful monitoring should be performed. PGE<sub>2</sub> comes in many dosage forms with varying pharmacokinetic properties. For example PGE<sub>2</sub> can come in a gel formulation that requires six hour dosing or it can come as a slow release dinoprostone pessary that does not need to be re-administered and can be taken out if necessary. In a quality improvement project done in UK, the switch from prostaglandin gel to the slow release dinoprostone pessary was able to lower cesarian section rates in women undergoing induction of labor in maternity care.
For the vaginal insert (brand name Cervidil), the manufacturer recommends keeping the medication frozen until use since it does not need to be warmed to room temperature. Once the package is open, a water miscible lubricant may be used to insert the medication, using your finger place the device into the vagina and position the device transversely in the posterior vaginal fornix. The person receiving the drug should remain laying down for two hours after administration of the insert is complete. The manufacturer also recommends waiting 30 minutes after removal of insert before starting oxytocin.
The vaginal gel (brand name Prostin E2, Canada) is administered through a prefilled syringe and the medication is placed in the posterior fornix of the vagina. After administration people should stay laying down for at least 30 minutes after they have received the drug.
Contraindications to a medication are any reasons to not use the drug. Prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) is used to induce labor and should not be used in people that are contraindicated to give birth vaginally or spontaneous labor. PGE<sub>2</sub> should not be used in people with allergies to prostaglandins or any components in the drugs formulations. PGE<sub>2</sub> should be stopped before other oxytocic agents like oxytocin are given.
Dinoprostone as a vaginal suppository is contraindicated for women with acute pelvic inflammatory disease or active disease of the cardiovascular, respiratory, hepatic, or renal systems. Caution is required for people with a history of cervical malignancy, hypo- or hypertension, anemia, epilepsy, jaundice, asthma, or pulmonary diseases. The suppository formulation is also not indicated for viable fetus evacuation.
Endocervical gel is contraindicated in those with who have a history of C-sections or major uterine surgery, if the fetus is in distress and delivery is not imminent, vaginal bleeding throughout the pregnancy that is unexplained, history of difficult labors and deliveries, have cephalopelvic disproportion, less than six previous term babies with nonvertex presentation, hyper or hypotonic uterine patterns.
When prostaglandin E<sub>2</sub> (PGE<sub>2</sub>) is given in excess, hyper-stimulation of the uterus occurs and immediate discontinuation of the drug usually results in resolution of toxic effects. If symptoms continue a beta adrenergic drug (e.g. terbutaline) can be used.
There are many different dosage forms of PGE<sub>2</sub>. The pharmacokinetic properties vary between dosage forms and should not be interchanged. A medication error was cited in the Institute for Safe Medication Practices where Prostin E2 was used in place of Cervidil. The hospital had run out of Cervidil which is a 10 mg endocervical insert and the provider decided to use half of a 20 mg Prostin E2 vaginal suppository. Cervidil delivers the drug at a constant rate and can be removed as necessary while Prostin E2 dissolves immediately and can not be removed. This error resulted in an emergency C-section since the fetus's heart rate dropped suddenly.
The synthetic PGE<sub>2</sub> dinoprostone has a plasma half-life of approximately 2.5âÂÂ5 minutes, after vaginal administration, with most metabolites being excreted in the urine. The first step in metabolism involves oxidation to 15-ketoprostaglandin E2 by the enxyme 15-hydroxyprostaglandin dehydrogenase (NAD+)
Swedish physiologist Ulf von Euler and British physiologist M.W. Goldblatt, first discovered prostaglandins independently in 1935 as factors contained in human seminal fluid. Prostaglandins were noted for having blood pressure reducing effects and smooth muscle regulation effects. Prostaglandin E<sub>2</sub> itself was identified in 1962 by Swedish biochemist Sune Bergström in the seminal fluid of sheep. The structure of prostaglandins is conserved in mammals, but it is also produced by marine organisms which allowed for more research into their biological roles. Prostaglandins were discovered to be products of arachidonic acid and with the ability to radio label arachidonic acid in the early 1960s, American chemist E.J. Corey was able to synthesize prostaglandin E<sub>2</sub> in the lab in the 1970. This advancement paved the way for later studies that helped define the actions and response of prostaglandin E<sub>2.</sub> Prostaglandin E<sub>2</sub> was approved for medical use in the United States in 1977 and it is on the World Health Organization's List of Essential Medicines. Prostaglandin E<sub>2</sub> was approved by the FDA in 1977.