Pre-eclampsia is diagnosed when a pregnant woman develops high blood pressure (two separate readings taken at least 6 hours apart of 140/90 or more) and 300 mg of protein in a 24 hour urine sample (proteinuria). Swelling or edema(especially in the hands and face)was originally considered an important sign for a diagnoses of pre-eclampsia, but in current medical practice only hypertension and proteinuria are necessary for a diagnoses.

Some women develop high blood pressure without the proteinuria, this is called Gestational Hypertension or, Pregnancy Induced Hypertension (PIH). Both Preeclampsia and PIH are very serious conditions and require careful monitoring of mother and baby.

Appearance

Pre-eclampsia is much more common in the first pregnancy (3-5% of births) and usually becomes evident in the third trimester (and virtually always after the 20th week of pregnancy). It is also more common in women who have preexisting hypertension, diabetes,renal disease, and family history of pre-eclampsia. It is also more common in women with a multiple gestation (twins, triplets and more).

Pre-eclampsia may also occur in the immediate post-partum period or up to 6-8 weeks post-partum. This is referred to as "post partum pre-eclampsia".

Causes

Pre-eclampsia is thought to be caused by inflammatory mediators secreted by the placenta and acting on the vascular endothelium. If severe, it progresses to fulminant pre-eclampsia, with headaches and visual disturbances, and further to HELLP syndrome and eclampsia. These are life-threatening conditions for both the developing fetus and the mother.

Pathogenesis

There are many theories on the pathogenesis of preeclampsia, although the exact cause is not known. Most involve abnormal development of the placenta, which leads to a distressed placenta that secretes factors into the maternal blood. These factors damage the maternal blood vessels, leading to high blood pressure and protein in the urine. In normal placenta the decidual spiral arteries are invaded by extravillous trophoblasts which makes the arteies eventually open into trophoblastic cavities called lacunae (though they are initially kept plugged by the trophoblasts). The invading trophoblasts replace some of the smooth muscles and endothelium of these arteries near the implantation site. This is supposed to help the spiral arteries to widen into thin and funnel like near their opening into the lacunae. This establishes a high capacity and low resistance circulation. The maternal blood in the lacunar network bath the chorionic villi lined by syncytiotrophoblast, supplying oxygen and nutrients to, and removing metabolic wastes from, the fetal circulation which is not in direct contact with the maternal blood. In case of preeclampsia the spiral arteries are insufficiently invaded by trophoblasts. They remain narrow and the smooth mucle layer (tunica media) around the arteries become hyperplastic. This leads to insufficient maternal perfusion of the placenta in preeclampsia. One of the factors, released into blood from the placenta, that has been speculated (by Karumanchi et al) to be a mediator of the "toxemia", is a soluble splice variant isoform of the VEGF receptor 1 (sFlt 1).

Read more at Wikipedia.org

• [List your site here Free!]

Mapping the theories of preeclampsia: the role of homocysteine
From Alternative Medicine Review, 6/1/05 by L.E. Mignini

Mignini LE, Latthe PM, Villar J, et al. Obstet Gynecol 2005;105:411-425.

OBJECTIVE: We conducted a systematic review to examine the hypothesized mechanism through which homocysteine could lead to preeclampsia. DATA SOURCES: We searched MEDLINE, EMBASE, BIOSIS, SciSearch, and bibliographies of primary and review articles, and we contacted experts. METHODS OF STUDY SELECTION: Of the 25 relevant primary articles, 8 studies measured total serum homocysteine concentrations before the clinical onset of preeclampsia (1,876 women), whereas 17 measured it afterward (1,773 women). Meta-analytic techniques were used to examine consistency, strength, temporality, dose-response, and plausibility of the disease mechanisms implicating folate, vitamin B(6), vitamin B(12), genetic polymorphisms, oxidative stress, and endothelial dysfunction in the pathway linking hyperhomocysteinemia to preeclampsia. TABULATION, INTEGRATION, AND RESULTS: Overall, there were higher serum homocysteine concentrations among pregnant women with preeclampsia than among those with uncomplicated pregnancies, but the results were heterogeneous (P =. 12; I(2) = 38.8%). Among studies with temporality, the size of association was smaller than that among those without (weighted mean difference 0.68 mumol/L versus 3.36 mumol/L; P < .006). There was no dose-response relationship between homocysteine concentration and severity of preeclampsia. The mechanisms underlying hyperhomocysteinemia (folate and vitamin B(12) deficiency and genetic polymorphisms) were not found to be plausible, but markers of oxidative stress and endothelial dysfunction were higher in hyperhomocysteinemia. CONCLUSION: Homocysteine concentrations are slightly increased in normotensive pregnancies that later develop preeclampsia and are considerably increased once preeclampsia is established. However, because of a lack of consistency in data, dose-response relationship, and biologic plausibility, the observed association cannot be considered causal from the current literature.

Return to Preeclampsia

Home

Contact

Resources

Exchange Links

ebay