Trimester-Specific Hemodynamic and Blood Volume Adaptations in Pregnancy: A Systematic Review of Normal and High-Risk Populations: Trimester-Specific Hemodynamic and Blood Volume Adaptations in Pregnancy

Azhar Ijaz; Saadia Anwar; Ommia Kalsoom; Najma Fida; Misbah Aslam; Muhammad Umair

doi:10.54393/pjhs.v6i5.3115

Authors

Azhar Ijaz Department of Physiology, Loralai Medical College, Loralai, Pakistan
Saadia Anwar Department of Physiology, Jinnah Medical College, Peshawar, Pakistan
Ommia Kalsoom Department of Physiology, Women Medical College, Abbottabad, Pakistan
Najma Fida Department of Physiology, Kabir Medical College, Peshawar, Pakistan
Misbah Aslam Department of Physiology, Quetta Institute of Medical Sciences, Quetta, Pakistan
Muhammad Umair Department of Physiology, Gomal Medical College, Medical Training Institute, Dera Ismail Khan, Pakistan

DOI:

https://doi.org/10.54393/pjhs.v6i5.3115

Keywords:

Maternal Blood Volume, Cardiac Output, Systemic Vascular Resistance, Pregnancy Hemodynamic, Fetal Growth Restriction, Obesity, Trimester-Specific Adaptation

Abstract

Pregnancy involves significant cardiovascular adaptations, including increased blood volume, cardiac output (CO), and reduced systemic vascular resistance (SVR), which are essential to support fetal development. While these changes are well established, the timing, magnitude, and variability across maternal risk profiles remain inconsistently reported. Objectives: To synthesize original research from 2015 to 2025 examining trimester-specific changes in maternal hemodynamic and blood volume, with a focus on both normal and high-risk pregnancies. Methods: Systematic searches were conducted in PubMed, Science Direct, Scopus, and Wiley Online Library. Inclusion criteria encompassed original English-language studies involving human pregnancies that assessed maternal blood volume or cardiovascular parameters using validated methods. Extracted data were synthesized across four domains: study characteristics, trimester-wise trends, methodology, and quality. Results: Nine studies met the inclusion criteria. Most reported a rise in CO and plasma volume from early to mid-pregnancy, alongside a reduction in SVR. In contrast, high-risk groups, including those with fetal growth restriction (FGR), preeclampsia (PE), and obesity, demonstrated impaired adaptation, marked by persistently high SVR and reduced stroke volume. Conclusions: It was concluded that trimester-specific hemodynamic adaptation is essential for healthy pregnancy progression. Deviations in high-risk populations may serve as early markers of complications. Incorporating non-invasive cardiovascular monitoring into routine prenatal care may improve risk stratification and outcomes.

Author Biographies

Saadia Anwar, Department of Physiology, Jinnah Medical College, Peshawar, Pakistan

Ommia Kalsoom, Department of Physiology, Women Medical College, Abbottabad, Pakistan

Najma Fida, Department of Physiology, Kabir Medical College, Peshawar, Pakistan

Misbah Aslam, Department of Physiology, Quetta Institute of Medical Sciences, Quetta, Pakistan

Muhammad Umair, Department of Physiology, Gomal Medical College, Medical Training Institute, Dera Ismail Khan, Pakistan

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Trimester-Specific Hemodynamic and Blood Volume Adaptations in Pregnancy: A Systematic Review of Normal and High-Risk Populations