The cervix is integral to the maintenance of pregnancy and timely delivery of the baby. Mechanical failure of the cervix resulting in spontaneous preterm birth presents with collapse of the internal os, yet little is known about why the cervix behaves in this way. This may in part be due to research being technically limited and/or limited to punch biopsies of the distal cervix that did not include tissue from the internal os. The aim of this thesis was to re-evaluate cervical anatomy using novel laboratory and imaging methods to gain further insight into the structure of the cervix and how this may influence function during pregnancy.
To achieve this, whole cervical samples were obtained from women undergoing hysterectomy for benign pathology. Uterine tissue was subsequently fixed and analysed using 2D and 3D histological methods. Cervical anatomy was characterised using markers for smooth muscle and collagen and analysed using computer-assisted quantification methods. Sequential tissue slices were then reconstructed to produce 3D models of the proximal, middle and distal cervix.
High-resolution diffusion-tensor imaging was used to determine whether complex cervical anatomy could be visualised using radiological methods. Tissue was assessed using quantitative and qualitative diffusion methods, and directly compared to immunohistochemically stained tissue. The results obtained demonstrated that diffusion-tensor imaging accurately assessed cervical anatomy and provided further detail in terms of fibre volume, density and organisation. Ex vivo endoscopic ultrasound was used to assess whether current, established medical imaging technology could discern cervical smooth muscle and collagen fibres. Although this method could be used to identify gross anatomical structures, it was not an appropriate method to identify cervical microanatomy.
The results described in this thesis provide further insight into how the cervix resists intrauterine forces throughout pregnancy, and then dilates and effaces to allow for delivery of a fetus. Diffusion-tensor imaging accurately assessed cervical anatomy, which may have implications for in vivo characterisation of cervical remodelling during pregnancy and identifying those at risk of delivering early. Finally, observations in this thesis encourage continued re-examination of the cervix using high-resolution imaging to provide insight into function and to develop strategies to discern cervical insufficiency from other known causes of preterm birth
