Autologous fat grafting (AFG) has been widely used as an injectable substance for breast reconstruction in cosmetic surgery; however, the clinical outcome of AFG is generally considered an unpredictable procedure, with long-term retention commonly varying between 20 and 90%, which is believed to be caused by poor blood supply in the early after grafting. Negative pressure using external volume expansion (EVE) has long been theorized as a potential means to precondition the recipient bed. In addition, the mechanical force has been confirmed to play a pivotal role in mesenchymal stem cells proliferation and differentiation. Accordingly, to investigate the effects of in vivo mechanical loading of EVE on cell proliferation, vascular growth and subsequent maturation as well as cellular markers, proliferation capacity and differentiation potential of adipose stem cells (ASCs) in subcutaneous fat, a swine model was devised to take advantage of anatomical and physiological similarities in skin and subcutaneous tissue between pigs and human. In this study, pigs were treated with continuous suction at -50 mmHg during the same eight-hour (9:00-17:00) interval each day until 10 or 21 days. Before sampling on day-11 or 22, an ultrasonography was performed to study the soft tissue thickness and results revealed that EVE-induced soft tissue enlargement is a transient effect. Specimens from control and treated groups conducted a various analysis. The result of H&E staining showed that EVE can enhance the process of vascular remodeling but has no significant effect on adipocytes size and numbers. IHC stain with Ki67 showed cell proliferation in basal keratinocytes and adipocytes did not appear significant difference as compared with the non-treated group; in contrast, vascular networks layered with smooth muscle cells increased in EVE treated groups as evident by the α-SMA staining. On the other hand, the epidermal thickness was measured by image J but no significant difference was observed across the groups. Immunofluorescence stain with CD31 suggested that blood vessel density would gradually increase with the loading time of EVE. Stromal vascular fraction (SVF) cells and ASCs were isolated and purified from fat tissue, respectively. Proliferation capacity of ASCs was measured by doubling time and colony-forming assay but no statistical difference was found between the control and EVE treated groups. ASCs were subjected to adipogenic induction for 21 days followed by Oil-Red O staining and adipogenic differentiation potential of ASCs had no significant difference across the groups. Flow cytometry analysis showed regardless of treatment interval, ASCs expressed mesenchymal markers such as CD29, CD44, CD90, CD105 while lacking expression of hematopoietic marker such as CD34. Multicolor flow cytometric analysis of SVF cells revealed no significant difference in the ratio of ASCs across the groups; in contrast, the percentage of endothelial cells of EVE treated groups significantly increased as treatment lengthened when compared with the control group. In conclusion, the predominant mechanism of action of EVE, which would modulate neovascular network formation, growth and maturation of functional blood vessels. The preconditioning effect of EVE has been demonstrated in the swine model, which may be easily translated into clinical practices to enhance cell and tissue engraftment. It is expected that this understanding may help clinicians to optimize the vascularity of the recipient bed to further improve fat volume retention before the operation.