Synthetic PEG Hydrogel for Engineering the Environment of Ovarian Follicles.

The functional unit within the ovary is the ovarian follicle, which is also a morphological unit composed of three basic cell types: the oocyte, granulosa, and theca cells. Similar to human ovarian follicles, mouse follicles can be isolated from their ovarian environment and cultured in vitro to study folliculogenesis, or follicle development for days or weeks. Over the course of the last decade, follicle culture in a three-dimensional (3D) environment exponentially improved the outcomes of in vitro folliculogenesis. Follicle culture in 3D environments preserves follicle architecture and promotes the cross talk between cells in the follicle. Hydrogels, such as polyethylene glycol (PEG), have been used for various physiological systems for regenerative purposes because they provide a 3D environment similar to soft tissues, allow diffusion of nutrients, and can be readily modified to present biological signals, including cell adhesion ligands and proteolytic degradation facilitated by enzymes secreted by the encapsulated cells. This chapter outlines the application of PEG hydrogels to the follicle culture, including the procedures to isolate, encapsulate, and culture mouse ovarian follicles. The tunable properties of PEG hydrogels support co-encapsulation of ovarian follicles with somatic cells, which further promote follicle survival and growth in vitro through paracrine and juxtacrine interactions.

Fibrosis worsens chronic lymphedema in rodent tissues.

Secondary lymphedema in humans is a common consequence of lymph node dissection (LND) to treat breast cancer. A peculiar characteristic of the disease is that lifelong swelling often precipitously appears several years after the surgical treatment, often due to an inflammatory stimulus. Although the incidence of secondary lymphedema dramatically increases after radiation therapy, the relationship between fibrotic scarring and the eventual appearance of lymphedema remains unclear. To clarify the role of fibrosis in secondary lymphedema initiation, we chemically increased fibrosis in rodent tissues with bleomycin and assessed the ability of the local lymphatic system to prevent lymphedema, either acutely or in a chronic state induced by inflammation. We found that bleomycin injections exacerbated fibrotic matrix deposition in an acute mouse tail lymphedema model (P < 0.005), reduced wound closure (P < 0.005), and impaired the ability of tail lymphatics to regenerate (P < 0.005) and reduce the swelling (P < 0.05). When fibrosis was worsened with bleomycin after axillary LND in the rat foreleg, the ability of the foreleg lymphatic system to reduce the chronic state swelling induced by stimulated inflammation was severely impaired (P < 0.005). Indocyanine green lymphography in axillary LND-recovered rat forelegs revealed a worsened lymphatic drainage due to inflammation and bleomycin pretreatment. Although inflammation reduced the drainage of dextran fluid tracer from control forelegs (P < 0.05), the reduction in fluid drainage was more severe after axillary LND when fibrosis was first increased (P < 0.005). These findings demonstrate that fibrosis reduces the lymphatic capacity to functionally regenerate and prevent the chronic appearance of lymphedema.

The multicomponent medication lymphomyosot improves the outcome of experimental lymphedema.

BACKGROUND: Secondary lymphedema is a life-long disease of painful tissue swelling that often follows axillary lymph node dissection to treat breast cancer. It is hypothesized that poor lymphatic regeneration across the obstructive scar tissue during the wound healing process may predispose the tissue to swell at a later date. Treatment for lymphedema remains suboptimal and is in most cases palliative. The purpose of this study was to evaluate the ability of Lymphomyosot to treat tissue swelling and promote lymphangiogenesis in experimental models of murine lymphedema. METHODS: Experimental models of mouse lymphedema were injected with varied amounts of Lymphomyosot and saline as control. Measurements of tail swelling and wound closure were taken and compared amongst the groups. Three separate groups of mice were analyzed for lymphatic capillary migration, lymphatic vessel regeneration, and macrophage recruitment. RESULTS: Lymphomyosot significantly reduced swelling and increased the rate of surgical wound closure. Lymphomyosot did not increase the migration of lymph capillaries in a mouse tail skin regeneration model or regeneration of lymph vessels following murine axillary lymph node dissection. CONCLUSIONS: Lymphomyosot may act through inflammatory and wound repair pathways to reduce experimental lymphedema. Its ability to regulate inflammation as well as assist in tissue repair and extracellular formation may allow for the production of a scar-free matrix bridge through which migrating cells and accumulated interstitial fluid can freely spread.

A chronic and latent lymphatic insufficiency follows recovery from acute lymphedema in the rat foreleg.

Secondary lymphedema in humans is a common consequence of axillary lymph node dissection (ALND) to treat breast cancer. Remarkably, secondary lymphedema generally first appears following a delay of over a year and can be triggered suddenly by an inflammatory insult. However, it remains unclear why the apparently functional lymphatic system is unable to accommodate an inflammatory trigger. To provide mechanistic insight into the delayed and rapid secondary lymphedema initiation, we compared the ability of the ALND-recovered rat foreleg lymphatic system to prevent edema during an inflammatory challenge with that of the uninjured lymphatic system. At 73 days postsurgery, the forelegs of ALND(-)- and ALND(+)-sensitized rats were exposed to the proinflammatory agent oxazolone, which was found to reduce fluid drainage and increase skin thickness in both ALND(-) and ALND(+) forelegs (P < 0.05). However, drainage in the ALND-recovered forelegs was more severely impaired than ALND(-) forelegs, as visualized by indocyanine green lymphography and quantified by interstitial transport of fluid marker (P < 0.05). Although both ALND(+) and ALND(-) forelegs experienced significant inflammation-induced edema with the oxazolone exposure (P < 0.05), the peak tissue swelling in the ALND(+) group was significantly greater than that of the ALND(-) forelegs (arm area peaked at ∼13.4 vs. ∼5.7% swelling, respectively, P < 0.005; wrist diameter peaked at 9.7 vs. 2.2% swelling, respectively, P < 0.005). The findings demonstrate that outward recovery from ALND in the rat foreleg masks an ensuing chronic and latent lymphatic insufficiency, which reduces the ability of the foreleg lymphatic system to prevent edema during an acute inflammatory process.

Increased hyaluronan expression at distinct time points in acute lymphedema.

Lymphatic dysfunction in lymphedema results in chronic accumulation of interstitial fluid and life-long tissue swelling. In the absence of restored lymphatic drainage via adequate lymphangiogenesis, the interstitial environment can remodel in ways that decrease the elevated interstitial stress. Presently, relatively little is known about the glycosaminoglycans (GAGs) that become upregulated in the interstitium during lymphedema. We employed a mouse tail model of acute lymphedema that reproduces important features of the chronic human condition to establish a relationship between hyaluronan (HA) and sulfated GAG concentration with tissue swelling. We found that HA was upregulated by tissue injury at day 5 and became upregulated again by skin swelling (HA content increasing by 27% relative to controls at days 15 and 20). Surprisingly, the second phase of HA expression was associated with the declining phase of the tail skin swelling (tail diameter significantly decreasing by 17% from day 10 peak to day 20), demonstrating that HA is upregulated by tissue swelling and may help to counteract the edema in the mouse tail. This finding was confirmed by intradermal injection of an HA degrading enzyme (hyaluronidase) to the swollen tail, which was found to worsen the tail swelling. Sulfated GAGs, including chondroitin sulfate (CS), were not regulated by tissue swelling. The results demonstrate that HA, but not sulfated GAGs, is upregulated in the interstitium by acute tissue swelling. We speculate that HA expression during lymphedema may be part of a natural adaptive mechanism of the interstitial environment to reduce capillary filtration and increase interstitial fluid outflow following lymphatic obstruction and fluid accumulation.

Functional recovery of fluid drainage precedes lymphangiogenesis in acute murine foreleg lymphedema.

Secondary lymphedema in humans is a common consequence of axillary lymph node dissection (ALND) to treat breast cancer. It is commonly hypothesized that lymphatic growth is required to increase fluid drainage and ameliorate lymphedema. Although there is a pronounced alteration in the balance of interstitial forces regulating fluid transport that sustains the chronic form of lymphedema, it is presently unknown whether changes occur to the balance of interstitial forces during acute lymphedema that may play a role in the recovery of fluid drainage. Here, we compared the relative importance of lymphangiogenesis of lymphatic vessels and interstitial flows for restoring fluid drainage and resolving acute lymphedema in the mouse foreleg after ALND. We found that removal of the axillary lymph nodes reduced lymph drainage in the foreleg at days 0 and 5 postsurgery, with fluid tracer spreading interstitially through subcutaneous tissues. Interstitial fluid drainage returned to normal by day 10, whereas functional regrowth of lymphatic vessels was first detected by indocyanine green fluorescence lymphography at day 15, demonstrating that the recovery of interstitial fluid drainage preceded the regrowth of lymphatic vessels. This was confirmed by the administration of VEGF receptor-3-neutralizing antibodies, which completely blocks lymphatic regrowth. It was found that the recovery of interstitial fluid drainage and the natural resolution of acute lymphedema produced by ALND were not hindered by VEGF receptor-3 neutralization, demonstrating that interstitial fluid drainage recovery and the resolution of acute lymphedema are lymphangiogenesis independent. The data highlight the central role of the interstitial environment in adapting to lymphatic injury to increase fluid drainage.