Interplay between Gut Lymphatic Vessels and Microbiota

Lymphatic vessels play a distinctive role in draining fluid, molecules and even cells from interstitial and serosal spaces back to the blood circulation. Lymph vessels of the gut, and especially those located in the villi (called lacteals), not only serve this primary function, but are also responsible for the transport of lipid moieties absorbed by the intestinal mucosa and serve as a second line of defence against possible bacterial infections. Here, we briefly review the current knowledge of the general mechanisms allowing lymph drainage and propulsion and will focus on the most recent findings on the mutual relationship between lacteals and intestinal microbiota.

Postmastectomic lymphedema prevention: modern possibilities

A three-dimensional computer model of the topographic and anatomical variants of the lymph nodes in the axillary fossa gives reason to doubt the indisputability of the known data on the normal anatomy of the lymph nodes. This mainly concerns the presence of a lateral (shoulder) group of axillary lymph nodes (4-6 nodes), which can be located not only on the medial, but also on the posterior surface of the shoulder. In some cases, this group of axillary lymph nodes is generally absent in its typical place and is in close proximity to the central (intermediate) group of lymph nodes. Attention to the lateral (shoulder) group of lymph nodes is due to the fact that through them lymph drainage occurs from the entire superficial (epifascial) lymphatic system of the volar surface of the upper limb (skin and subcutaneous tissue). From the lateral group of lymph nodes, lymph drainage goes either to the central group or to the deltapectoral lymph nodes. In the course of axillary lymph node dissection of I, II and III levels in breast cancer, it is possible to save only the deltapectal lymph node with its afferent and efferent vessels, which provides full-fledged lymphatic drainage from the dorsolateral surface of the upper limb. But in this situation, without lymphatic drainage (superficial and deep) with preserved lymph production, the inner (volar) part of the upper limb remains, where lymphostasis begins to develop. An exception is the variant of localization of the brachial group of lymph nodes on the posterior surface of the shoulder, in which it is possible to preserve the lateral group of lymph nodes, which does not fall into the block of adipose tissue with other regional lymph nodes, and therefore partially preserve the lymph drainage from the medial surface of the ipsilateral upper limb towards the deltapectoral lymph node. Taking into account the topographic and anatomical variability of the lymph drainage collectors in the axillary fossa and the varied nature of the involvement of lymph nodes in the metastatic process, in each clinical case, the standard preoperative mapping of axillary lymph nodes (reverse lymphatic mapping) does not allow predicting the risk and timing of the development of postoperative upper limb lymphedema. The advantage of our technology two-contrast fluorescent lymphography - is the possibility of visual differentiation of all elements of lymph drainage from the mammary gland (indocyanine green - ICG) and the ipsilateral upper limb (methylene blue - MB). According to the results of the study, it will be possible to clarify the localization of the lateral (shoulder) group of axillary lymph nodes, topographic and anatomical features of the lymphatic drainage collectors in the axillary fossa and indications for lymphovenous shunting for primary surgical prevention of postmastectomy lymphedema of the upper limb.

Comparison of the Immediate Effect of Petrissage Massage and Manual Lymph Drainage Following Exercise on Biomechanical and Viscoelastic Properties of the Rectus Femoris Muscle in Women

Context: Fast and adequate recovery after exercise and activity is important for increasing performance and preventing injuries. Inadequate recovery usually causes changes in the biomechanical and viscoelastic properties of the muscle. Objective: To compare the immediate effect of petrissage massage (PM) and manual lymph drainage (MLD) following submaximal exercise on the biomechanical and viscoelastic properties of the rectus femoris muscle in healthy women. Design: Cross-sectional, repeated-measures. Setting: Marmara University. Participants: 18 healthy female students. Intervention(s): Following the submaximal quadriceps strengthening exercise performed in 3 sets of 8 repetitions with intensity of 75% of 1 maximum repetition, participants’ right leg received a 5-minute PM (PM group) and the contralateral leg received a 5-minute MLD application (MLD group). Main Outcome Measures: Skin temperature was measured using P45 thermographic thermal camera (Flir System; ThermaCAM, Danderyd, Sweden), and muscle tone, biomechanical, and viscoelastic features were measured with a myometer (Myoton AS, Tallinn, Estonia) at baseline, immediately postexercise, post-PM/MLD application, and 10 minutes postexercise. Results: In the PM group, the tonus (P = .002) and stiffness (P < .001) values measured after the massage and at the end of the 10-minute resting period were found to be statistically different than those measured right after the exercise (P < .05). Relaxation time and creep values at all measurement times were significantly different (P < .05). In the MLD group, it was observed the tonus (P < .001), stiffness (P = .025), and relaxation time (P < .01) values decreased significantly after the MLD compared with the values measured after the exercise; however, the creep value was found to be significantly different in all measurements (P < .05). Conclusion: PM and MLD reduce passive tissue stiffness and improve the extent of muscle extensibility over time against the muscle tensile strength. PM and MLD are therapeutic methods that can be used to support tissue recovery after exercise and prevent injuries.

Mesenteric Lymph Duct Drainage Attenuates Lung Inflammatory Injury and Inhibits Endothelial Cell Apoptosis in Septic Rats

The present study was to investigate the effect of mesenteric lymph duct drainage on lung inflammatory response, histological alteration, and endothelial cell apoptosis in septic rats. Animals were randomly assigned into four groups: control, sham surgery, sepsis, and sepsis plus mesenteric lymph drainage. We used the colon ascendens stent peritonitis (CASP) procedure to induce the septic model in rats, and mesenteric lymph drainage was performed with a polyethylene (PE) catheter inserted into mesenteric lymphatic. The animals were sacrificed at the end of CASP in 6 h. The mRNA expression levels of inflammatory mediators were measured by qPCR, and the histologic damage were evaluated by the pathological score method. It was found that mesenteric lymph drainage significantly reduced the expression of TNF-α, IL-1β, and IL-6 mRNA in the lung. Pulmonary interstitial edema and infiltration of inflammatory cells were alleviated by mesenteric lymph drainage. Moreover, increased mRNA levels of TNF-α, IL-1β, IL-6 mRNA, and apoptotic rate were observed in PMVECs treated with septic lymph. These results indicate that mesenteric lymph duct drainage significantly attenuated lung inflammatory injury by decreasing the expression of pivotal inflammatory mediators and inhibiting endothelial apoptosis to preserve the pulmonary barrier function in septic rats.

Using thermal imaging to measure changes in breast cancer-related lymphoedema during reflexology

Reflexology lymph drainage (RLD) for breast cancer-related lymphoedema (BCRL) may have a positive impact on arm swelling and pain. Thermal imaging is a means of tracking temperature change by visual images. This study aimed to explore the use of thermal imaging in treatment for BCRL. The swollen arms of two participants with BCRL were photographed using a thermal imaging camera during a single RLD treatment. Limb Volume Circumferential Measurement (LVCM) of both arms was taken before, after and the next day. The images were examined for visual changes, and temperature data were extracted. Images showed differences in temperature within the affected hand and arm over 45 minutes. LVCM data indicated a loss of limb volume in the affected arm in both cases, which continued to decrease over 24 hours. Thus, thermal imaging may be useful in tracking temperature change during treatment for BCRL.