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Currently, the ketogenic diet (KD) is used to treat obesity. A prospective study on the use of KD and nutraceutical correction of the nutritional status of patients with lipedema was carried out. Aim. To study the effect of the ketogenic diet, accompanied by correction of changes in the intestinal microbiome and hepatoprotection,on the reduction of fatty deposits in lipedema and the dynamics of changes in lipid and carbohydrate metabolism hormones. Material and methods. 60 patients with lower limb lipedema of stages I-III were randomized into 2 groups: Group 1 received a lowcalorie diet (LCD), physical exercises in the gym (PE), and physical activity (FA) in the form of daily walking up to 3-5 km/ day. Group 2 received a modified version of the Atkins ketogenic diet, physical exercises in the gym and FA, as well as nutraceutical correction of increased appetite, probiotic intestinal composition, hepatoprotection. The duration of the treatment course was 4 weeks. Anthropometric methods and bioimpedansometry were used to control limb circumferences, waist and thigh. Results and discussion. After treatment, patients in 1st group showed a decrease in body weight, lean and active cell mass, a decrease in musculoskeletal mass, and a decrease in total water due to extracellular water. A decrease in total cholesterol and high density lipoproteins (HDL) fraction, an increase in blood triglyceride fraction was noted. Leptin decreased by 12.73%. Patients of the 2nd group showed a decrease in body weight, fat mass, lean mass, total water and extracellular water. There was a decrease in total cholesterol, triglycerides, transaminases. Leptin decreased by 32.02%, insulin decreased by 9.87%. To prevent the development of fatty hepatosis against the background of the use of KD, patients of the 2nd group received nutraceutical correction: hepatoprotector Gepamin, metaprebiotic Stimbifid-plus, modulating the formation of resident intestinal microbiota. To reduce appetite, the patients of the 2nd group were also prescribed anorexic - an algal product Nativ containing the polysaccharide fucoidan, having a prebiotic effect. Improvement of reparative processes in the liver, suppression of oxidative processes also contributed to the restoration of the sensitivity of insulin receptors, which was confirmed by the normalization of the lipid-carbohydrate spectrum of blood in patients of the 2nd group after the course of the treatment. The insulin decrease in patients of Group 2 indicated not only insulin resistance decrease , but also the lipogenesis decrease and stimulation of lipolysis. Adipose tissue reduction due to lipolysis stimulation was also indicated by a decrease in leptin expression. Conclusion. Thus, a ketogenic diet, accompanied by nutraceutical correction of the intestinal microbiome and hepatoprotection can be effectively used in combination with physical activity in order to reduce body weight, fat mass and edema, as evidenced by a decrease in the expression level of leptin and insulin, correlating with the levels of fat loss and free water.

Lipedema is a chronic disease seen frequently in women that causes abnormal fat deposition in the lower limbs and associated bruising and pain. Despite increasing knowledge concerning lipedema, there are still aspects of diagnosis that need further investigation. We performed a prospective, observational cohort study to describe prevalence of clinical characteristics present in patients with lipedema in an attempt to establish diagnostic criteria. Participants were consecutive patients with lipedema presenting at a public hospital in Spain from September 2012 to December 2019. Patients were examined for the following signs and symptoms of lipedema: symmetrical involvement; disproportion between the upper and lower part of the body; sparing of the feet; pain; bruising; Stemmer' sign; pitting test; fibrosis; venous insufficiency; upper limbs involvement; vascular spiders; skin coldness; and lymphangitis attacks. In addition, orthopedic alterations were examined in all patients. We recruited 138 patients (median age=47.6 years; mean BMI=29.9 Kg/m2). Using waist-to-height-ratio, 41.3% of the patients were slim or healthy. The most frequent type of lipedema was Type III (71%), and most were in stage 1 and 2. The features of lipedema with a prevalence >80% were symmetrical involvement, unaffected feet, pain, bruising, vascular spiders, and disproportion. Pain was nociceptive in 60.2% and neuropathic in 33.1%, and there was a reduced social or working activities in 37.9%. Orthopedic alterations including cavusfeet or valgus-knees were observed in 1/3 of the patients. X-ray of the knees was performed in 63 patients and knee osteoarthritis diagnosed in 37. We found that the most frequent manifestations of lipedema were bilateral involvement, unaffected feet, pain, easy bruising, vascular spiders, and disproportion between the upper and lower parts of the body. These should be considered as major criteria for diagnosis. In addition, our findings on the prevalence of orthopedic alterations in patients with lipedema highlights the need for a multidisciplinary and integrated approach.

Abstract Liposuction, a method widely known to be used for esthetic reasons, can have particularly beneficial results in cases of certain pathological conditions. These include gynecomastia, lipomas, lipoedema, axillary hyperhidrosis, hypertrophic insulin lipodystrophy, correction of depressed scars.

Background: Lipedema is a chronic disorder of the adipose tissue that affects mainly women, characterised by symmetrical, excessive fatty tissue on the legs and pain. Standard conservative treatment is long-term comprehensive decongestive therapy (CDT) to alleviate lipedema-related pain and to improve psychosocial wellbeing, mobility and physical activity. Patients may benefit from surgical removal of abnormally propagated adipose tissue by liposuction. The LIPLEG trial evaluates the efficacy and safety of liposuction compared to standard CDT. Methods/design: LIPLEG is a randomised controlled multicentre investigator-blinded trial. Women with lipedema (n=405) without previous liposuction will be allocated 2:1 to liposuction or CDT. The primary outcome of the trial is leg pain reduction by ≥2 points on a visual analogue scale ranging 0–10 at 12 months on CDT or post-completion of liposuction. Secondary outcomes include changes in leg pain severity, health-related quality of life, depression tendency, haematoma tendency, prevalence of oedema, modification physical therapy scope, body fat percentage, leg circumference and movement restriction. The primary analysis bases on intention-to-treat. Success proportions are compared using the Mantel-Haenszel test stratified by lipedema stage at a 5% two-sided significance level. If this test is statistically significant, the equality of the response proportions in the separate strata is evaluated by Fisher’s exact test in a hierarchical test strategy. Discussion: LIPLEG assesses whether surgical treatment of lipedema is safe and effective to reduce pain and other lipedema-related health issues. The findings of this trial have the potential to change the standard of care in lipedema. Trial registration: ClinicalTrials.gov NCT04272827. Registered on February 14, 2020. Trial status: Protocol version is 02_0, December 17, 2019

Background: Lipedema is a chronic, progressive disease that occurs almost exclusively in women and leads to pathological, painful fat growths at the extremities. Only symptomatic therapy can be offered since the etiology of the disease has not yet been clarified. Liposuction in tumescent anesthesia has established itself as a surgical treatment method of choice. The complication rate associated with the procedure and the pharmacological course and safety of treatment in patients with lipedema has not yet been sufficiently studied.The aim of the study was to broaden the evidence on the safety of ambulatory high-volume liposuction in tumescent anesthesia in lipedema patients. Influencing factors of patients (weight, fat content, comorbidities) or the process technique (drug administration, volume of aspirates) should be investigated on the safety and risks of tumescent anesthesia. This was a retrospective data analysis in which data from 27 patients (40 liposuction procedures) treated at the Sandhofer and Barsch lipedema center between 2016 and 2018 were evaluated. The liposuctions were carried out in tumescent anesthesia and using a Power-Assisted Liposuction system. Clinical examinations and regular blood samples were carried out before the procedure, intra- and postoperatively. The procedures lasted an average of 118 minutes and an average of 6111 ml of aspirate was removed. For tumescent anesthesia, patients were given an average lidocaine dose of 34.23 mg/kg body weight and an epinephrine dose of 0.11 mg/kg body weight. No relevant complications associated with drug side effects, hypovolemia or hypervolemia or blood loss were detected. Liposuction under high volume tumescent anesthesia for the treatment of lipedema patients is, even for major intervention, a safe procedure.

Iliac vein compression (IVC) is a common anatomic disorder affecting more than 20% of the adult population, especially young females. Most of those patients are asymptomatic. Some of them will develop symptoms in their left leg, such as swelling, pain, and heaviness. But progression to venous claudication, skin changes, and even venous ulceration is possible. Intolerance to exercise is an undervalued symptom. The most feared complication is the development of a deep venous thrombosis (DVT) and pulmonary embolism (PE). In addition to the symptomatology, the diagnosis can be confirmed using duplex ultrasound, computed tomographic (CT) scan, or magnetic resonance (MR) venography. However, for the exact measurement of the degree of stenosis and indication for stenting, intravascular ultrasound (IVUS) is the preferred tool for assessing iliac vein compression. Those patients are, especially in combination with other risk factors, at higher risk for developing DVT and PE. However, it is difficult to identify the patients who will benefit from a treatment (stenting) in terms of symptomatology and quality of life (QOL) or even in effective DVT prevention. Venous stenting is the treatment of choice and seems to be safe and effective. Poststenting antiplatelet medication is most appropriate for patients with nonthrombotic IVC, whereas postthrombotic patients should preferably be treated with oral anticoagulants. Meticulous selection of patients for treatment is necessary to avoid over-treatment.

The term lipedema is misleading, although it is true that there is an alteration of the fatty tissue, there is little evidence regarding edema. It is considered a disease since the last ICD‑11 (2019), included in the section of pathologies of skin, fat and subcutaneous cellular tissue. However, there are still doubts about whether it should be considered a disease or whether it is an aesthetic disorder. The diagnosis of lipedema can present challenges, since it is often confused with other nosological entities; especially with lymphedema. The aim of this task is to determine the basis for a correct differential diagnosis that helps to recognize lipedema as an entity with its own characteristics in order to facilitate its early identification. Clinical manifestations, plus the anamnesis and detailed examination of each patient, may be sufficient to reach a correct diagnosis. In case of doubt, there are tests capable of differentiating between lipedema and lymphedema. Differential diagnosis between lipedema and lymphedema should be made thoroughly and early in order to offer early advice and specific treatment to patients.

Lipedema is a chronic and progressive disease characterized by a symmetrical and bilateral swelling of the lower extremities. In general, the feet are not involved. Lipedema is believed to affect nearly 1 in 9 adult women worldwide. Despite this relatively common disease, lipedema is often confused with primary lymphedema or obesity. In clinically advanced lipedema stages, fat continues to build up and may block the lymphatic vessels causing a secondary lymphedema (Lipo-Lymphedema). We consecutively evaluated 54 women with a clinical diagnosis of lower limbs lipedema. Two doses of 99mTc-nanocolloid were injected intradermally at the first intermetatarsal space and in the lateral malleolar area. Two static planar scans were taken at rest immediately following the intradermal injection. Subsequently, all patients were asked to perform an isotonic muscular exercise (stepping) for 2 min. Then, post exercise scans were performed to monitor the tracer pathway. Subsequently, the patient was asked to take a 30-40 min walk (prolonged exercise) and delayed scans were acquired. In early clinical stages, the lymphatic flow is usually preserved and the rest/stress intradermal lymphoscintigraphy may visualize a normal lymphatic drainage with a frequent pattern (tortuous course) of the leg lymphatic pathway. In clinically advanced stages, lymph stagnation areas were observed. Unlike obesity, lipedema fat storage is resistant to dietary regimen, bariatric surgery, and physical activity. Surgical treatment (tumescent liposuction and reductive surgery) is the most effective treatment to remove adipose tissue. Complex decongestive therapies are helpful in reducing the lymph stagnation, especially in patients with advanced lipolymphedema.

Lipedema (LI) is a common yet misdiagnosed condition, often misconstrued with obesity. LI affects women almost exclusively, and its painful and life-changing symptoms have long been thought to be resistant to the lifestyle interventions such as diet and exercise. In this paper, we discuss possible mechanisms by which patients adopting a ketogenic diet (KD) can alleviate many of the unwanted clinical features of LI. This paper is also an effort to provide evidence for the hypothesis of the potency of this dietary intervention for addressing the symptoms of LI. Specifically, we examine the scientific evidence of effectiveness of adopting a KD by patients to alleviate clinical features associated with LI, including excessive and disproportionate lower body adipose tissue (AT) deposition, pain, and reduction in quality of life (QoL). We also explore several clinical features of LI currently under debate, including the potential existence and nature of edema, metabolic and hormonal dysfunction, inflammation, and fibrosis. The effectiveness of a KD on addressing clinical features of LI has been demonstrated in human studies, and shows promise as an intervention for LI. We hope this paper leads to an improved understanding of optimal nutritional management for patients with LI and stimulates future research in this area of study.

Multiple associated comorbidities have been described for lipedema patients. Disease diagnosis still remains challenging in many cases and is frequently delayed. The purpose of this study was to determine the most common comorbidities in lipedema patients and the impact of surgical treatment onto disease progression. A retrospective assessment of disease-related epidemiologic data was performed for patients who underwent liposuction between July 2009 and July 2019 in a specialized clinic for lipedema surgery. All patients received a standardized questionnaire regarding the clinical history and changes of lipedema-associated symptoms and comorbidities after surgery. 106 patients who underwent a total of 298 liposuction procedures were included in this study after returning the questionnaire fully filled-in. Multiple comorbidities were observed in the assessed collective. The prevalence for obesity, hypothyroidism, migraine, and depression were markedly increased in relation to comparable nonlipedema populations. Despite a median body mass index (BMI) of 31.6 kg/m2 (IQR 26.4-38.8), unexpected low prevalence of diabetes (5%) and dyslipidemia (7%) was found. Diagnosis and initiation of guideline-appropriate treatment were delayed by years in many patients. After surgical treatment (medium follow-up 20 months, IQR 11-42), a significant reduction of lipedema-associated symptoms was demonstrated. Lipedema occurs with a diversity of associated comorbidities. Therefore, on the basis of available data, the authors suggest the necessity of a multimodal therapy concept for a comprehensive and holistic treatment. Despite a commonly increased BMI, lipedema patients appear to have an advantageous metabolic risk profile.

<b><i>Introduction:</i></b> Lipoedema is characterized as subcutaneous lipohypertrophy in association with soft-tissue pain affecting female patients. Recently, the disease has undergone a paradigm shift departing from historic reiterations of defining lipoedema in terms of classic edema paired with the notion of weight loss-resistant leg volume towards an evidence-based, patient-centered approach. Although lipoedema is strongly associated with obesity, the effect of bariatric surgery on thigh volume and weight loss has not been explored. <b><i>Material and Methods:</i></b> In a retrospective cohort study, thigh volume and weight loss of 31 patients with lipoedema were analyzed before and 10–18 and ≥19 months after sleeve gastrectomy (SG) or Roux-en-Y gastric bypass (RYGB). Fourteen patients, with distal leg lymphoedema (i.e., with healthy thighs), who had undergone bariatric surgery served as controls. Statistical analysis was performed using a linear mixed-effects model adjusted for patient age and initial BMI. <b><i>Results:</i></b> Adjusted initial thigh volume in patients with lipoedema was 23,785.4 mL (95% confidence interval [CI] 22,316.6–25,254.1). Thigh volumes decreased significantly in lipoedema and control patients (baseline vs. 1st follow-up, <i>p</i> &#x3c; 0.0001 and <i>p</i> = 0.0001; baseline vs. 2nd follow-up, <i>p</i> &#x3c; 0.0001 and <i>p</i> = 0.0013). Adjusted thigh volume reduction amounted to 33.4 and 37.0% in the lipoedema and control groups at the 1st follow-up, and 30.4 and 34.7% at the 2nd follow-up, respectively (lipoedema vs. control <i>p</i> &#x3e; 0.999 for both). SG and RYGB led to an equal reduction in leg volume (operation type × time, <i>p</i> = 0.83). Volume reduction was equally effective in obese and superobese patients (weight category × time, <i>p</i> = 0.43). <b><i>Conclusion:</i></b> SG and RYGB lead to a significant thigh volume reduction in patients with lipoedema.

Background: Fluid in lymphedema tissue appears histologically as spaces around vessels and between dermal skin fibers. Lipedema is a painful disease of excess loose connective tissue (fat) in limbs, almost exclusively of women, that worsens by stage, increasing lymphedema risk. Many women with lipedema have hypermobile joints suggesting a connective tissue disorder that may affect vessel structure and compliance of tissue resulting in excess fluid entering the interstitial space. It is unclear if excess fluid is present in lipedema tissue. The purpose of this study is to determine if fluid accumulates around vessels and between skin fibers in the thigh tissue of women with lipedema. Methods: Skin biopsies from the thigh and abdomen from 30 controls and 80 women with lipedema were evaluated for dermal spaces and abnormal vessel phenotype (AVP): (1) rounded endothelial cells; (2) perivascular spaces; and (3) perivascular immune cell infiltrate. Women matched for body mass index (BMI) and age were considered controls if they did not have lipedema on clinical examination. Data were analyzed by analysis of variance (ANOVA) or unpaired t-tests using GraphPad Prism Software 7. p < 0.05 was considered significant. Results: Lipedema tissue mass increases beginning with Stage 1 up to Stage 3, with lipedema fat accumulating more on the limbs than the abdomen. AVP was higher in lipedema thigh (p = 0.003) but not abdomen skin compared with controls. AVP was higher in thigh skin of women with Stage 1 (p = 0.001) and Stage 2 (p = 0.03) but not Stage 3 lipedema versus controls. AVP also was greater in the thigh skin of women with lipedema without obesity versus lipedema with obesity (p < 0.0001). Dermal space was increased in lipedema thigh (p = 0.0003) but not abdomen versus controls. Dermal spaces were also increased in women with lipedema Stage 3 (p < 0.0001) and Stage 2 (p = 0.0007) compared with controls. Conclusion: Excess interstitial fluid in lipedema tissue may originate from dysfunctional blood vessels (microangiopathy). Increased compliance of connective tissue in higher stages of lipedema may allow fluid to disperse into the interstitial space, including between skin dermal fibers. Lipedema may be an early form of lymphedema. ClinicalTrials.gov: NCT02838277.

The article discusses the launching by MA Healthcare of the European Lipoedema Association as of October 2020 to improve the diagnosis and management of lipoedema by creating standard and evidence-based guidelines. The association was launched with the help of leading lymphology specialist Tobias Bertsch. Also cited is how lipoedema affects the adipose tissue.

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Compression hosiery is commonly used for the management of lymphoedema as well as lipoedema, but it is more commonly indicated for the lower limbs than for the upper limbs. The effects of compression hosiery on upper-limb lipoedema are poorly understood and researched. It is known that compression hosiery works in conjunction with activity or movement when standing or walking, which produces anti-inflammatory and oxygenating effects in the tissues. This effect is naturally difficult to realise in the upper limbs. Lymphoedema practitioners who treat those with lipoedema should bear in mind that compression treatment might not produce the same effects in upper-limb lipoedema as it does in lower-limb lipoedema. In these times of an overstretched health service, pragmatic resource use is essential.