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Lipedema can cause chronic pain and increases patients’ risk for conditions such as lymphedema and venous disease. This author explores how lipedema affects the body, why its effects are disproportionate in the lower body, and how to diagnose and manage the condition.

BACKGROUND: People with lipedema or Dercum's disease (DD) can have a similar distribution of excess painful nodular subcutaneous adipose tissue (SAT), making them difficult to differentiate. METHODS: Case series of 94 patients with DD, 160 with lipedema and 18 with both diagnoses (Lip+DD) from a single clinic in an academic medical center to improve identification and differentiation of these disorders by comparison of clinical findings, prevalence of type 2 diabetes (DM2), hypermobility by the Beighton score and assessment of a marker of inflammation, Total complement activity (CH50). RESULTS: Differences between groups were by Student's t-test with α of 0.05. The Lipedema Group had significantly greater weight, body mass index (BMI), gynoid distributed nodular SAT and fibrotic and heavy tissue than the DD Group. Hypermobility was significantly higher in the Lipedema (58±0.5%) than DD Group (23±0.4%; P<0.0001). DM2 was significantly greater in the DD (16±0.2%; P=0.0007) than the Lipedema Group (6±0.2%). Average pain by an analog scale was significantly higher in the DD (6±2.5%) than the Lipedema Group (4±2.1%; P<0.0001). Fatigue and swelling were common in both groups. Easy bruising was more common in the Lipedema Group, whereas abdominal pain, shortness of breath, fibromyalgia, migraines and lipomas were more prevalent in the DD Group. The percentage of patients with elevated CH50 was significantly positive in both groups. CONCLUSIONS: The significantly lower prevalence of DM2 in people with lipedema compared with DD may be due to the greater amount of gynoid fat known to be protective against metabolic disorders. The high percentage of hypermobility in lipedema patients indicates that it may be a comorbid condition. The location of fat, high average daily pain, presence of lipomas and comorbid painful disorders in DD patients may help differentiate from lipedema.

Background: Butcher’s broom plant extract has been reported to improve lymphatic flow and the trace mineral, selenium, has been shown to improve lymphedema. This retrospective case study examines the effectiveness of Butcher’s broom in conjunction with selenium to decrease limb volume of a patient with lipedema, a common fat distribution disorder with excess adipose tissue fluid. Methods: Selenium (400 mcg) was initiated 6 days prior to limb volume evaluation utilizing perometry. The patient underwent physical therapy that consisted of manual lymph drainage (MLD) with Histological Variable Manual Technique (HIVAMAT), and compression bandaging. Butcher’s broom (one gram daily) was added on day 95 of treatment in addition to selenium and both were continued through day 293 (end of study). Results: Total volume reduction over the study period for the left and right upper extremities and left and right lower extremities was 525 ml and 225 ml (p<0.05), and 1769 ml and 1614 ml (p<0.0001), respectively. The total percent volume reduction during the time period when MLD with HIVAMAT and compression bandaging were performed for the left and right legs was 70.6 and 79.0%, respectively. In the absence of compression bandaging, the left and right arms lost 21.2 and 10% of initial volumes, respectively at the 6 month follow-up visit. During the latter part of the study when the patient was performing a home maintenance program, at which time selenium and Butcher’s broom were continued, the left and right lower extremities decreased an additional 29.4 and 20.9% of initial volumes, respectively, despite a lack of exercise due to a foot injury during the last 46 days. Conclusion: Butcher’s broom and selenium may offer new tools in conjunction with physical therapy to improve swelling and pain associated with lipedema.

Background: Butcher’s broom plant extract has been reported to improve lymphatic flow and the trace mineral, selenium, has been shown to improve lymphedema. This retrospective case study examines the effectiveness of Butcher’s broom in conjunction with selenium to decrease limb volume of a patient with lipedema, a common fat distribution disorder with excess adipose tissue fluid. Methods: Selenium (400 mcg) was initiated 6 days prior to limb volume evaluation utilizing perometry. The patient underwent physical therapy that consisted of manual lymph drainage (MLD) with Histological Variable Manual Technique (HIVAMAT), and compression bandaging. Butcher’s broom (one gram daily) was added on day 95 of treatment in addition to selenium and both were continued through day 293 (end of study). Results: Total volume reduction over the study period for the left and right upper extremities and left and right lower extremities was 525 ml and 225 ml (p<0.05), and 1769 ml and 1614 ml (p<0.0001), respectively. The total percent volume reduction during the time period when MLD with HIVAMAT and compression bandaging were performed for the left and right legs was 70.6 and 79.0%, respectively. In the absence of compression bandaging, the left and right arms lost 21.2 and 10% of initial volumes, respectively at the 6 month follow-up visit. During the latter part of the study when the patient was performing a home maintenance program, at which time selenium and Butcher’s broom were continued, the left and right lower extremities decreased an additional 29.4 and 20.9% of initial volumes, respectively, despite a lack of exercise due to a foot injury during the last 46 days. Conclusion: Butcher’s broom and selenium may offer new tools in conjunction with physical therapy to improve swelling and pain associated with lipedema.

Lipoedema is painful nodular subcutaneous adipose tissue (SAT) on legs and arms of women sparing the trunk. People with Dercum disease (DD) have painful SAT masses. Lipoedema and DD fat resists loss by diet and exercise. Treatments other than surgery are needed. Six women with lipoedema and one with DD underwent twelve 90-min sessions over 4 weeks. Body composition by dual X-ray absorptiometry scan, leg volume, weight, pain, bioimpedance, tissue size by caliper and ultrasound were analysed before and after SAT therapy by paired t-tests. There was a significant decrease from baseline to end of treatment in weight, 87.6 ± 21 to 86.1 ± 20.5 kg (P = 0.03), leg fat mass 17.8 ± 7.7 to 17.4 ± 7.6 kg (P = 0.008), total leg volume 12.9 ± 4 to 12 ± 3.5 L (P = 0.007), six of 20 calliper sites and tissue oedema. Pain scores did not change significantly. By ultrasound, six women had 22 hyperechoic masses in leg fat that resolved after treatment; five women developed seven new masses. Fascia improved by ultrasound after treatment. SAT therapy reduced amount and structure of fat in women with lipoedema and Dercum disease; studies are needed to compare SAT therapy to other therapies.

BACKGROUND: Mast cells are immune cells that mediate hypersensi-tivity and allergic reactions in the body, secreting histamine and other inflammatory molecules. They have been associated with different inflammatory conditions such as obesity and other adipose tissue di-sorders. Lipedema is a chronic disease characterized by an abnormal accumulation of adipose tissue on the legs and arms, pain, and other symptoms. Mast cells may play a role in the pathology of lipedema. OBJECTIVE: Pilot study to determine levels of histamine and its metabolites in lipedema subcutaneous adipose tissue (SAT) biopsy samples, and to test sodium cromoglycate for the treatment of mast cells in women with lipedema. METHODS: Biopsies from lipedema and control SAT were collected and analyzed histologically for the presence of mast cells. Mass spec-trometry was used to measure the levels of histamine, a key marker of mast cells, and its metabolites in SAT in women with lipedema and controls, and after a group of women with lipedema were administered oral and topical doses of sodium cromoglycate for two weeks. RESULTS: Histological examination of biopsies from lipedema patients confirmed the presence of mast cells. Metabolomic analysis revealed high levels of histamine and its metabolites in samples from women with lipedema compared to controls. Following a two-week treatment period, lipedema tissue samples exhibited reduced levels of histamine, suggesting a reduction of mast cell activity. CONCLUSION: Sodium cromoglycate has the ability to stabilize mast cells and reduce histamine levels in lipedema patients, which could be useful in lowering the symptoms of lipedema.

BACKGROUND: Lipedema, a complex and enigmatic adipose tissue disorder, remains poorly understood despite its significant impact on the patients' quality of life. Genetic investigations have uncovered potential contributors to its pathogenesis, including somatic mutations, which are nonheritable genetic alterations that can play a pivotal role in the development of this disease. AIM: This review aims to elucidate the role of somatic mutations in the etiology of lipedema by examining their implications in adipose tissue biology, inflammation, and metabolic dysfunction. RESULTS: Studies focusing on leukocyte clones, genetic alterations like TET2 and DNMT3A, and the intricate interplay between adipose tissue and other organs have shed light on the underlying mechanisms driving lipedema. From the study of the scientific literature, mutations to genes correlated to three main pathways could be involved in the somatic development of lipedema: genes related to mitochondrial activity, genes related to localized disorders of subcutaneous adipose tissue, and genes of leukocyte clones. CONCLUSIONS: The insights gained from these diverse studies converge to highlight the complex genetic underpinnings of lipedema and offer potential avenues for therapeutic interventions targeting somatic mutations to alleviate the burden of this condition on affected individuals.

OBJECTIVE: The aim of this qualitative review is to provide an update on the current understanding of the genetic determinants of lipedema and to develop a genetic test to differentiate lipedema from other diagnoses. MATERIALS AND METHODS: An electronic search was conducted in MEDLINE, PubMed, and Scopus for articles published in English up to March 2019. Lipedema and similar disorders included in the differential diagnosis of lipedema were searched in the clinical synopsis section of OMIM, in GeneCards, Orphanet, and MalaCards. RESULTS: The search identified several genetic factors related to the onset of lipedema and highlighted the utility of developing genetic diagnostic testing to help differentiate lipedema from other diagnoses. CONCLUSIONS: No genetic tests or guidelines for molecular diagnosis of lipedema are currently available, despite the fact that genetic testing is fundamental for the differential diagnosis of lipedema against Mendelian genetic obesity, primary lymphedema, and lipodystrophies.

Adipocytes express various enzymes, such as aldo-keto reductases (AKR1C), 11β-hydroxysteroid dehydrogenase (11β-HSD), aromatase, 5α-reductases, 3β-HSD, and 17β-HSDs involved in steroid hormone metabolism in adipose tissues. Increased activity of AKR1C enzymes and their expression in mature adipocytes might indicate the association of these enzymes with subcutaneous adipose tissue deposition. The inactivation of androgens by AKR1C enzymes increases adipogenesis and fat mass, particularly subcutaneous fat. AKR1C also causes reduction of estrone, a weak estrogen, to produce 17β-estradiol, a potent estrogen and, in addition, it plays a role in progesterone metabolism. Functional impairments of adipose tissue and imbalance of steroid biosynthesis could lead to metabolic disturbances. In this review, we will focus on the enzymes involved in steroid metabolism and fat tissue deposition.