Nutritional Ketosis: a Novel Metabolic Strategy to Treat Lymphedema Patients? (KETOLYMPH)

Lymphedema is a debilitating disorder that severely impairs the quality of life of the patients and requires life-long attention. It can be classified as primary or secondary, based on the etiology. Primary lymphedema is a rare, congenital disorder caused by inherited genetic mutation on a number of genes that are essential for lymphatic vessel development and function. Acquired (or secondary) lymphedema is a consequence of lymphatic trauma, predominantly due to surgery or radiotherapy for various types of cancers, with axillary and/or inguinal lymph node dissection being the most common cause. At the cellular level, perturbed or dysfunctional lymphatic drainage triggers accumulation of interstitial fluid, negatively affects cellular behavior, and induces infiltration of fibroblasts, adipocytes and keratinocytes, eventually leading to possible fibrosis and ulceration.

Upper extremity lymphedema most commonly affects breast cancer patients, while lower extremity lymphedema is typically associated with gynecological cancers, prostate cancer, lymphoma and melanoma. Besides the functional impairments, lymphedema severely reduces the quality of life, causing psychosocial problems such as depression, sexual dysfunctions, social avoidance and a decrease in self-confidence. While the prevalence of lymphedema is relatively high (1.33-1.44 pro mille), its true prevalence is likely underestimated and 1 in 6 patients undergoing treatment for a solid tumor ultimately develops lymphedema.

Nevertheless, treatment for lymphatic dysfunction remains largely symptomatic, without real cure. According to the International Society of Lymphology, lymphedema has to be treated with Decongestive Lymphatic Therapy, a two-stage treatment program. During the first or intensive phase, lymphedema has to be maximally reduced: this phase consists of skin care, manual lymph drainage (MLD), multi-layer bandaging and exercise therapy. The second or maintenance phase aims to conserve and optimize the result obtained in the first phase, and consists of skin care, compression by a low-stretch elastic sleeve, exercises and MLD. Skin care, multi-layer bandaging, elastic sleeve and exercises are treatment modalities that can be performed by the patients themselves, after careful instruction from the physician. On the contrary, MLD has to be applied by a physical therapist and hence entails a big financial cost for the patient and the Health Care. In addition, reductive techniques, such as direct excision and liposuction, can be applied to patients with more advanced stages of lymphedema with a predominant fibrofatty component. Encouraging initial results, i.e. symptomatic improvement and reduction in excess volume, have been obtained with lymphovenous bypass, the microsurgical anastomosis of collecting lymphatic vessels to adjacent venules, and vascularized lymph node transplantation, where lymph nodes are harvested from an unaffected region and transferred to the lymphedematous area. However, all the treatments available so far can offer only stabilisation of lymphedema and prevent further evolution, but they do not offer a definitive cure. There is thus a large unmet need to develop new effective therapies for lymphedema and, more general, lymph vessel dysfunction. In contrast to various strategies inhibiting lymphatic vessel growth, stimulating lymphatic vessel growth has been more challenging; there is currently no approved clinical strategy for ameliorating lymphatic dysfunctions. In this trial we will evaluate an entirely novel pro-lymphangiogenic strategy, not based on the delivery of lymphangiogenic growth factors, but rather based on modulating lymphatic endothelial cell metabolism. The lab of Angiogenesis and Vascular Metabolism (PCA lab), Catholic University Leuven, led by Prof. Peter Carmeliet recently reported that metabolism (glycolysis, fatty acid β-oxidation, glutamine metabolism) of endothelial cells, the cells lining blood vessels, controls vessel sprouting. Initial experiments from this PCA lab indicate that the Ketogenic Diet (KD) , which is effective in increasing the levels of ßOHB both in the plasma and lymph, ameliorates the disease outcome in the mouse (tail) model of lymphedema, by reducing edema formation over time. Strikingly, lymphangiography with Evans blue dye revealed that KD improves lymph vessel function, increasing dye uptake after subcutaneous injection in the lymphedematous tissue and its drainage into lymph, plasma and lymph nodes.

Based on these proof-of-concept data, the investigators plan to test this innovative concept to ameliorate lymph vessel dysfunction in lymphedema patients.

Randomisation will be performed between 3 arms: a ketogenic diet and a isocaloric diet without or including ketone monoester supplementation (KE).

After randomization and baseline measurements (determination of energy requirements and intake), the intervention will consist of 3 phases: a two week run-in period, 12 weeks of strict KD or KE and a 6 months Modified Atkins Diet or an isocaloric diet. The first phase, the two week run-in period, is the establishment of the individual ketosis level (on average after five days ketosis is introduced). During this run-in period, the exact ratio of lipids over proteins and carbohydrates will be determined per patient based on an isocaloric diet; this ratio will vary per patient and over time. During this run-in period, patients will become familiar with their diet, and in particular, they will learn which foods are allowed and which are not. To assist the patients, the ketobel program (a computer program developed by the metabolic dieticians of the Clinical Nutrition Unit, University Hospital Leuven) will allow the calculation of the exact amount of foods/lipids each patient can/needs to consume. The instructions given by the program will allow patients to create a menu according to their personal preferences, with the final aim of increasing the adherence to the KD. A dietician will assist every participant intensively in this run-in period (10 h/week). To ensure ketotic state, ketosis will be measured twice a day (morning and evening) using urinary sticks. If there is a change in the ketotic state for the KD, the lipid/non-lipid fraction ratio will be adjusted in collaboration with the dietician.

The KE group will include ketone esters within their dietary intake. Fixed doses of 25g will be consumed 3 times a day. Ingestion will be detached from a meal, with at least 4-hour intervals in between doses to induce 12 hours of ketosis. If blood β-OHB levels are substantially below 3mmol/L, a weight-based dosing of the KEs (up to 0.5g/kg bodyweight), rather than a fixed dosing strategy, will be utilized.

In the second phase, the patients following the KD for 12 weeks the dietician will assist the patient during this phase 2 hours/week. This support is necessary as the lipid/non-lipid ratio to obtain ketosis varies over time as well. The KE group will adhere to an isocaloric healthy diet including 3 doses of 25g of ketone esters daily. A researcher will assess on a weekly basis general health status, body parameters (weight, waist circumference), physical activity, weight loss and compliance to diet. The plasma metabolite profile (different types of cholesterol, triglycerides, fasting glucose, hsCRP, ketone bodies) will be performed every 3 weeks. To stimulate adherence to the diet, chat sessions will be organized between patients and a dietician, as moderator; these sessions will take place once a week and allow patients to exchange ideas/recipes about the diet and to motivate each other. These chat sessions have been organized previously by the members of the Clinical and Experimental Endocrinology group in other projects and were considered by the patients as an added value and a stimulation to continue with the intervention.

In the third phase, the patients' diet will be less strict and adapted to a Modified Atkins Diet. This shift is necessary to enhance adherence on the one hand and to allow follow-up for a longer period.