Postgraduate Cancer Education and Training in Lithuania: Harmonization According to the EU Rules.

The purpose of this article is to discuss Lithuanian postgraduate cancer education according to the data of 2013. In Lithuania, a specialization in an area called clinical oncology is absent; as independent specialities in oncology, there are both medical oncologists and radiation oncologists. These types of oncologists complete rigorous residency training in the clinics. Separate courses are provided in different residency programmes. Currently, there are two medical oncology and radiation oncology programmes for 3rd-, 4th- and 5th-year residents, one at the National Cancer Institute and another at the Lithuanian University of Health Sciences and Kaunas Clinics. Today, there are only 45 radiation oncologists and 56 medical oncologists licensed in Lithuania. This means that each radiation oncologist and medical oncologist is providing for 397 and 319 new cancer cases per year, respectively, or there are 0.3 practising in the major specialties of oncology per 10,000 population. Most other medical residency programmes expose their trainees to oncology for only 1 month either in the 1st or the 2nd year of residency. Due to the growing number of new cancer cases worldwide, these programmes have to be extended, especially for family and internal medicine residents. Lithuanian postgraduate cancer education and training is in the process of harmonization according to the EU rules. All the Lithuanian residency programmes are certificated by an independent public agency and are recognized by a number of countries, including all the countries of the EU.

Cancer education in Lithuania.

The aim of this article is to describe cancer education in Lithuania according to the data of 2013. In Lithuania, there are the following stages of education for physicians: basic education through integrated studies of medicine (six years), postgraduate education through residency studies (four to five years), and continuing professional development. In recent years, integrated studies of medicine have been the most popular specialty. Oncology is incorporated into the teaching courses in medicine programmes. In each university, an oncology course is mandatory during these studies. In Lithuania, there are two types of specialists related to oncology: medical oncologists and radiation oncologists. These oncologists complete multidisciplinary residency study programmes in the clinics. To receive a doctoral degree, specialists may join PhD programmes at any of the accredited universities. In recent years the number of dissertations in oncology has grown. Notably, oncology is chosen not only by students in the field of medicine. It also becomes the choice of those seeking a doctorate in the fields of nursing, public health, biochemistry, and physics. The professional development of oncologists is a lifelong commitment. In Lithuania, continuing specialist medical training is mandatory. This requirement is ensured with the process of licensing of medical practice. All Lithuanian study programmes are certificated by an independent public agency and are recognised by a number of other countries as well.

[Fluorescence diagnostics of skin tumors using 5-aminolevulinic acid and its methyl ester]. / Odos naviku fluorescencine diagnostika naudojant 5-aminolevulinine rugsti ir jos metilinta esteri.

OBJECTIVE: The incidence of malignant skin tumors is rapidly increasing. Early diagnosis, determining the margins of the tumor, is extremely important to achieve good treatment results. We investigated fluorescence of protoporphyrin IX in skin carcinomas. The study aimed to compare the effectiveness of topical 5-aminolevulinic acid and methyl-aminolevulinate in determining the exact margins of skin tumors. MATERIALS AND METHODS: Fluorescence measurements were performed in 126 patients with malignant, premalignant, and benign skin lesions for detection of the margins of squamous cell carcinoma and basal cell carcinoma. 5-Aminolevulinic acid or its methyl ester was applied to the skin lesion for 2-4 h, and the data of evaluated protoporphyrin IX fluorescence were correlated with the data of morphological tissue examination. RESULTS: Malignant tissue shows a specific red fluorescence when illuminated with blue-violet light, whereas no fluorescence was observed in normal skin. In 30% of cases, the delineation of neoplastic lesions excited by 5-aminolevulinic acid was slightly weaker than using methyl-aminolevulinate. A sensitivity of 95.4% and a specificity of 88.6% as well as positive and negative predictive values of 86.1% and 96.3%, respectively, were obtained. CONCLUSIONS: Fluorescence diagnostics can be used for complete visualization of malignant skin lesions after topical application of 5-aminolevulinic acid or methyl aminolevulinate. It has been shown to be highly effective in the diagnostics of malignant superficial skin lesion. This method is applicable for detecting early superficial tumors, margins of tumors, and follow-up after therapy. Topical application of methyl aminolevulinate is slightly superior to 5-aminolevulinic acid in detection of lesion margins.

Skin and mucosal fluorescence diagnosis with different light sources.

At the laboratory of Laser and Photodynamic Treatment (Institute of Oncology, Vilnius University) 98 patients with various kinds of skin and mucosal malignant, pre-malignant and benign lesions underwent 5-aminolevulinic acid (ALA) or its methyl ester (methyl aminolevulinate)-induced protoporphyrin IX (PpIX), or hematoporphyrin derivate (HpD) fluorescence imaging. Intensity and all other changes of fluorescence were evaluated and compared with the pathological findings. Margins of tumours were clearly outlined under fluorescent vision, giving a helpful contribution to diagnosis and therapy, even in clinically non-visible tumours. Most of the malignant tumours were found to be fluorescent, whereas no fluorescence was observed in normal skin and mucosa. In the blue light mode, there is background blue fluorescence in normal tissue and red fluorescence in malignant areas. The suitability of different light wavelengths for fluorescence diagnosis (FD) was compared. From our data the most appropriate wavelength for this purpose is 401 nm.