Journal of Nanomedicine & Biotherapeutic Discovery

Journal of Nanomedicine & Biotherapeutic Discovery
Open Access

ISSN: 2155-983X

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Research Article - (2014) Volume 4, Issue 2

Novel Approach for Designing Supportive Care in Genetic Disorders of Gastrointestinal Tract: Three-Dimensional Polymer Model of Nutritional Therapies in Cystic Fibrosis, Ulcerative Colitis, and Crohn`s Disease

Paul Zarogoulidis1,2, Ioannis Kioumis1, Theodora Tsiouda4, Nikolaos Pezirkianidis1,7, Christos Ritzoulis5, Haidong Huang6, Wolfgang Hohenforst-Schmidt7, Dionysios Spyratos1, Konstantinos Porpodis1, Georgia Pitsiou1, Sofia Lampaki1, John Organtzis1, Bianca Kathryn Malecki1,8,9, Sindre Ervik Saetre1,8,9, Konstantinos Zarogoulidis1 and Marek Malecki9,10*
1Aristotle University of Thessaloniki, Thessaloniki, EU, Greece
2University of Duisburg-Essen, Duisburg, EU, Germany
3Theagenio Anticancer Hospital, Thessaloniki, EU, Greece
4Alexander Technological Educational Institute, Thessaloniki, EU, Greece
5II Military University Hospital, Shanghai,, China
6Coburg Regional Hospital, EU, Germany
7Private Practice, Serres, EU, Greece
8Jagiellonian University Medical College, Krakow, EU, Poland
9Phoenix Biomolecular Engineering Foundation, San Francisco, CA,, USA
10University of Wisconsin, Madison, WI, USA
*Corresponding Author: Marek Malecki, M.D., Ph.D., Phoenix Biomolecular Engineering Foundation, San Francisco, CA 91105, USA, Tel: 4157134370, Fax: 4157134371 Email:

Abstract

Background: Inflammatory diseases such as; crohn`s disease and ulcerative colitis are responsible for the malnutrition of the patients. These patients due to structural damage within the gastrointestinal tract do not absorb nutrients. Cystic fibrosis is a hereditary disease where the viscosity of mucus induces organ deficiency and nutrition malnutrition.

Materials and Methods: A novel polymer tube was constructed in order to evaluate the rheology of different types of nutrients. Results: The current 3D model simulates both light and severe disease with the different types of “traps” that have been constructed within it.

Conclusion: Modification of the different nutrients will elicit the proper future modifications that the industry should make for the patients with these underlying diseases.

Keywords: Cystic Fibrosis; Crohn`s Disease; Ulcerative Colitis; Nutrition model; Bioengineering; Biotechnology

Introduction

Cystic Fibrosis, Ulcerative Colitis, and Crohn’sDisease originate with mutations of the genes and manifest with the symptoms within the gastrointestinal track.

Specifically, Cystic Fibrosis is an autosomal recessive disorder caused by a mutation in the gene on chromosome 7, which is coding for the protein cystic fibrosis transmembrane conductance regulator (CFTR). The CFTR is responsible for the transport of chloride and sodium ions across epithelial membranes, therefore a defective protein lead to thick and viscous secretions. Mutations at several different locations in the gene can all lead to Cystic Fibrosis manifesting with differing symptoms and with varying prognoses of the disease. Some mutations lead to production of a less functional protein, while others lead to no production at all. While the most common mutation is delta F508, over 1500 different mutations have been reported. The disease primarily affects the lungs, liver and pancreas. Increased PCO2 and respiratory acidosis is observed in advanced disease. Cystic fibrosis can be diagnosed before birth. Treatment of cystic fibrosis consists of bronchodilators, corticosteroids, antibiotics, enzyme replacement, insulin, bisphosphonates and vaccination during influenza exacerbation, and physiotherapy. Lung transplantation is eligible for final stage disease [1-6]. The vigorous work on gene therapy is rapidly progressing.

Ulcerative Colitis is a chronic inflammatory disease of the gastrointestinal tract. While genetic susceptibility is at the core problem, the factor triggering the disease remains elusive. Dozens of genes have also been linked to ulcerative colitis, many of them involved in the protective function of the intestines. In addition, there is an increased incidence of inflammatory bowel disease in people that have a family member with inflammatory bowel disease, suggesting a genetic basis of these diseases. Ulcerative Colitis usually attacks the large intestine. It has exacerbation periods and disease free periods [7], all manifesting by chronic bloody diarrhea. It is mostly treated as an autoimmune disease, although symptoms might diminish spontaneously. Nutritional supplementation certainly improves the patients’ well-being. Pregnancy is possible during symptom free periods. [7-12].

Crohn’sDisease has genetic mutations as the causative factor. Perhaps the most important of these genes is the NOD2 gene, as people with a mutated NOD2 have a 20 times increased risk of the disease. Nevertheless, mutations in many other genes may contribute to developing full blown symptoms. Crohn’sDisease might affect any part of the gastrointestinal tract (GIT). Patients may present with a variety of symptoms such as vomiting, weight loss, abdominal pain and diarrhea. Moreover, other symptoms include eye inflammation, anemia, arthritis and skin rash [13]. The manifestation of this disease, in the genetically susceptible people, depends on the interaction of the immune system, environmental factors and bacteria. Nevertheless, Crohn’sDisease does not appear to have an autoimmune background [14-16]. Treatment consists of anti-inflammatory agents, immune system suppressors, antibiotics, surgery, nutritional support and symptomatic relief (anti-diarrheal, laxatives) [17]. Potential of immuno-gene therapy is intensively explored.

The rapid progress takes place in refining the genomic background for these diseases. This creates the solid foundations for developing strategies for gene therapy. Meanwhile, the treatments are aimed at providing to the patients some relief of symptoms they are suffering from.

This work was dedicated to compensating the problems resulting from disturbances of the gastrointestinal tract the patient suffer. In this realm, we have developed a three-dimensional polymer model for designing of therapeutic nutrition.

Materials and Methods

The rationale for the project was the well known fact, that that the aforementioned diseases of the gastrointestinal tract induce formation of crypts. These crypts have different sizes with different diameters of entrances. The result is that the nutrient may easily enter, but may have difficulties on exit. This phenomenon aggravates the symptoms of the disease. Therefore, we pursued the concept of designing and engineering of a spatial model of tract simulating pathologically altered gastrointestinal tract of the patients. In order to do that we used the Altech® breathing circuit LOT: 6259.1503.12, 120 cm limb Y connector with ports 2lt latex free. We acquired pipettes with two different diameters 5 mm and 7 mm. We cut out most of the suction tube leaving only 5 mm in length. Afterwards we punctured 10 holes in different parts of the circuit and clued the pipettes head and neck in between the beginning and end (Figure 1). We glued the neck of the pipettes with Pattex® silicone that was melted again with Pattex®- Henkel KGaA melting apparatus (Nr: 10172786 Duesseldorf) (Figure 2). We have chosen to use two different pipettes with different ``necks`` in order to simulate two different types of crypts. We named the 7 mm diameter grade I and the 5 mm diameter grade II (Figure 3). Grade II was relevant to the worse, based on the fact that a crypt with a smaller entrance releases the nutritional material more difficult. We designed three different groups of nutritional material: a) Proteins b) Carbohydrates and c) Fat. For each group we designed additionally six subgroups with different pH and viscosity. Viscosity is the most important factor influencing the rheology and deposition of nutrition within the GI tract. We have to comment at this point that all pipettes had the same volume. We are currently designing and engineering a pump simulating the gastrointestinal tract movement, so that more information can be gathered regarding its function, as well as of administered nutrients.

nanomedicine-biotherapeutic-Polymer-Tude

Figure 1: 3D Polymer Tude with endoluminal traps

nanomedicine-biotherapeutic-melting-apparatus

Figure 2: Pattex® -Henkel KGaA melting apparatus (Nr: 10172786 Duesseldorf, Germany).

nanomedicine-biotherapeutic-outside-lumine

Figure 3: Close picture of a trap, outside the lumine.

Results and Conclusions

In all aforementioned diseases, Ulcerative Colitis, Crohn’sDisease, and Cystic Fibrosis, gastrointestinal tract of the patients is pathologically altered. This may lead to their malnutrition. Therefore, nutrition is the key element of the supportive care.

The newly developed three-dimensional model simulates effectively the structure and functions of the gastrointestinal tract of the patients with mild and severe. Modifications of the different nutrients, with properties complementing the changed by diseases functionalities of the patients’ gastrointestinal tracts, will help to design the proper supportive therapies; thus to prevent the patients’ malnutrition. This can be accomplished by well designed composition and properly adjusted administration of the nutritional therapy, which addresses the spatial changes (crypts) for each of these diseases. While there are already several nutritional supplements on the market that can be used by the patients additionally to their treatment, their selection may benefit from tests run on the model system, which we present herein. We continue experimenting with the different types of nutritional compounds, different viscosities, acid/bases gradients, osmolarity, etc in order to identify the optimal combinations for the particular patient. Optimization of nutrition rheology could contribute effectively to the adjuvant treatment for these patients. In general, spatial models of the pathologically altered gastrointestinal tract are excellent starters for initial experimentation, as we can easily proceed to an in vitro or in vivo experimentation [18]. Further refinement of the model system described herein, should help us in designing optimal composition and properties of the provided nutrients, thus to improve supportive care of our patients.

Conflict of Interest Statement

The authors state no conflict of interest.

Sources of Funding for the Work

This work was supported by the funds from the National Institutes of Health [grant numbers: P41 RR000570 and from the Phoenix Biomolecular Engineering Foundation [grant number: 2006070101] to Marek Malecki MD PhD - Principal Investigator. Administrators of the funding institutions and managers of the facilities had no influence on the project design and apresented data.

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Citation: Zarogoulidis P, Kioumis I, Tsiouda T, Pezirkianidis N, Ritzoulis C (2014) Novel Approach for Designing Supportive Care in Genetic Disorders of Gastrointestinal Tract: Three-Dimensional Polymer Model of Nutritional Therapies in Cystic Fibrosis, Ulcerative Colitis, and Crohn`s Disease. J Nanomedine Biotherapeutic Discov 4: 128.

Copyright: © 2014 Zarogoulidis P, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
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