Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT06381635 |
| Other study ID # |
FD-BUE-REC: IRB000124920 |
| Secondary ID |
|
| Status |
Recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
April 1, 2024 |
| Est. completion date |
January 1, 2025 |
Study information
| Verified date |
April 2024 |
| Source |
Ain Shams University |
| Contact |
Fatma E. Hassanein |
| Phone |
+201000093885 |
| Email |
fatmahassanein[@]dent.asu.edu.eg |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
The goal of this [ type of study: Clinical trial] is to test effectiveness of Aloe Vera Gel
and Manuka Honey in management of Radiation Induced Mucositis in head and neck cancer
patients.
The main question [s] ] is to [ learn about, test, compare etc.] it aims to answer are:
1. Is Aloe Vera Gel and Manuka Honey effective in management of Radiation Induced
Mucositis?
2. Does Aloe Vera Gel and Manuka Honey affect the level of TGFβ1 and EGF in saliva of
patients with radiation induced mucositis? participants will be asked to apply Aloe Vera
Gel and Manuka Honey or saline three times daily during radiotherapy and 6 months after
radiotherapy.
Description:
Head and neck cancer is the eighth common type among all cancer types all over the world [1]
The treatment comprises surgery, radiotherapy, chemotherapy or a combination escorted by
restoration therapy, and social support [2] Radiotherapy leads to irreversible loss of the
reproductive integrity, the cell cycle necessary for cell growth, apoptosis, and necrosis of
cancer cells [3] Conventional fraction size ranges from 1.8 to 3 Grays (Gy) per fraction over
4-6 weeks [4] The accumulative dose of radiation for the primary treatment of head and neck
cancer treatment is 60-70 Gy, depending on the irradiation of the tumor [5].
Radiation affects malignant cells and is also absorbed by the oral mucosa and
gastrointestinal mucosa, especially in rapidly dividing cells [6] Oral mucositis is the most
frequent, distressing, painful, clinical side effect of radiotherapy [7] It is defined as an
inflammatory lesion of oral mucosa resulting from the cancer therapy typically manifesting as
atrophy, swelling, erythema, ulceration, and pseudomembrane formation [8,9] It is described
in five overlapping stages: initiation, upregulation, message generation, ulceration, and
healing [9,10].
Radiation-induced oral mucositis shows hyperkeratosis of the oral mucosa after the dose of
10-20 Gy [6,8] Erythema is the first clinical sign seen on the oral mucosa, and severity of
mucositis reaches at a dose of 30 Gy. After the completion of radiotherapy, the symptoms
abate in 2-6 weeks [11,12] Effective management of oral mucositis is very important [13,14].
Honey is an important traditional medicine and prophylactic agent that has numerous
beneficial health properties including its ability to facilitate healing.[15,16] Honey helps
in the reduction of ulceration and inflammation of the biological process of
mucositis.[17,18] Honey has been used to manage burns, oral infections, surgical wounds, and
pressure wounds.[19,20]. Honey was applied to the oral mucosa of patients undergoing
radiotherapy which is beneficial in limiting the severity of oral mucositis. Honey is a
natural product with rich nutritional properties that is economical and a pleasant agent for
managing mucositis [21].
Manuka honey is a monofloral honey, produced from the nectar of flowers of Manuka tree. This
variety is produced from the Apis mellifera honey bees, using New Zealand Manuka plants
producing specific floral-variety named as Leptospermum scoparium [22]. Manuka honey is
usually rated using a classification system known as the Unique Manuka Factor (UMF), which
reflects the equivalent concentration of phenol (%, w/v) required to produce the same
antibacterial activity as honey.
The composition of Manuka honey consists of carbohydrates, minerals, proteins, fatty acids,
phenolic and flavonoid compounds. Although such compounds are found in other types of honey,
other unique features also occur in Manuka honey, such as an unusually high level of
methylglyoxal (MGO) formed from dihydroxyacetone (DHA) which correlates with antibacterial
activity [23, 24]. Kato et al. also noted the occurrence of methyl syringate glycoside
(leptosperin) as a unique maker for Manuka honey authentication [25]. Interestingly, the UMF
rating of Manuka honey strongly correlates with MGO equivalence and antibacterial activity
but the relation is not wholly understood [26]. In addition to antibacterial activity [22,
26], UMF honey has the ability to stimulate macrophages through Apalbumin 1 protein to
release mediators such as TNF-α, IL-1β and IL-6, which are needed for reducing microbial
infections and helping in tissue healing [27]. Manuka honey shows antioxidant and anticancer
properties, which are considered due to its constituents-phytochemicals working as active
bio-compounds [28, 29].
Aloe Vera (AV) is a cactus-like plant that grows readily in hot, dry climates. It belongs to
the Liliacea family, of which there are about 360 species. Only two species are grown
commercially: Aloe barbadensis Miller and Aloe aborescens. The parenchymatous cells in the
fresh leaves of aloe vera secrete colorless mucilaginous gel (i.e., Aloe vera gel) that
contains 98-99% water and 1-2% active compounds [30, 31] Aloe vera gel has various
pharmacological actions like antibacterial, antifungal, anti-inflammatory, antioxidant,
antitumour, hypoglycaemic properties and immune boosting. Therefore it is used traditionally
as nutritional drinks, moisturizer, healing agent in cosmetics, diabetic patients, sun burn,
wounds and digestive tract disorders, there is no adverse effect [32].
Aloe vera gel had also been used in dentistry and showed good results. It had been used for
treatment of over extraction socket and endodontic medicament. Various dentifrices also
contains Aloe vera gel as its constituent because of its medicinal property [33-34]. Studies
have demonstrated that aloe vera has an important therapeutic uses in the management of oral
lesions such as oral lichen planus, oral submucous fibrosis, radiation induced mucositis,
burning mouth syndrome, xerostomia, recurrent apthous ulcers [31].
Transforming growth factor-β (TGF-β) is a family of related proteins that regulate many
cellular processes including growth, differentiation, extracellular matrix formation and
immunosuppression [35]. TGF-β protein is produced by nearly all normal cells and functions
through a complex cell surface receptor system [36].
The three mammalian isoforms of TGF-β (TGF-βs 1, 2, and 3) have similar but distinct
functions and are approximately 70% identical in amino acid sequence. Transforming growth
factor-β (TGF-β) proteins and their antagonists have entered clinical trials. These
multi-functional regulators of cell growth and differentiation induce extracellular matrix
proteins and suppress the immune system making TGF-βs useful in treatment of wounds with
impaired healing, mucositis, fractures, ischemia-reperfusion injuries, and autoimmune
disease. In diseases such as keloids, glomerulonephritis and pulmonary fibrosis, excessive
expression of TGF-β has been implicated as being responsible for accumulation of detrimental
scar tissue. In these conditions, agents that block TGF-β have prevented or reversed disease.
Similarly, in carcinogenesis, blocking TGF-β activity may be valuable in stimulating an
immune response towards metastasis. As these blocking agents receive approval, we will likely
have new therapies for previously recalcitrant diseases [37]. It has been stated that
transforming growth factor-β3 (TGF-β3) negatively regulates epithelial cell proliferation and
reduces the incidence of oral mucositis [38].
A great number of growth factors and cytokines are involved in the wound site [39]. Of the
growth factors, basic fibroblast growth factor (bFGF), transforming growth factor (TGF-b),
and platelet-derived growth factor (PDGF) are anti-inflammatory and the most important in the
wound healing process [40]. The bFGF (FGF-2) is a member of the FGF's family and has been
shown in several studies to be an essential growth factor for fibroblast and vascular
endothelial cell [41]. bFGF is increased in acute wound healing and plays a role in
granulation tissue formation, re-epithelization, and tissue remodeling [42]. Although
clinical studies have shown that bFGF was not successful in the treatment of diabetic foot
ulcers, topical bFGF application has been found to increase the healing of burns and venous
ulcers [43, 44, 45]. Moreover, TGF-β and PDGF are both crucial for inflammation, granulation,
angiogenesis, connective tissue regeneration, re-epithelization, and remodeling which
stimulate macrophages by increasing the secretion of other growth factors [43, 46]. They
stimulate collagen production, affect matrix formation, and inhibit metalloproteinase (MMP)
activity, which degrades collagen deposition. Levels of PDGF, TGF-β, and FGF are decreased in
chronic wounds.
Epidermal growth factor (EGF), first discovered in the submaxillary gland of a rat in 1962,
comprises a single-chain polypeptide containing 53 amino acids [47, 48]. EGF was later
discovered in various normal tissues and body fluids, including the skin, mucosa, tears,
cornea, saliva, milk, semen, and fluids secreted by the duodenal glands [49, 50]. EGF helps
maintain tissue homeostasis by regulating epithelial cell proliferation, growth, and
migration. It also induces angiogenesis, which provides nutritional support for tissues.
Thus, EGF plays an important role in wound healing and tissue generation and may be useful in
the treatment of radiation-induced oral mucositis [51, 52].
