INFLUENCE OF PROCESSING METHODS ON THE PROTEIN AND CYANIDE CONTENT OF AFRICAN YAM BEAN SPHENOSTYLIS STENOCARPA
Table Of Contents
- Title Page
Approval Page
Dedication
Acknowledgement
Table Of Contents
AbstractChapter One
- 1.0IntroductionChapter Two
- 2.0Literature Review
- 2.1Legumes
- 2.2Nutritive Value Of Legumes
- 2.3African Yam Bean
- 2.4Utilization Of African Yam Bean
2.
- 5.0Limitations In The Utilization Of African Yam Bean
2.
- 5.1Unacceptable Flavour
2.
- 5.2Hard – To – Cook Phenomenon
2.
- 5.3The Presence Of Anti – Nutritional Factors
2.
- 4.1Pre – Conditioning Treatment Used In African Yam Bean Processing
2.
- 7.0Functionality Of Legume Protein/Flour
2.
- 7.1Nitrogen Solubility
2.
- 7.2Water And Oil Absorption
2.
- 7.3Emulsion Capacity
2.
- 7.4Foam Capacity
2.
- 7.5GelationChapter Three
- 3.0Materials And Source
- 3.1Sample Preparation
- 3.2Flow Charts For The Production Of The Different Flour Samples
3.
- 2.1Flow Chart For The Production Of Sample A (Raw Sample)
3.
- 2.2Flow Chart For The Production Of Samples B
3.
- 2.3Flow Chart For The Production Of Samples C
3.
- 2.4Flow Chart For The Production Of Toasted Sample (D Sample)
3.
- 3.0Determination Of Functional Properties Of African Yambean Flour
3.
- 3.1Water Absorption Capacity
3.
- 3.2Oil Absorption Capacity
3.
- 4.0Chemical Composition Of African Yam Bean
3.
- 4.1Determination Of Moisture Content
3.
- 4.2Determination Of Ash Content
3.
- 4.3Determination Of Crude Protein Content
- 3.5Determination Of Glycosidic Cyanide
- 3.6Determination Of Bulk DensityChapter Four
- 4.0Results / DiscussionChapter Five
- 5.0Conclusion
- 5.1Recommendation
References
Thesis Abstract
Abstract
African yam bean (Sphenostylis stenocarpa) is a leguminous crop commonly consumed in West Africa due to its nutritional benefits. This study aimed to investigate the influence of different processing methods on the protein and cyanide content of African yam bean. Fresh African yam bean samples were processed using four methods soaking, boiling, roasting, and fermentation. The protein content was determined using the Kjeldahl method, while cyanide levels were measured using spectrophotometry. Results showed that the processing methods significantly affected the protein content of African yam bean. Boiling and fermentation led to the highest protein content, with boiling resulting in a 25% increase compared to the raw samples. Roasting and soaking also increased the protein content but to a lesser extent. Cyanide content varied among the processing methods, with roasting resulting in the highest reduction compared to the raw samples. Fermentation also led to a significant decrease in cyanide levels, while soaking and boiling had minimal effects on cyanide content. Overall, the findings suggest that processing methods have a significant impact on the protein and cyanide content of African yam bean. Boiling and fermentation were the most effective methods for increasing the protein content, while roasting was the most efficient in reducing cyanide levels. These results are important for improving the nutritional quality and safety of African yam bean consumption. Further research is needed to explore the effects of these processing methods on other nutritional components and to optimize processing conditions for maximum nutritional benefits.
Thesis Overview
INTRODUCTION
African yam bean (Sphenostylis stenocarpa) belongs to the genera papilliona sec which is in the class known as Leguminousae (Okigbo, 1973). It is one of the neglected indigenous grain legumes in Nigeria. It is produced mostly in the eastern part of the country where it is consumed in different forms such as snacks, delicacy, man meal etc. It can be used for the fortification of other foods (Eke, 1997)
In Nigeria, it has as many names as there are communities cultivating it. Some of the names are Okpdudu, Azam, Uzuaku, Ijiriji, Azara, Ahaja, Nzamiri, Odudu, Girigiri (Hausa), sese (Yoruba) and Nsana (Ibibio) (Ogbo, 2002).
The high protein content of African yam bean makes it an important source of protein in the diets of population groups of many tropical countries (Kon, 1979, Ekpen young and Borchers, 1980). In addition, the high protein bean flour fractions could be substituted for wheat flour to produce acceptable qualities of cookies breads and leavened doughs (Uebersax and Zabik, 1986; Nzereogu, 1993).
It may also be consumed as porridge after cooking. The mature dry seeds can be used to prepare “moi - moi†and “akara†(Ezueh, 1973; Akoma, 1996). The African yam bean apart from being rich in protein also contains carbohydrate, fat and minerals (NAS, 1979).
A major constraint in the utilization of African yam bean is the different dehulling method. Traditionally, the dehulling method involves manual removal of the hulls from the individual soaked seeds. This method is quite laborous (labour intensive), time – consuming and does not favour effective utilization of the bean. It is widely believed that under cooked African yam bean seeds cause diarrhoea and over cooked seeds cause constipation (Asusu and Undie, 1986).
Previous works showed that steeping will among other things improve the dehulling characteristic of the African yam bean while maintaining the nutritional quality viz: invitro protein digestibility and also improving the functional properties when processed into flour (Abbey and Berezi, 1988). It is evident that better processing methods will not only enhance the acceptability and utilization of this legume but will also improve the nutritional status of the consuming populace (Uebersax et al, 1989).
The overall objective of this study is to investigate the various processing methods and their effects on the protein and cyanide content of African yam bean in conclusion, before the commencement of any research or project, there is meant to be aim/aims of such research.As such, the aims of this study include:-
1. To determine the hydrogen cyanide content of the flour.
2. To analyse for the crude protein content of the flour.
3. To determine some of the functional properties of the flour.
4. Determination of the chemical composition of the flour.
5. To determine the bulk density of the flour.