Nutritional profiling of stingless bee bread (Meliponini) across species and sites in Riau, Indonesia

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Published: 2026-01-22
DOI: https://doi.org/10.13057/biodiv/d261217
Keywords:
Agroforestry, nutritional variability, proximate composition, smallholder meliponiculture, stingless bee bread
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ENI SUHESTI
Department of Forestry, Faculty of Forestry and Science, Universitas Lancang Kuning. Jl. Yos Sudarso KM 8, Pekanbaru 28261, Riau, Indonesia
YELMIZA
Department of Chemistry, Faculty of Forestry and Science, Universitas Lancang Kuning. Jl. Yos Sudarso KM 8, Pekanbaru 28261, Riau, Indonesia
DITA FITRIANI
Department of Agricultural Product Technology, Faculty of Agriculture, Universitas Lancang Kuning. Jl. Yos Sudarso KM 8, Pekanbaru 28261, Riau, Indonesia
HADINOTO
Department of Forestry, Faculty of Forestry and Science, Universitas Lancang Kuning. Jl. Yos Sudarso KM 8, Pekanbaru 28261, Riau, Indonesia

Abstract

Abstract. Suhesti E, Yelmiza, Fitriani D, Hadinoto. 2025. Nutritional profiling of stingless bee bread (Meliponini) across species and sites in Riau, Indonesia. Biodiversitas 26: 6151-6161. Stingless bee bread is a nutrient-dense fermented pollen increasingly promoted as a functional food, yet Indonesian nutritional datasets remain scarce. This study characterizes proximate composition and vitamins A, B2, and E in bee bread from three stingless bee species (Geniotrigona thoracica, Heterotrigona itama, and Trigona apicalis) managed by smallholders at multiple sites in Riau, Indonesia. For each species × site combination, bee-bread pots were pooled to obtain a homogenized composite, which was summarized on a unified fresh-mass basis. Group differences among species and sites were evaluated using non-parametric tests. At a co-occurring site, G. thoracica consistently exhibited the highest levels of vitamins A, B₂, and E; T. apicalis showed the highest total fat and fat-derived energy; and H. itama combined relatively high total energy with elevated protein. Within H. itama, site effects were evident, with vitamins A and E peaking at specific locations and vitamin B₂ at another. These patterns resolve into three practical nutritional signatures, vitamin-oriented in G. thoracica, lipid-oriented in T. apicalis, and relatively stable energy or protein in H. itama. While the pooled composite design constrains colony-level inference, the species- and site-resolved ranges reported here provide preliminary nutritional baselines that can inform future work on quality control and biodiversity-aligned meliponiculture.

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Vol. 26 No. 12 (2025)

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Articles
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This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

Author Biography

ENI SUHESTI, Department of Forestry, Faculty of Forestry and Science, Universitas Lancang Kuning. Jl. Yos Sudarso KM 8, Pekanbaru 28261, Riau, Indonesia

Eni Suhesti is a lecturer and researcher at Universitas Lancang Kuning, Indonesia. She currently serves as the Director of the Institute for Research and Community Service (LPPM), where she plays an active role in advancing institutional research development. Her leadership focuses on strengthening academic collaboration and promoting applied research that not only enriches higher education but also delivers meaningful contributions to society. Driven by a strong vision for academic excellence and social impact, she continues to inspire innovation and foster a culture of knowledge sharing among scholars and practitioners.

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