# Nano-scale evidence for osteocyte network integration across bone remodeling interfaces in human bone revealed by synchrotron nanoCT

**Authors:** Sophie Anuth, Emely Bortel, Julie Villanova, Jussi-Petteri Suuronen, Sven Geissler, Amaia Cipitria, Peter Fratzl, Tobias Fretwurst, Katja Nelson, Susanne Nahles, Bernhard Hesse

PMC · DOI: 10.1016/j.mtbio.2026.102813 · 2026-01-16

## TL;DR

This study uses advanced imaging to show how bone cells connect across different bone layers, revealing a complex network that adapts during bone remodeling.

## Contribution

The study introduces canalicular looping as a nano-structural signature of directed formation in bone network architecture.

## Key findings

- The osteocyte network integrates across bone remodeling interfaces, influenced by local tissue conditions.
- Canalicular loops in newly formed bone near cement lines indicate a directed, adaptive search for reconnection.
- A 'cross-generational' osteocyte network enhances tissue connectivity and functional resilience across remodeling stages.

## Abstract

Bone remodeling is a highly regulated, hierarchical process critical for maintaining structural integrity and mineral homeostasis. At the nano-scale, the osteocytes orchestrate mechanosensing, signaling, and nutrient transport across the mineralized matrix utilizing their extensive network of cell dendrites. The lacunar-canalicular network (OLCN) houses the cellular components within the matrix. How this network integrates across bone regions formed during different remodeling cycles remains unresolved. How the cellular network is connected across interfaces between different remodeling regions or cement lines is the focus of this exploration: is the network integration merely stochastical occurrences or result of a cued, directed formation process?

Using synchrotron-based nano computed tomography (nano-CT), we analyze human bone samples of 35 different patients with sub-micron resolution to characterize canalicular structures around cement lines. The results show the network's ability and affinity to integrate, and the strong influence of local tissue conditions on the degree of integration. We novelly include the structural analysis of canalicular network architecture to interpret underlying formation processes. Besides 'cross-generational' canalicular connections, we identify previously overlooked canalicular loops in newly formed bone near cement lines and interpret these as morphological indicators of a directed, adaptive search for reconnection. The study suggests a mechanism combining random outgrowth and directed progression influenced by local cues.

We propose a 'cross-generational' OLCN: a deliberately integrated network that enhances tissue connectivity, functional resilience, and osteocyte survival across temporal remodeling stages. These findings advance the understanding of bone network complexity and introduce canalicular looping as a nano-structural signature of directed formation in bone network architecture.

Network development/ formation of canalicular patterns and resulting network integrity across cement lines is shown as a response to existence of possible connection points within the adjacent pre-existing mineralized matrix. A) Case one – formation of “cross-generational” connections - given the presence of possible connection points and B) case two – formation of loops – in absence of connection points within the pre-existing matrix are visualized with minimum intensity projections over 10 μm. Locally younger (re)modeling regions is indicated with (1), locally older region with (2), the cement line interface with a turquois arrow.Image 1

Network development/ formation of canalicular patterns and resulting network integrity across cement lines is shown as a response to existence of possible connection points within the adjacent pre-existing mineralized matrix. A) Case one – formation of “cross-generational” connections - given the presence of possible connection points and B) case two – formation of loops – in absence of connection points within the pre-existing matrix are visualized with minimum intensity projections over 10 μm. Locally younger (re)modeling regions is indicated with (1), locally older region with (2), the cement line interface with a turquois arrow.

## Linked entities

- **Species:** Homo sapiens (taxon 9606)

## Full-text entities

- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12859465/full.md

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Source: https://tomesphere.com/paper/PMC12859465