From Single-Nozzle to Multi-Nozzle Electrospinning: A Comparative Manufacturability Perspective on 3D Electrospun Structures

Authors

• Somanaathan Muthusamy, Universiti Malaya
• Edzrol Niza Mohamad, Universiti Malaya
• Mohd Ridha Bin Muhamad, Universiti Malaya
• Zuradzman Bin Mohamad Razlan, Universiti Malaysia Perlis

Document Type

Review

Publication Date

5-1-2026

Abstract

Electrospinning has evolved from producing two-dimensional nanofiber mats to forming three-dimensional electrospun (3D ES) structures with improved mechanical integrity and functional performance. However, scalable and controllable fabrication of 3D ES structures remains challenging. This review provides a quantitative and mechanism-oriented comparison of major fabrication strategies, including single-nozzle electrospinning (SN), electric field manipulation (EFM), mold-based methods (MBM), near-field electrospinning (NF), hybrid electrospinning–3D printing methods (HBM), controlled deposition systems (CDM), and multi-nozzle electrospinning (MN). Reported operating parameters span applied voltages from 0.1 to 65 kV, working distances from 0.1 to 385 mm, and material delivery rates from 0.006 to 96 mL/h. SN-based and mold-assisted approaches demonstrate the feasibility of forming 3D ES structures under single-jet conditions and low flow rates (typically < 7 mL/h), but their scalability is inherently limited. NF achieves high positional accuracy at short working distances (≤ 80 mm) and low voltages (≤ 8 kV), though its narrow process window restricts large-area fabrication. In contrast, MN electrospinning enables the highest throughput, with nozzle counts ranging from 2 to 72 and fiber diameters as small as 66 nm. Importantly, successful 3D structure formation using single-nozzle configurations confirms that the fundamental electrohydrodynamic mechanisms for three-dimensional growth already exist, implying that MN systems operating at higher throughput possess greater potential for scalable 3D ES fabrication. Despite this, MN performance remains highly sensitive to inter-nozzle spacing, electric-field uniformity, and jet–jet electrostatic interactions, which continue to limit deposition uniformity and mechanical robustness.

Keywords

3D structure, Additive manufacturing, Electrospinning, Multi-nozzle, Nano manufacturing, Nanofiber, Tissue engineering

Publication Title

International Journal of Precision Engineering and Manufacturing

ISSN

2234-7593

DOI

10.1007/s12541-026-01460-5

Recommended Citation

Muthusamy, Somanaathan; Mohamad, Edzrol Niza; Muhamad, Mohd Ridha Bin; and Razlan, Zuradzman Bin Mohamad, "From Single-Nozzle to Multi-Nozzle Electrospinning: A Comparative Manufacturability Perspective on 3D Electrospun Structures" (2026). Research Publications (2026 to 2030). 112.
https://knova.um.edu.my/research_publications_2026_2030/112

Volume

27

Issue

5

First Page

2199

Publisher

SpringerOpen