DILICERA: Experimental study of cerebrospinal fluid flow in the spinal canal: drug dispersion and implications in neurological diseases (PID2020-115961RB-C31/C32).

Duration
09/2021 - 08/2024

Summary

Cerebrospinal fluid (CSF) is predominantly secreted from blood plasma and bathes the external surfaces of the brain and spinal cord. It maintains the electrolyte balance of the central nervous system (CNS), serves as a medium for the supply of nutrients to neuronal and glial cells and the removal of waste products of cellular metabolism. It also transports hormones, neurotransmitters and other neuropeptides throughout the CNS. Dysregulation of the CSF circulation can compromise the transport of these solutes and normal physiological functions of the CNS.

CSF also provides a conduit for the delivery of potent analgesics and chemotherapy to the CNS, a drug delivery procedure often referred to as intrathecal or intraspinal drug delivery (ITDD). To date, there is no comprehensive methodology capable of predicting the long-term, patient-specific transport of CSF solute molecules in the spinal canal. Thus, the main objective of this proposal is to develop a modelling methodology capable of predicting the transport of solute molecules along the spinal canal in each patient-specific anatomical and physiological condition, and apply it to optimise ITDD protocols. The model combines the use of two time-scale asymptotic analyses of the CSF Eulerian velocity field in the spinal canal with in-vitro experiments and detailed patient-specific in-vivo radiological measurements. The proposed methodology is valid for molecular diffusivities typically found in intrathecally administered drugs and takes into account the convective effects of CSF, including "shear-increased dispersion", "steady-streaming" and "Stokes drift", to determine the Lagrangian solute transport in the subarachnoid space (SAS) of the spinal canal. The development of malformations such as Chiari I, and associated syringomyelia, cause abnormal movement of cerebrospinal flow, which has important implications for the development of these diseases. Thus, this proposal also focuses on the analysis of flow in the upper subarachnoid space to describe changes in CSF dynamics when Chiari I malformation is present. The expected outcomes of the proposed research are as follows: it will provide a detailed understanding of the mechanisms that regulate the transport of all important molecules key to CNS function, it is also expected to provide a methodology that will allow optimisation of ITDD protocols and it will clarify some of the possible mechanisms that lead to the formation of a syrinx, a fluid-filled sac or cyst, in the spinal cord in patients with Chiari malformation.

Goals

This coordinated project has the following general objectives:

O1. Understanding cerebrospinal fluid flow and solute transport in the spinal canal and development of subject-specific models for application in intrathecal drug delivery protocols.

O2. Characterisation of abnormal CSF flow induced by Chiari malformation type 1 and its role in the development of syringomyelia.

The specific objectives, within the general objectives, are:

  1.  To understand the effect of patient-specific geometric and physiological characteristics on CSF flow in the spinal canal and solute transport.
  2.  Characterise the impact of the respiratory cycle on both first-order oscillatory flow and long-term flow and transport.
  3.  To quantify the effect of micro-anatomical features of the spinal canal on CSF flow and transport.
  4.  To characterise the effects of specific drug properties on their transport along the spinal canal.
  5. To quantify the hydrodynamic modifications induced by the geometric alterations associated with Chiari malformation type 1.
  6. To study the mechanisms of formation and growth of CSF-filled syrinx cavities within the spinal cord caused by shear-induced fluid-structure interaction between CSF flow in the SSAS and the spinal cord.

Tasks

Goal 1. Understanding cerebrospinal fluid flow and solute transport in the spinal canal and development of subject-specific models for application in intrathecal drug delivery protocols.

TASK 1.1. Study of normal CSF flow in the spinal canal: identification and characterisation of the governing physical mechanisms, effect of control parameters and realistic conditions.

TASK 1.2. Effect of the respiratory cycle on short- and long-term CSF flow and transport.

TASK 1.3. Influence of microanatomy on CSF flow and transport.

TASK 1.4. Characterisation of the influence of specific drug parameters: drug baricity, pharmacokinetics and drug injection protocols.

Goal 2. Characterisation of abnormal CSF flow induced by Chiari malformation type 1 and its role in the development of syringomyelia.

TASK 2.1. Quantification of the effect of Chiari malformation type 1 on flow in the upper spinal subarachnoid space.

TASK 2.2. Study of syrinx formation and growth by shear-induced CSF segregation.

Results

  • Performance of in-vitro MRI tests on real subjects.
  • Designing and performing simplified CSF flow experiments in the presence of flexible walls.
  • Simulations and simplified theoretical modelling to characterise CSF movement in channels with moving and/or flexible walls.

Technical or international scientific impact

This project aims to deepen the study of the flow of cerebrospinal fluid (CSF) in the spinal canal and its implications in the development of associated pathologies and their treatment. In particular, a comprehensive methodology, based on numerical analysis, complemented with theoretical and experimental studies, is proposed to understand the flow and transport of solutes in the spinal canal, the causes and hydrodynamic effects of Chiari Malformation type 1 (CM1) and related syringomyelia. The novel approach lies in the application of known mechanisms in fundamental fluid mechanics that are not yet identified in this type of biological flows, which may constitute a significant advance in knowledge in the field of clinical medicine. The high degree of innovation associated with the project is expected to lead to important scientific and technical impacts. In particular, such results have the potential to generate the design of personalised intrathecal or intraspinal drug delivery protocols for each patient. In addition, the study of the mechanical processes of biofluidics and their effect on the hydrodynamics caused by CM1-associated syringomyelia may help to improve the efficiency of the associated medical treatment, supported by new scientific evidence, thus complementing the documented experience of physicians and neuro-radiologists.

The international projection of the project is reinforced by the collaboration of researchers from the University of California at San Diego, who have outstanding experience in the field of bioengineering and biological flows, and with whom the proposing team has established a solid and fruitful collaboration. The support of renowned radiologists and neurosurgeons from the University of Wisconsin-Madison and the Hospital Virgen de las Nieves in Granada also highlights the multidisciplinary nature of the proposal.

Furthermore, the interest and support shown by companies, such as Siemens Healthineers España AG, or the CMATIAVANTE technology centre, demonstrates the relevance of the proposed research and the possible technical exploitation of models and tools derived from the project. Overall, it seems reasonable to believe that the application of the results will have far-reaching benefits in the short term, with the knowledge that will be generated having a clear potential to translate into future improvements in medical procedures.

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The project

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