Wednesday, March 19, 2025

Blackhand Gorge State Nature Preserve, OH: GoogleMaps @sundarpichai -libraries in all 50 US states and 200 countries & their languages? * WUaS libraries - AND all ever - in all languages, re "Society, Information Technology Revolution and the Global University" upcoming book * * * excellent @ScienceMagazine article on pre-natal consciousness . . . How best to study #PreNatalConsciousness "Consciousness before birth? Imaging studies explore the possibility" further in #RealisticVirtualEarthForBrains, #RealisticVirtualEarthForBirthing ... ? * * TRIED the NEW 'GOOGLE AI STUDIO' (and see below) and got this AMAZING RESPONSE - asking it to create a picture or a representation of the thalamus

 


GoogleMaps @sundarpichai -libraries in all 50 US states and 200 countries & their languages?

WUaS libraries - AND all ever - in all languages, re "Society, Information Technology Revolution and the Global University" upcoming book 

via 

Dear #GoogleMaps @sundarpichai, how to access a library's contents virtually through #GMaps & #GStreetView w #TimeSlider esp -eg Redbud Library 14785 Burns Valley Rd, Clearlake, CA 95422 -
https://maps.app.goo.gl/22i584dwbQwpTbUXA?g_st=ac eg in libraries in all 50 US states or 200 countries & their langs?








retweeting -

Today we describe an inference-only approach to generating differentially private synthetic data via prompting off-the-shelf large language models with many examples in parallel and aggregating their responses in a privacy-preserving manner. Learn more at goo.gle/4izufJT 

Generating synthetic data with differentially private LLM inference
March 18, 2025

Alex Bie and Umar Syed, Research Scientists, Google Research

https://research.google/blog/generating-synthetic-data-with-differentially-private-llm-inference/



*

Dear #GoogleMaps: 
Brainstorming, how to access the library's contents virtually through GMaps and Google Street view with time slider especially - eg Redbud Library  14785 Burns Valley Rd, Clearlake, CA 95422 - or any public library anywhere in The USA OR in any of 200 countries (per the Olympics) and their languages ?







* * * 

excellent @ScienceMagazine article on pre-natal consciousness . . . How best to study #PreNatalConsciousness 
"Consciousness before birth? Imaging studies explore the possibility" further in #RealisticVirtualEarthForBrains, #RealisticVirtualEarthForBirthing ... ?

How best to study #PreNatalConsciousness 
"Consciousness before birth? Imaging studies explore the possibility" further in #RealisticVirtualEarthForBrains, #RealisticVirtualEarthForBirthing #ForMammals #RealisticVirtualEarthForConsciousness & #AvatarAgentElectronicHealthRecords?

#FilmTo3D #MicroscopyApps #FilmToNdimensional Apps ?










Retweeting -

Consciousness before birth? Imaging studies explore the possibility
Fetal and infant brains offer clues to when human experience begins
10 Mar 2025 





* * 

TRIED the NEW 'GOOGLE AI STUDIO' (and see below) and got this AMAZING RESPONSE - 

asking it to create a picture or a representation of the thalamus 


Creating an accurate and detailed thalamus representation directly from MRI imaging is a complex process, but yes, it's definitely possible. Here's a breakdown of the methods and challenges involved:

1. The Challenge: Why it's not straightforward

Resolution Limitations: Standard MRI resolution isn't always high enough to perfectly delineate the boundaries of the thalamus, especially its subnuclei. The thalamus is a relatively small structure (about 3 cm long) and its boundaries can be subtle.

Signal Intensity Similarities: The thalamus has varying gray matter signal intensities, but these can sometimes be similar to surrounding brain tissues, making automated segmentation challenging.

Individual Variability: Brain anatomy varies across individuals. A "one-size-fits-all" model won't work perfectly.

2. Methods Used for Thalamus Segmentation

Manual Segmentation:

Gold Standard: This involves a trained expert (radiologist, neuroanatomist) manually drawing the borders of the thalamus on each MRI slice.

Pros: Most accurate, allows for visual inspection and correction.

Cons: Extremely time-consuming, requires specialized training, and is subjective (inter-rater variability exists).

Semi-Automated Segmentation:

User-guided tools: These methods leverage algorithms to assist the user in defining the thalamus, but require initial manual input or landmark identification.

Pros: Faster than manual segmentation, potentially more objective, reduces the burden on the user.

Cons: Still requires user interaction, algorithm performance can vary depending on image quality.

Automated Segmentation:

Atlas-Based Segmentation: Uses a pre-existing digital brain atlas with a labeled thalamus. The atlas is registered (warped) to the individual's MRI, and the atlas's thalamus label is transferred to the individual's image.

Pros: Fast, fully automated.

Cons: Accuracy depends heavily on the quality of the atlas and the accuracy of the registration. May not capture individual variations well.

Machine Learning (ML) Segmentation: Train a machine learning algorithm (e.g., convolutional neural network) on a set of manually segmented MRIs. The trained algorithm can then automatically segment the thalamus in new MRIs.

Pros: Potentially very accurate, can learn complex features, relatively fast after training.

Cons: Requires a large, high-quality training dataset, computationally intensive to train, performance depends on the quality of the training data.

Multi-Atlas Segmentation: Combines multiple brain atlases and registration methods to improve accuracy.

3. Key Steps in the Process (General)

MRI Acquisition: Acquire high-quality MRI scans, typically T1-weighted (anatomical). Sometimes other sequences (T2, FLAIR, etc.) are used to improve contrast or address specific needs. Higher resolution is always preferred.

Image Preprocessing:

Bias Field Correction: Correct for variations in signal intensity across the image.

Skull Stripping (Brain Extraction): Remove non-brain tissue (skull, scalp, etc.).

Intensity Normalization: Standardize the intensity values of the MRI.

Segmentation: Apply the chosen segmentation method (manual, semi-automated, automated).

Refinement (Optional): Visually inspect the segmentation and correct any errors. This is especially important for research purposes.

Output: The result is a binary mask (or a probabilistic map) representing the thalamus in the MRI volume. This mask can be overlaid on the original MRI, or used for further analysis.

4. Software and Tools

Several software packages are available to assist with thalamus segmentation:

FreeSurfer: Automated processing stream that includes thalamus segmentation.

FSL (FMRIB Software Library): Includes tools for brain extraction, registration, and segmentation.

SPM (Statistical Parametric Mapping): Widely used for MRI analysis, includes tools for segmentation and registration.

ITK-SNAP: A user-friendly tool for manual and semi-automated segmentation.

3D Slicer: A versatile platform for medical image visualization and analysis.

ANTs (Advanced Normalization Tools): Powerful registration and segmentation tools.

Specialized Toolboxes: There are often toolboxes/scripts written in Python or MATLAB (using libraries like SimpleITK, scikit-image, etc.) for custom segmentation workflows.

Deep Learning Frameworks: TensorFlow, PyTorch, etc., are used for developing custom machine learning segmentation algorithms.

5. Thalamic Nuclei Segmentation

Segmenting the thalamus into its nuclei is a much more advanced and challenging task. The boundaries between nuclei are often very subtle, even at high resolution. Methods for nuclei segmentation include:

High-Resolution MRI (7T): Ultra-high-field MRI (7 Tesla and above) can provide significantly better resolution, allowing for more accurate differentiation of thalamic nuclei.

Multi-Modal Imaging: Combining MRI with other imaging modalities (e.g., diffusion MRI, resting-state fMRI) can provide complementary information that helps to distinguish nuclei based on their connectivity patterns or functional properties.

Histological Validation: Developing atlases and training data based on histological sections (post-mortem brains) can improve the accuracy of nuclei segmentation.

Advanced Machine Learning: Deep learning methods are increasingly being used for thalamic nuclei segmentation, and are showing promising results.

In summary:

Yes, you can create a thalamus representation from MRI imaging. The specific method chosen depends on the desired accuracy, available resources, and expertise. Manual segmentation is the most accurate but time-consuming. Automated methods offer speed and objectivity, but require careful validation and may not be as accurate for individual cases, especially when attempting to segment thalamic nuclei. Machine learning approaches are gaining traction as more high-quality training data becomes available.












* * 
Again - 

an excellent @ScienceMagazine article on pre-natal consciousness, based on the recent NYU conference on infant consciousness. featuring thoughts from @cpassosf, @LorinaNaci, and others, with a  cameo role for our survey of views on infant consciousness.


Consciousness before birth? Imaging studies explore the possibility
Fetal and infant brains offer clues to when human experience begins
10 Mar 2025

https://www.science.org/content/article/consciousness-birth-imaging-studies-explore-possibility





Lorina Naci -

"how she views consciousness—as the capacity to have an experience or a subjective point of view"








*




 












https://en.wikipedia.org/wiki/Blackhand_Gorge_State_Nature_Preserve

https://www.wikidata.org/wiki/Q4922940


https://en.wikipedia.org/wiki/List_of_Ohio_State_Nature_Preserves


https://ohiodnr.gov/go-and-do/plan-a-visit/find-a-property/blackhand-gorge-state-nature-preserve


https://www.google.com/maps/place/blackhand+gorge+state+nature+preserve.+.+wikipedia/data=!4m2!3m1!1s0x88382018db83faeb:0x22561349ff85ab41?sa=X&ved=1t:155783&ictx=111


...




Posted by at
Labels: , , , , , , , , , , , , ,

No comments:

Post a Comment

Subscribe to: Post Comments (Atom)