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Chirality in Nature02:30

Chirality in Nature

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Chirality is the most intriguing yet essential facet of nature, governing life’s biochemical processes and precision. It can be observed from a snail shell pattern in a macroscopic world to an amino acid, the minutest building block of life. Most of the snails around the world have right-coiled shells because of the intrinsic chirality in their genes. All the amino acids present in the human body exist in an enantiomerically pure state, except for glycine - the sole achiral amino acid.
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Prochirality02:05

Prochirality

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The concept of prochirality leads to the nomenclature of the individual faces of a molecule and plays a crucial role in the enantioselective reaction. It is a concept where two or more achiral molecules react to produce chiral products. A typical process is the reaction of an achiral ketone to generate a chiral alcohol. Here, the achiral reactant reacts with an achiral reducing agent, sodium borohydride, to generate an equimolar mixture of the chiral enantiomers of the product. For example, an...
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Molecules with Multiple Chiral Centers02:25

Molecules with Multiple Chiral Centers

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Molecules that possess multiple chiral centers can afford a large number of stereoisomers. For instance, while some molecules like 2-butanol have one chiral center, defined as a tetrahedral carbon atom with four different substituents attached, several molecules like butane-2,3-diol have multiple chiral centers. A simple formula to predict the number of stereoisomers possible for a molecule with n chiral centers is 2n. However, there can be a lower number where some of the stereoisomers are...
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Assembly of Cytoskeletal Filaments01:18

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Cytoskeletal filaments are polymeric forms of smaller protein subunits. However, individual cytoskeletal filaments may easily disassemble or associate with other similar filaments to form rigid structures. Microfilaments, made of actin monomers, rely on actin-binding proteins to form bundles and create networks of individual actin filaments. Microtubules rely on microtubule-associated proteins (MAPs) to form sturdy cylindrical structures. However, the proteins involved in forming complex...
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Stereoisomerism of Cyclic Compounds02:33

Stereoisomerism of Cyclic Compounds

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In this lesson, we delve into the role of ring conformation and its stability, which determines the spatial arrangement and, consequently, the molecular symmetry and stereoisomerism of cyclic compounds. 1,2-Dimethylcyclohexane is used as a case study to evaluate the possible number of stereoisomers. Here, given the multiple (n = 2) chiral centers, there are 2n = 4 possible configurations that lack a plane of symmetry, as the ring skeleton exists in a non-planar chair conformation. In addition,...
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Related Experiment Video

Updated: Mar 7, 2026

Design and Synthesis of a Reconfigurable DNA Accordion Rack
07:44

Design and Synthesis of a Reconfigurable DNA Accordion Rack

Published on: August 15, 2018

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Reconfigurable Microscale Frameworks from Concatenated Helices with Controlled Chirality.

Seog-Jin Jeon1, Ryan C Hayward1

  • 1Department of Polymer Science and Engineering, University of Massachusetts Amherst, Amherst, MA, 01003, USA.

Advanced Materials (Deerfield Beach, Fla.)
|February 22, 2017
PubMed
Summary

Researchers created microscale, temperature-responsive helical structures using a novel trilayer fabrication method. These complex, shape-morphing multihelices offer new possibilities for micro-robotics and biomaterials.

Keywords:
chiralityconcatenationframeworkshelicesreconfigurable

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Area of Science:

  • Materials Science
  • Microfabrication
  • Biomimetic Design

Background:

  • Helical structures are vital for motion in microorganisms and plants.
  • Existing synthetic responsive helices are macroscopic and limited in complexity.
  • Concatenated helices have not been explored for microscale applications.

Purpose of the Study:

  • To develop a microfabrication method for stimuli-responsive helical architectures.
  • To demonstrate the formation of complex, shape-controlled multihelices.
  • To explore the potential of helical segments as building blocks for 3D structures.

Main Methods:

  • Microfabrication of trilayer samples: rigid plastic stripes sandwiching a temperature-responsive hydrogel.
  • Design of helical junctions controlled by stripe direction.
  • Prescription of torsion angles based on segment twist for multihelix formation.

Main Results:

  • Successful microfabrication of temperature-responsive helices inspired by Bauhinia seedpods.
  • Demonstration of shape-controlled frameworks from concatenated multiple helices (multihelices) with tunable chirality.
  • Establishment of simple geometric design rules for complex 3D structure fabrication.

Conclusions:

  • This work presents a robust method for microfabricating complex, responsive helical structures.
  • The developed multihelix system offers new insights into programming 3D shapes using helical building blocks.
  • Potential applications include scaffolds for cell culture, reconfigurable microfluidic channels, and microswimmers.